VICP Registry Case Source Bundle
Canonical URL: https://vicp-registry.org/case/USCOURTS-cofc-1_18-vv-01625
Package ID: USCOURTS-cofc-1_18-vv-01625
Petitioner: Roy Romero
Filed: 2018-10-19
Decided: 2026-03-25
Vaccine: influenza
Vaccination date: 2016-10-21
Condition: acute inflammatory demyelinating polyneuropathy (AIDP) / Guillain-Barre syndrome (GBS)
Outcome: entitlement_granted_pending_damages
Award amount USD: 

AI-assisted case summary:
On October 19, 2018, Roy Romero filed a petition alleging that an influenza vaccination administered on October 21, 2016 caused acute inflammatory demyelinating polyneuropathy, clarified in an amended petition as Guillain-Barre syndrome. Mr. Romero was 49 years old at vaccination.

The case had an important procedural split. In 2021, the Special Master found that Mr. Romero's first neurologic symptoms began about 54 to 58 hours after vaccination, which was too soon to qualify for the influenza/GBS Vaccine Table interval of three to forty-two days. That ruling dismissed the Table claim but allowed the off-Table causation claim to proceed.

Mr. Romero's pre-vaccination history was medically active. Earlier in October 2016, he had urgent-care and hospital visits for flu-like symptoms, abdominal pain, fever, chills, diarrhea, acute pancreatitis, newly diagnosed diabetes, fatty liver, and later chest pain and cardiac evaluation. He received the flu vaccine on October 21, 2016. On the evening of October 23 he developed hand weakness; by October 24 he was walking slowly, and by October 25 he could not walk. At the emergency department on October 26, his weakness was progressing upward and he had difficulty writing. Neurology documented weakness and absent reflexes, lumbar puncture supported AIDP, and EMG/NCS showed an axonal and demyelinating neuropathy consistent with an axonal variant of AIDP. He was treated with IVIG, transferred to inpatient rehabilitation, and then continued through prolonged outpatient PT and OT. He improved but continued to require assistive devices and could not return to his prior work.

Petitioner relied on neurologist Dr. Marcel Kinsbourne and immunologist Dr. Omid Akbari. Their theory was that the flu vaccine, given while Mr. Romero was already in a systemic inflammatory state from his recent illness and pancreatitis, substantially contributed to an immune cascade that produced GBS unusually quickly. Respondent's experts argued that the recent respiratory or gastrointestinal illness, pancreatitis, diabetes, surgery, or inflammatory condition provided a more plausible explanation and that the rapid onset was not medically acceptable for vaccine causation.

On March 25, 2026, Special Master Mindy Michaels Roth found that the vaccine was a substantial factor and but-for cause of Mr. Romero's GBS. She accepted that his preexisting inflammatory state explained the unusually rapid 54-to-58-hour onset, found that respondent had not proved any non-vaccine factor was the sole substantial cause, and granted entitlement. The case was ordered to proceed to damages.

Theory of causation field:
Influenza vaccine October 21, 2016, at age 49, causing AIDP/GBS; onset 54-58 hours post-vaccination. ENTITLEMENT GRANTED; damages pending. Table claim denied in 2021 because onset was shorter than the 3-42 day Table interval. Off-Table theory: flu vaccine was administered during an existing systemic inflammatory state after pancreatitis/GI or respiratory illness, triggering immune-mediated GBS. Petitioner experts Dr. Marcel Kinsbourne and Dr. Omid Akbari; respondent argued recent illness/inflammation was the cause. LP and EMG/NCS supported AIDP; IVIG and rehab followed. SM Mindy Michaels Roth granted entitlement March 25, 2026. Attorney: Michael A. Baseluos.

Public staged source text:

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DOCUMENT 1: USCOURTS-cofc-1_18-vv-01625-0
Date issued/filed: 2021-04-19
Pages: 8
Docket text: PUBLIC ORDER/RULING (Originally filed: 03/11/2021) regarding 50 Findings of Fact & Conclusions of Law, Signed by Chief Special Master Brian H. Corcoran. (sw) Service on parties made.
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Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 1 of 8
In the United States Court of Federal Claims
OFFICE OF SPECIAL MASTERS
No. 18-1625V
UNPUBLISHED
ROY ROMERO, Chief Special Master Corcoran
Petitioner, Filed: March 11, 2021
v.
Special Processing Unit (SPU);
SECRETARY OF HEALTH AND Findings of Fact; Onset; Influenza
HUMAN SERVICES, (Flu) Vaccine; Guillain-Barré
Syndrome (GBS)
Respondent.
Michael Adly Baseluos, Baseluos Law Firm, San Antonio, TX, for petitioner.
Camille Michelle Collett, U.S. Department of Justice, Washington, DC, for respondent.
FINDINGS OF FACT AND CONCLUSIONS OF LAW DISMISSING TABLE CLAIM1
On October 19, 2018, Roy Romero filed a petition for compensation under the
National Vaccine Injury Compensation Program, 42 U.S.C. §300aa-10, et seq.2 (the
“Vaccine Act”). Petitioner alleged that he suffered acute inflammatory demyelinating
polyneuropathy, a variant of Guillain-Barré Syndrome (“GBS”), as a result of an influenza
(“flu”) vaccine administered on October 21, 2016. Petition at 1. The case was assigned
to the Special Processing Unit (“SPU”) of the Office of Special Masters.
1 Because this unpublished fact ruling contains a reasoned explanation for the action in this case, I am
required to post it on the United States Court of Federal Claims' website in accordance with the E-
Government Act of 2002. 44 U.S.C. § 3501 note (2012) (Federal Management and Promotion of Electronic
Government Services). This means the fact ruling will be available to anyone with access to the
internet. In accordance with Vaccine Rule 18(b), petitioner has 14 days to identify and move to redact
medical or other information, the disclosure of which would constitute an unwarranted invasion of privacy.
If, upon review, I agree that the identified material fits within this definition, I will redact such material from
public access.
2 National Childhood Vaccine Injury Act of 1986, Pub. L. No. 99-660, 100 Stat. 3755. Hereinafter, for ease
of citation, all “§” references to the Vaccine Act will be to the pertinent subparagraph of 42 U.S.C. § 300aa
(2012).

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 2 of 8
Although Mr. Romero did not formally allege a flu-GBS claim under the Vaccine
Injury Table (“Table”), this case was assigned to SPU based upon the initial assumption
that such a claim might be tenable. However, as discussed herein, the medical record
best supports the conclusion that the onset of Petitioner’s GBS occurred less than three
days after vaccination – and thus outside the prescribed 3-42 day Table onset period for
a flu-GBS injury. Because Petitioner cannot preponderantly establish all of the
requirements of a presumptive flu-GBS injury, his Table claim must be dismissed
(although the matter may proceed outside of SPU as a non-Table claim).
PROCEDURAL HISTORY
Petitioner initiated this case on October 19, 2018, alleging that he suffered GBS
as a result of a flu vaccine administered on October 21, 2016.3 Petition at 1. On January
27, 2020, Respondent filed a status report indicating that he intended to defend this case.
ECF No. 36.
Respondent filed a Rule 4(c) Report on May 14, 2020. In it, Respondent asserted
that Petitioner had not established that he suffered a presumptive flu-GBS injury as set
forth in the Table, or alternatively that Petitioner’s GBS was caused-in-fact by the
vaccination. Res. Report at 17-18. Regarding the Table requirements, Respondent
argued that Petitioner’s medical records variously placed the onset of his GBS the day of
vaccination, the day after vaccination, and/or two days after vaccination – all outside the
3-42 day Table onset period. Id. at 18. Respondent additionally contended that there was
evidence Petitioner’s GBS was caused by factors unrelated to the administration of the
vaccine (e.g., gastrointestinal illness). Id.
A status conference was held with the parties on July 1, 2020. During the
conference, the parties were informed that in light of the onset and alternative cause
issues raised by Respondent, Petitioner’s claim might not be viable, whether as a Table
or non-Table, causation-in-fact claim. ECF No. 42. The parties were directed to Rowan v.
Sec'y of Health & Human Servs., No. 17-760V, 2020 WL 2954954 (Fed. Cl. Spec. Mstr.
Apr. 28, 2020), a case in which I determined that a GBS onset sooner than three days
post-vaccination was not scientifically or medically supported, given that GBS is known
to be mediated by autoantibodies produced via the adaptive immune system, and this
process takes longer than three days to result in symptoms.
3 Petitioner also filed a Supplemental Petition on April 5, 2019, which incorporated and discussed medical
records that were filed after the original Petition. In the Supplemental Petition, Mr. Romero also asserted
that his pre-vaccination medical conditions were unrelated to the onset of his GBS. See generally
Supplemental Petition (ECF No. 13).
2

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 3 of 8
At a follow-up status conference held on July 13, 2020, Petitioner’s counsel stated
that he had consulted with an expert who believed Petitioner’s pre-vaccination
pancreatitis could in fact have caused an onset sooner than three days due to immune
system general activity. ECF No. 43. Counsel also maintained that Rowan could be
distinguished, primarily due to the fact that the petitioner in that case was elderly (and
therefore the immune process was likely to be slower). Id. And counsel further proposed
that it was possible the symptoms Petitioner experienced within three days of his
vaccination (e.g., weakness) were unrelated to GBS. Id.
In response, I reiterated my initial view that the Table claim did not appear viable
given the record evidence suggesting an onset of sooner than three days, although I
allowed that Petitioner might succeed with a non-Table causation-in-fact claim supported
by the proposed expert opinion. Id. I therefore expressed the intention to transfer this
case from SPU, given the time elapsed since the case was filed, the complexity of the
medical issues involved, and the unlikelihood of informal resolution. Id.
I also indicated my expectation that the Table version of the claim warranted
dismissal – although I noted that I would permit Petitioner to show cause why this should
not occur. Id. I emphasized, however, that Petitioner should not obtain an expert report
(although he could attempt to explain why the record facts supported a Table claim, and
how an expert opinion would assist that showing). Id. After briefing, I noted that I would
rule on the Table claim, and then (assuming I acted as predicted) transfer the matter for
adjudication of the causation-in-fact claim. Id.
Petitioner filed a brief (“Br.”) regarding his Table claim on September 28, 20204
(ECF No. 47), and Respondent opposed the Table claim’s maintenance (“Opp.”) on
October 20, 2020. ECF No. 48. Petitioner filed a reply brief on October 21, 2020. ECF
No. 49. Accordingly, this case is now ripe for a determination.
AUTHORITY
Before compensation can be awarded under the Vaccine Act, a petitioner must
demonstrate, by a preponderance of evidence, all matters required under Section
11(c)(1), including the factual circumstances surrounding his claim. Section 13(a)(1)(A).
In making this determination, the special master or court should consider the record as a
whole. Section 13(a)(1). Petitioner’s allegations must be supported by medical records or
by medical opinion. Id.
4 Petitioner also filed an affidavit on September 27, 2020 providing a timeline of his post-vaccination
symptoms. ECF No. 46.
3

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 4 of 8
To resolve factual issues, the special master must weigh the evidence presented,
which may include contemporaneous medical records and testimony. See Burns v. Sec'y
of Health & Human Servs., 3 F.3d 415, 417 (Fed. Cir. 1993) (explaining that a special
master must decide what weight to give evidence including oral testimony and
contemporaneous medical records). Contemporaneous medical records are presumed to
be accurate. See Cucuras v. Sec’y of Health & Human Servs., 993 F.2d 1525, 1528 (Fed.
Cir. 1993). To overcome the presumptive accuracy of medical records testimony, a
petitioner may present testimony which is “consistent, clear, cogent, and compelling.”
Sanchez v. Sec'y of Health & Human Servs., No. 11–685V, 2013 WL 1880825, at *3 (Fed.
Cl. Spec. Mstr. Apr. 10, 2013) (citing Blutstein v. Sec'y of Health & Human Servs., No.
90–2808V, 1998 WL 408611, at *5 (Fed. Cl. Spec. Mstr. June 30, 1998)).
In addition to requirements concerning the vaccination received, the duration and
severity of petitioner’s injury, and the lack of other award or settlement,5 a petitioner must
establish that he suffered an injury meeting the Table criteria, in which case causation is
presumed, or an injury shown to be caused-in-fact by the vaccination he received.
Section 11(c)(1)(C).
The most recent version of the Table, which can be found at 42 C.F.R. § 100.3,
identifies the vaccines covered under the Program, the corresponding injuries, and the
time period in which the particular injuries must occur after vaccination. Section 14(a).
Pursuant to the Vaccine Injury Table, GBS is compensable if it manifests within 3-42 days
(not less than three days and not more than 42 days) of the administration of a flu
vaccination. 42 C.F.R. § 100.3(a)(XIV)(D). Further criteria for establishing a GBS Table
injury can be found under the accompanying Qualifications and Aids to Interpretation. 42
C.F.R. § 100.3(c)(15).
Cases alleging a flu-GBS Table injury have often been dismissed for failure to
establish proper onset. See, e.g., Randolph v. Sec'y of Health & Human Servs., No. 18-
1231V, 2020 WL 542735, at *8 (Fed. Cl. Spec. Mstr. Jan. 2, 2020) (finding GBS onset at
the earliest occurred 76 days post-vaccination, “well outside the 3-42 day window set by
the Table for a flu-GBS claim”); Upton v. Sec'y of Health & Human Servs., No. 18-1783V,
2020 WL 6146058, at *2-3 (Fed. Cl. Spec. Mstr. Sept. 24, 2020) (finding the petitioner did
not establish the onset of his GBS within the 3-42 day time frame prescribed and thus did
not establish a Table Injury).
5 In summary, a petitioner must establish that he received a vaccine covered by the Program, administered
either in the United States and its territories or in another geographical area but qualifying for a limited
exception; suffered the residual effects of his injury for more than six months, died from his injury, or
underwent a surgical intervention during an inpatient hospitalization; and has not filed a civil suit or collected
an award or settlement for his injury. See § 11(c)(1)(A)(B)(D)(E).
4

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 5 of 8
ANALYSIS
After reviewing the entire record, including all medical records, affidavits,
Respondent’s Rule 4(c) Report,6 and the parties’ briefing, I have concluded that the onset
of Petitioner’s GBS occurred less than three days after vaccination and thus outside the
prescribed flu-GBS Table onset period.7 I have specifically based my finding on the
following evidence:
• On October 21, 2016, Petitioner presented to David Gomez, PA-C, at Ramos
Family Medical Group to establish care as a new patient. Ex. 17 at 3-5. During the
appointment, Petitioner was administered a flu vaccine. Id. at 4.
• Five days later, on October 26, 2016, Petitioner presented to the emergency room
at University Health System. Ex. 11 at 212. An intake record noted that Petitioner
was recently hospitalized due to pancreatitis8 and had been prescribed medication
for diabetes, high cholesterol, hypertension, and GERD. Id. Petitioner indicated
that, since taking the aforementioned medications, he had experienced
progressive weakness with difficulty performing fine motor tasks and decreased
energy. Id.
• Shortly thereafter on that same date, Petitioner was assessed by an emergency
room physician, who noted that Petitioner had experienced numbness of his hands
for five days, but that two-to-three days ago had also begun experiencing bilateral
lower extremity weakness and pain. Id. at 210.
• A second emergency room physician recorded on October 26, 2016, that Petitioner
was in his normal state of health four days prior, but reported numbness and
weakness of the extremities for three days. Id. at 205. Petitioner was further noted
to have fatigue and tingling in the bilateral lower extremities leading to weakness
6 In his Report, Respondent identified several records that are potentially outstanding – including records
associated with a medical appointment on October 25, 2016. See, e.g., Res. Report at 6 n.7. Petitioner has
asserted that many of the records requested by Respondent do not exist and that all relevant medical
records have been filed. See, e.g., Res. Report at 6; Petitioner’s Amended Statement of Completion, filed
December 19, 2019 (ECF No. 34). I find that the available record is sufficient to make a limited finding
regarding the nonviability of Petitioner’s flu-GBS Table claim.
7 A more complete recitation of the facts can be found in the Petition, Respondent’s Rule 4(c) Report, and
the parties’ briefing. Given the issues involved in this ruling, I have limited my discussion to the records
most relevant to the onset of Petitioner’s GBS.
8 Petitioner was hospitalized from October 9 to October 11, 2016 for treatment of acute pancreatitis. See
Ex. 15 at 3-4, 13-14.
5

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 6 of 8
and an inability to walk. Id. The assessment was “[l]ikely Guillain Barre vs. atypical
ALS.” Id. at 207.
• A third emergency room physician recorded on October 26, 2016 that Petitioner
began experiencing bilateral lower extremity weakness for two-to-three days that
had progressed upward toward his upper extremities. Ex. 11 at 208. Petitioner was
referred for a neurology consultation. Id. at 209.
• Petitioner underwent a resident neurology consultation on October 26, 2016, at
University Health System. Id. at 199. Petitioner stated that he had received a flu
vaccination on Friday (October 21) and had begun experiencing weakness of the
hands on Sunday (October 23). Id. By Monday (October 24) he began walking
slowly, and he was unable to walk by Tuesday. Id. A “Faculty Attestation” from the
attending neurologist noted that Petitioner had a flu vaccination a “few days ago
and the next day noticed weakness and the following day unable to walk.” Id. at
203.
• Petitioner underwent an EMG/NCS study on October 31, 2016. Id. at 152. The
medical history provided indicated that Petitioner had weakness of the arms and
legs since “~8 days ago” (or October 23rd). Id. Petitioner also stated that he
received a flu vaccination two days prior to the onset of symptoms. Id.
• On November 1, 2016, Petitioner had a rehabilitation consultation for treatment of
upper and lower extremity weakness. Id. at 139. Petitioner reported that he had
received a flu vaccine about three days prior to the onset of his symptoms. Id.
• On November 11, 2016, Petitioner had an internal medicine consultation for
treatment of a fever. Ex. 3 at 184-88. Petitioner reported that he had been
administered a flu vaccine two days prior to the start of his weakness. Id. at 185.
• On September 27, 2020, Petitioner filed an affidavit providing a timeline of his
symptom onset following the October 21, 2016 vaccination.9 Ex. 21. Petitioner
averred that he noticed weakness in his hands at 10 PM on October 23, 2016. Id.
at 1. Petitioner further stated that he began experiencing difficulty using his hands
and walking over the following two days. Id. at 1-2.
The records above provide varying dates regarding the onset of Petitioner’s GBS.
Nevertheless, I find that the cumulative record evidence preponderantly supports an
9 Petitioner previously filed a timeline of his symptom onset in conjunction with his Petition (Ex. 4), which is
consistent with the September 27, 2020 timeline.
6

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 7 of 8
onset of less than three days after vaccination. In making this determination, I find the
records associated with Petitioner’s October 26, 2016 neurological consultation to be
especially probative. These records specifically include a day-by-day description of
Petitioner’s early symptoms. Indeed, the examining neurologist recorded that Petitioner
received a flu vaccination on Friday, October 21, 2016, and began experiencing
weakness of the hands on Sunday, October 23, 2016. Ex. 11 at 199. Petitioner was further
noted to have begun walking slowly on Monday, October 24, 2016 with a complete
inability to walk the following day. Id. In addition to being detailed and contemporaneous
with the events described therein, these records comport with Petitioner’s affidavit and
the timeline he provided regarding his symptom onset.
There are other onset concessions made by Petitioner in this case. In his brief,
Petitioner notes that after speaking to his expert, “it appears the weakness in [his] hands
54-55 hours of vaccination may represent the first objective sign of GBS/AIDP alleged to
be caused by vaccination.” Br. at 2. Petitioner further acknowledges that his post-
vaccination symptoms do not appear to comport with the timeline prescribed in the Table.
Id. Even so, Petitioner states that he does not concede that he cannot establish a flu-GBS
Table claim because further expert input, or other evidence, might show that his initial
symptoms were unrelated to the onset of GBS. Id. at 2-3. Petitioner therefore requests
that I transfer this matter out of SPU without dismissing the flu-GBS Table claim. Id. at 3.
I have considered Petitioner’s arguments but do not find them persuasive. Initially,
as described, both Petitioner and his expert appear to admit that Petitioner’s GBS
symptoms began less than three days after vaccination. I further note that Petitioner’s
initial post-vaccination symptoms, including weakness, are consistent with GBS based on
the Table’s Qualifications and Aids to Interpretation and my prior experience adjudicating
Program cases. See 42 C.F.R. § 100.3(c)(15)(ii) (listing weakness as a requirement for
the diagnosis of acute inflammatory demyelinating polyneuropathy). I therefore conclude
that further factual development and expert input are not needed to determine that the
onset of Petitioner’s GBS occurred less than three days after vaccination – outside the 3-
42 day Table onset period. Accordingly, Petitioner’s Table Claim for flu-GBS is
dismissed. Because the matter no longer includes a Table claim (and otherwise cannot
be decided, as discussed below, in an expedited timeframe), it is appropriate to transfer
it out of SPU.
In his brief, Respondent questions the viability of Petitioner’s remaining non-Table
causation-in-fact claim, asserting that there may not be a reasonable basis for Petitioner
to retain an expert in furtherance of it. Opp. at 2-4. Respondent specifically references
the issues regarding the early onset of Petitioner’s GBS, and also notes that Petitioner
had a pre-vaccination history of gastrointestinal illness – a possible alternative cause.
7

Case 1:18-vv-01625-UNJ Document 53 Filed 04/19/21 Page 8 of 8
See 42 U.S.C. § 300aa-13(a)(1)(B) (noting that compensation shall not be awarded if a
preponderance of the evidence indicates the illness, disability, injury, condition, or death
described in the petition is due to factors unrelated to the administration of the vaccine
described in the petition).
I have considered Respondent’s arguments. Although Respondent raises issues
that may ultimately prevent an entitlement finding in Petitioner’s favor, the present record
is insufficiently developed to resolve a non-Table version of this claim. Petitioner could
establish, for example, through expert testimony or other persuasive evidence, that the
specific circumstances of this case explain an earlier-than-usual onset, despite what is
known about GBS’s pathogenesis. He may also be able to rebut arguments regarding
alternative cause. For these reasons, dismissal of the entire case would be premature.
Rather, Petitioner should be permitted to proceed with his remaining non-Table
causation-in-fact claim after this case is transferred out of SPU.
CONCLUSION
• For the reasons described above, Petitioner’s flu-GBS Table Claim is dismissed.
• Pursuant to Vaccine Rule 3(d), I will issue a separate order reassigning this case
randomly to a Special Master.
IT IS SO ORDERED.
s/Brian H. Corcoran
Brian H. Corcoran
Chief Special Master
8

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DOCUMENT 2: USCOURTS-cofc-1_18-vv-01625-3
Date issued/filed: 2026-04-20
Pages: 39
Docket text: PUBLIC RULING (Originally filed: 3/25/2026) regarding 141 Ruling on Entitlement. Signed by Special Master Mindy Michaels Roth. (nb) Service on parties made.
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Case 1:18-vv-01625-UNJ Document 145 Filed 04/20/26 Page 1 of 39
In the United States Court of Federal Claims
OFFICE OF SPECIAL MASTERS
No. 18-1625V
Filed: March 25, 2026
* * * * * * * * * * * * *
ROY ROMERO, *
*
Petitioner, *
*
*
v. *
*
SECRETARY OF HEALTH *
AND HUMAN SERVICES, *
*
Respondent. *
*
* * * * * * * * * * * * *
Michael A. Baseluos, Esq., Baseluos Law Firm, PLLC, San Antonio, TX, for petitioner.
Naseem Kourosh, Esq., U.S. Department of Justice, Washington, DC, for respondent.
RULING ON ENTITLEMENT1
Roth, Special Master:
On October 19, 2018, Roy Romero (“petitioner”) filed a petition for compensation under
the National Vaccine Injury Compensation Program, 42 U.S.C. §300aa-10, et seq.2 (the “Vaccine
Act” or “Program”). The petition alleged that Mr. Romero developed acute inflammatory
demyelinating polyneuropathy (“AIDP”) from the influenza (“flu”) vaccination he received on
October 21, 2016. Petition, ECF No. 1. He later amended the petition to clarify that AIDP is also
known as “GBS,” or Guillain-Barré syndrome. Amended Petition, ECF No. 13.
On December 18, 2023, petitioner filed the instant Motion for Ruling on the Record. ECF No.
125. Following careful review of all evidence, I find that petitioner has provided preponderant
evidence that his flu vaccine was a substantial factor in causing his GBS and that but for the
1 Because this Ruling contains a reasoned explanation for the action taken in this case, it must be made publicly
accessible and will be posted on the United States Court of Federal Claims’ website, and/or at
https://www.govinfo.gov/app/collection/uscourts/national/cofc, in accordance with the E-Government Act of 2002.
44 U.S.C. § 3501 note (2018) (Federal Management and Promotion of Electronic Government Services). This means
the Ruling will be available to anyone with access to the internet. In accordance with Vaccine Rule 18(b), the parties
have 14 days to identify and move to redact medical or other information, the disclosure of which would constitute an
unwarranted invasion of privacy. Any changes will appear in the document posted on the website.
2 National Childhood Vaccine Injury Act of 1986, Pub. L. No. 99-660, 100 Stat. 3755. Hereinafter, for ease of citation,
all “§” references to the Vaccine Act will be to the pertinent subparagraph of 42 U.S.C. § 300aa (2018).

Case 1:18-vv-01625-UNJ Document 145 Filed 04/20/26 Page 2 of 39
vaccination he would not have developed GBS.
I. Procedural History
The petition was filed on October 19, 2018, and assigned to the Special Processing Unit
(“SPU”). Petition, ECF No. 1; ECF No. 5.
Petitioner filed medical records through December 12, 2021, ECF Nos. 1, 10, 12, 14, 15,
22, 25, 29, 30, 32, 33, 57, 59, 63, 67, and 68, when he filed his fourth and final statement of
completion. ECF Nos. 9, 16, 34, 69. Respondent filed his Rule 4(c) Report on May 14, 2020,
arguing that petitioner could not show a causal link between the flu vaccine and his GBS. ECF No.
41.
Thereafter, an Order to Show Cause issued for petitioner to show cause as to why his Table
claim should not be dismissed. ECF No. 43. On March 11, 2021, the Chief Special Master issued
his Findings of Fact and Conclusions of Law dismissing petitioner’s Table claim. ECF No. 50.
The case was permitted to proceed on causation in fact.
The claim was then reassigned to me. ECF No. 52. A status conference was held following
which petitioner was ordered to file updated medical records, a supplemental affidavit, and all
documentation supporting his alleged damages. ECF No. 54.
Petitioner then filed expert reports and supporting medical literature. Petitioner’s Exhibits
(“Pet. Ex.”) 42-49, 52-54, ECF Nos. 74-80, 89-93, 107-08, 117-20, 122-23. Respondent also filed
expert reports and medical literature. Respondent’s Exhibits (“Resp. Ex.”) A-G, ECF Nos. 82-86,
99, 101, 114-15.
At the July 26, 2023, status conference, the parties requested to file supplemental expert
reports and agreed to proceed with a Motion for Ruling on the Record. ECF No. 113. Petitioner
filed the instant Motion on December 18, 2023. ECF No. 125. Respondent filed his Response on
March 18, 2024. ECF No. 130. Petitioner filed his Reply on April 18, 2024. ECF No. 131. Based
on the evidence in the record and arguments of the parties, I determined that the parties have had
a fair and complete opportunity to be heard.
This matter is now ripe for decision.
II. Factual Background
The detailed medical history that follows includes but is not limited to the factual findings
made by the Chief Special Master in his Ruling on Onset, petitioner’s Motion for Ruling on the
Record, respondent’s Response to the Motion for Ruling on the Record, petitioner’s Reply and
Respondent’s Rule 4(c) report along with a thorough review of all the medical records filed.
A. Medical History Prior to Vaccination
Petitioner was born on June 26, 1967. Pet. Ex. 1 at 1.
2

Case 1:18-vv-01625-UNJ Document 145 Filed 04/20/26 Page 3 of 39
Petitioner received medical care when needed at Ramos Family Medical Group and Texas
MedClinic, an urgent care clinic, since 2014. He had no documented history of any prior health
issues. Pet. Ex. 7 at 7.
On October 5, 2016, petitioner presented to Texas MedClinic reporting body aches, chills,
eye burning, throat pain, hoarse voice, pain on inspiration, chest and stomach pain, excessive thirst,
decreased appetite, and 102° fever. Pet. Ex. 7 at 1. Examination was normal but for nasal discharge.
Id. A/B flu testing was negative. Id. at 5. See Pet. Ex. 8 at 5. He was diagnosed with flu-like
symptoms and was prescribed Bentyl for stomach cramping with instructions to return if
necessary. Pet. Ex. 7 at 1, 4.
Four days later, on October 9, 2016, petitioner presented to the emergency room (“ER”) at
Mission Trails Baptist Hospital (“Mission Trails”) reporting abdominal pain that started on
October 4, 2016, associated with consuming bad fast food. Pet. Ex. 15 at 14. He reported fever,
chills, and diarrhea each time he ate or drank, four to five times a day, with stomach pain improved
after bowel movements. Id. at 14, 22. Petitioner also reported a history of consuming alcohol,
typically one to two beers weekly, but had binge drank over the weekend, approximately 12 cans
of beer. Id. at 5, 22.
Petitioner presented because his stomach pain had worsened. There was no vomiting, but
he did report some episodes of nausea. Pet. Ex. 15 at 14. He had a fever of 102° at a recent urgent
care visit days before and was treated with fluids. Id. He had upper abdominal tenderness on
examination but no fever. Id. at 15, 17, 24. A CT and ultrasound of the abdomen revealed a fatty
liver and gallstones without inflammation. Id. at 18. Stool testing revealed fecal leukocytes3
indicating infection or inflammation but no parasites, campylobacter infection, or shigella toxin.
Id. at 122. Blood work revealed elevated AST,4 CRP,5 lipase,6 glucose,7 and A .8 Id. at 116-119.
1C
The diagnoses included diabetes mellitus (“DM”) and acute pancreatitis. Id. at 2. It was unclear if
petitioner’s pancreatitis was the cause of his diarrhea, if his elevated lipase was due to viral
gastroenteritis, or if his drinking was the cause. Id. at 5, 15. He was treated with ciprofloxacin9 and
3 A leukocyte is a type of “colorless blood cell.” Leukocytes are also called “white blood cell[s].” “Leukocyte,”
Dorland’s Illustrated Medical Dictionary 1015 (33rd ed. 2020).
4 Aspartate transaminase, or “AST,” is “an enzyme . . . present in most eukaryotic cells.” “The serum level of [AST]
. . . [is] frequently elevated in a variety of disorders causing tissue damage.” “Aspartate Transaminase,” Dorland’s
Illustrated Medical Dictionary 161 (33rd ed. 2020).
5 A c-reactive protein, or “CRP,” is “the most predominant of the acute-phase proteins.” “C-reactive Protein,”
Dorland’s Illustrated Medical Dictionary 1509 (33rd ed. 2020). A high-sensitivity CRP test is used to “determine the
level of CRP in the blood.” “[A]s the hs-CRP rises, the risk of cardiovascular disease increases.” “High-sensitivity C-
reactive Protein Test,” Dorland’s Illustrated Medical Dictionary 1862 (33rd ed. 2020).
6 Elevated lipase levels in the blood “are seen in impaired liver function and pancreatitis.” “Lipase Test,” Dorland’s
Illustrated Medical Dictionary 1864 (33rd ed. 2020).
7 Blood glucose testing is “a direct measurement of the blood glucose level. It is most commonly used in the evaluation
of diabetic patients.” Kathleen Deska Pagana & Timothy J. Pagana, Mosby’s Manual of Diagnostic and Laboratory
Tests 267 (3rd ed. 2006). “In general, true glucose elevations indicate diabetes mellitus (DM).” Id. at 268.
8 Hemoglobin A levels “are increased in persons with poorly controlled diabetes mellitus.” “Hemoglobin A ,”
1C 1C
Dorland’s Illustrated Medical Dictionary 830 (33rd ed. 2020).
9 Also known as “Cipro,” ciprofloxacin is an “antibacterial effective against many” bacteria, including many
penicillin-resistant strains. “Ciprofloxacin,” Dorland’s Illustrated Medical Dictionary 357 (33rd ed. 2020).
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Flagyl for possible C. Difficile (“C Diff”) due to the presence of fecal leukocytes. C-diff testing
was negative. Id. at 121. The elevated AST was thought to be due to a fatty liver. Id. at 15.
The diarrhea and stomach pain resolved by the next day. Pet. Ex. 15 at 101. Petitioner was
discharged on October 11, 2016, with diagnoses of acute pancreatitis without necrosis or infection,
likely secondary to binge drinking on the weekends; viral intestinal infection NOS (not otherwise
specified); and DM for which Metformin and Glipizide were prescribed. Pet. Ex. 15 at 3-5, 14-15,
18, 98. He was to follow up with CentroMed as soon as possible since he did not have a primary
care physician (“PCP”). Id. at 5.
Petitioner returned to Mission Trails on October 15, 2016, reporting chest pain. Pet. Ex. 15
at 198, 200. Troponin10 levels were elevated. Id. at 447. The thought was recurrent pancreatitis,
but petitioner reported that his pain was different and thought it was due to his new DM medication.
Id. at 199. He was admitted. Cardiology evaluation revealed T wave changes on EKG. Id. at 201.
Lipase was abnormal and amylase11 was suggestive of pancreatic disease. Id. Echocardiogram was
normal. There was no coronary artery disease seen during heart catheterization, only suspected
microvascular disease. Id. at 295, 365. Some ischemia was noted on stress testing. Id. at 371, 472.
Petitioner had severe stomach pain while hospitalized that resolved, but his discharge summary
included “unusual” abdominal pain and bloating. He was to follow up with cardiology and for his
pancreatitis. Id. at 181-82. His white blood cell count (“WBC”)12 was elevated at 14,000, and
though his “readmission risk [was] high,” he stated that he wanted to go home. Id. at 182. No
antibiotic was prescribed but he needed to follow up with repeat labs in two days. Id. No CT
changes of his pancreatitis were noted, and his lipase remained elevated. Id. The diagnosis on
discharge was “Acute Pancreatitis.” Id. at 183.
B. Medical History Post-Vaccination
Petitioner presented to a new primary to establish care on October 21, 2016. His recent
diagnoses of diabetes, hypertension, pancreatitis, and his cardiac catheterization were noted. Pet.
Ex. 17 at 3. He had no complaints. His examination was normal with normal strength and intact
sensory. Id. at 3-4. He was taking DM medication and metoprolol.13Id. at 3-5. Blood work
performed that that day was abnormal including but not limited to inflammatory/oxidation levels
of myeloperoxidase14 of 1083 (at risk > 995); CRP of 186.6 (at risk >3.0); fibrinogen15 of 659 (>
10 Troponin is a “complex of globular muscle proteins . . . that inhibits contraction” of the muscle. “Troponin,”
Dorland’s Illustrated Medical Dictionary 1942 (33rd ed. 2020).
11 Amylase is a type of enzyme. Together with lipase, elevated levels are suggestive of pancreatitis. “Amylase,”
Dorland’s Illustrated Medical Dictionary 68 (33rd ed. 2020).
12 WBC, or “leukocyte count,” is the “determination of the number of leukocytes in the unit volume of blood.”
“Leukocyte Count,” Dorland’s Illustrated Medical Dictionary 420 (33rd ed. 2020).
13 Metoprolol is “a cardioselective β1-adrenergic blocking agent” often used to treat chest pain or high blood pressure.
“Metoprolol,” Dorland’s Illustrated Medical Dictionary 1138 (33rd ed. 2020).
14 Myeloperoxidase is an “oxidoreductase . . . [that] play[s] a role in oxygen-dependent killing of microorganisms and
tumor cells.” “Peroxidase,” Dorland’s Illustrated Medical Dictionary 1399 (33rd ed. 2020).
15 Fibrinogen is a coagulation factor and a plasma protein. “Fibrinogen,” Dorland’s Illustrated Medical Dictionary 694
(33rd ed. 2020).
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at risk at 493); interleukin-6 (“IL-6”)16 at 39.6 (at risk at >13); interleukin-8 (“IL-8”)17 at 52.6 (at
risk at >26); mildly elevated WBC at 11.9 (4.0-11.0); and elevated platelets18 at 550 (130-400).
Id. at 98-102. The subject flu vaccine was administered that day. Id. at 4.
Petitioner affirmed the onset of weakness in his hands at around 10:00 PM on October 23,
2016, which he believed was caused by the vaccination. By Tuesday, October 25, 2016, he could
not walk and presented to the doctor’s office that day. Pet. Ex. 4 at 5.19 Petitioner was diagnosed
with GBS on October 25, 2016, “while in the care of Dr. Neely. She was not the one to diagnose
but attended him at same facility [sic] at University of San Antonio Health System.” Id.
Petitioner presented to the ER at University Health System on October 26, 2016. Pet. Ex.
11 at 212. His recent hospitalization for pancreatitis on October 9, 2016, and prescriptions for
diabetes, high cholesterol, hypertension, and gastroesophageal reflux disease (“GERD”)
medications were noted. Id. Petitioner reported that since taking the medications, he had
experienced progressive weakness with difficulty performing fine motor tasks along with
decreased energy. Id.
Multiple ER physician assessments followed. One ER physician documented numbness
for five days, with bilateral lower extremity weakness and pain beginning two to three days prior.
Pet. Ex. 11 at 210. Another ER physician documented a normal state of health until four days prior,
numbness and weakness of the extremities beginning the day after, followed by fatigue and
tingling of both lower extremities and weakness with an inability to walk. Petitioner’s hands were
involved, and he had difficulty writing over the previous one to two days. Id. at 205, 207. Recent
gastrointestinal or upper respiratory infection was denied. Id. at 206. Examination revealed
weakness and absent reflexes. Id. at 205. The assessment was “[l]ikely Guillain Barre vs. atypical
ALS.” Id. at 207. A third ER physician documented bilateral lower extremity weakness for two to
three days that progressed upward to the upper extremities. Id. at 208. Neurology consultation was
ordered. Id. at 209.
Petitioner was evaluated by the neurology resident that same day. Pet. Ex. 11 at 199. He
reported a flu vaccine on Friday, October 21, 2016; weakness of his hands on Sunday, October 23,
2016; walking slowly on Monday, October 24, 2016; and inability to walk by Tuesday, October
25, 2016. Id. Examination revealed weakness and diminished/absent reflexes. Id. at 201. The
impression was “Guillain-Barre syndrome following vaccination.” Id. at 202. The attending
neurologist documented “flue [sic] like illness” and acute pancreatitis on October 9, 2016, receipt
of a flu vaccination a few days prior to this evaluation, weakness the following day, and inability
to walk the day after that. Id. at 203. The assessment was that petitioner’s symptoms were
16 Interleukin is a “generic term for a group of multifunctional cytokines that are produced by a variety of lymphoid
and nonlymphoid cells and have effects at least partly within the lymphopoietic system.” “Interleukin,” Dorland’s
Illustrated Medical Dictionary 937 (33rd ed. 2020). IL-6 is a lymphokine produced by certain cells, including T cells,
that stimulates immunoglobulin production by B cells. “Interleukin-6,” Dorland’s Illustrated Medical Dictionary 937
(33rd ed. 2020).
17 Interleukin-8 is a “chemokine” that may play a role in the discharge of certain white blood cells in inflammation.
“Interleukin-8,” Dorland’s Illustrated Medical Dictionary 937 (33rd ed. 2020).
18 A platelet is a “disk-shaped structure . . . found in the blood of all mammals and chiefly known for its role in blood
coagulation.” “Platelet,” Dorland’s Illustrated Medical Dictionary 1437 (33rd ed. 2020).
19 No record of the October 25, 2016, visit has been filed.
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“[u]nlikely to be related to the flue [sic] vaccine and [were] likely related to the flue [sic] like
illness in eaely [sic] October which also caused acute pancreatitis.” Id.
Blood work performed on October 27, 2016, included but was not limited to: strong
positive GM1 antibody 180 and GD1b antibody 395 (≥101),20 Pet. Ex. 11 at 69-70, and Pet. Ex. 3
at 691; A1C 9.0 [4.0-6.4], Pet. Ex. 11 at 71; elevated lipase on admission at 595 [350-373], Id. at
64; and ESR and CRP inflammatory markers elevated at 81 [0-20] and 62 [≥10 indicates
inflammatory process] respectively, Id. at 70. These results “could all be explained by
pancreatitis.” Id. at 168. At discharge, ESR was still elevated at 97 [0-20] but CRP was normal.
Id. at 78; Pet. Ex. 3 at 693. The clinical summary included GBS following vaccination. Pet. Ex.
11 at 2.
A lumbar puncture was consistent with AIDP, a variant of GBS. Pet. Ex. 11 at 168; Pet.
Ex. 3 at 687-689. EMG/NCS studies revealed axonal and demyelinating neuropathy consistent
with the axonal variant of AIDP. Pet. Ex. 11 at 155-156, 159. The EMG/NCS history included
weakness of the arms and legs beginning “~8 days ago,” October 23, 2016, with tingling that
started in the feet now affecting the hands. Id. at 152. There was no noted recent diarrheal illness,
but petitioner was noted to have received a flu shot two days before onset of symptoms. Id. The
attending neurologist found that the sensory fibers were spared from peripheral neuropathy on the
EMG/NCS but added that there could be abnormality in the future if AIDP was not of a pure motor
form. Id. Upper quadrant ultrasound revealed gallstones without inflammation. Id. at 84, 169.
An inpatient rehabilitation consultation was performed on November 1, 2016, for treatment
of upper and lower extremity weakness. Petitioner reported onset of symptoms about three days
after receipt of a flu vaccination with no recent illness. Pet. Ex. 11 at 139. Gabapentin and
nortriptyline were prescribed in turn for neuropathic pain. Id. at 135, 138. Petitioner received five
days of IVIg with improvement. He was discharged to Reeves Inpatient Rehabilitation (“Reeves”)
from November 2, 2016, to November 18, 2016. Id. at 139-140.
Petitioner’s history of flu vaccine two or three days prior to onset of symptoms was noted
upon admission to Reeves. Pet. Ex. 3 at 72, 184-185. By November 9, 2016, he was ambulating
with a walker. Id. at 154. On discharge, he had 4/5 strength throughout, was prescribed senna,
Colace, Tylenol with codeine, and Lipitor, and was instructed to follow up with his PCP and
neurology. Outpatient physical and occupational therapy was to continue. Id. at 240-241.
Petitioner presented to his PCP on November 23, 2016, with weakness, in a wheelchair,
and with many medication changes. Pet. Ex. 17 at 6. The assessment was type 2 diabetes with
hyperglycemia (primary); AIDP; hyponatremia;21 chronic pancreatitis; and vitamin D deficiency.
Id. His blood work continued to show elevated platelets, CRP, AST, and ALT. Id.
Petitioner presented for outpatient therapy on December 1, 2016, and received physical
20 GM autoantibodies “participate[] in the recognition of cells, compaction of myelin, signal transduction, and
1
chemokine binding.” They are “present in . . . [GBS], and other motor neuron diseases (MNDs), including [CIDP].”
“GM Autoantibodies,” Julius M. Cruse & Robert E. Lewis, Illustrated Dictionary of Immunology 297 (3rd ed. 2009).
1
21 Hyponatremia is a “deficiency of sodium in the blood.” “Hyponatremia,” Dorland’s Illustrated Medical Dictionary
892 (33rd ed. 2020).
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and occupational therapy throughout that month. Pet. Ex. 3 at 261, 267.
On December 21, 2016, petitioner presented for his first visit to UT Health San
Antonio/MARC. Pet. Ex. 16 at 4. He consistently reported his history following his receipt of the
flu vaccine. Id. He now had tingling and pain in his hands with cramping in his lower extremities
which interfered with sleep. He was unable to walk. He had diminished strength with EMG/NCS
testing suggestive of a motor variant of AIDP due to intact sensation. Id. at 5-6. His history
included flu vaccination, DM, and pancreatitis at the beginning of October 2016. Lyrica and
Tylenol #3 were prescribed, along with a follow-up with his PCP, physiatry, continued PT/OT and
a return in six months. Id.
That same day, December 21, 2016, petitioner presented to the ER at University Hospital
with right upper quadrant pain, nausea, and vomiting that began that afternoon. Pet. Ex. 3 at 277.
Ultrasound revealed gallbladder sludge and fatty liver with fibrosis. Id. at 378. Liver enzymes were
elevated and attributed to atorvastatin which had been prescribed in November. Lipase was normal.
Id. at 285-286. He was prescribed Cipro for abnormal urinalysis. He was to follow up with his
PCP. Id. at 287.
Petitioner presented to his PCP on December 23, 2016, for right upper quadrant pain and
elevated LFTs. CT and ultrasound showed no acute findings. His statin was stopped. Pet. Ex. 17
at 8. He had pain and was in a wheelchair. Id. at 9. He had normal motor strength in his upper and
lower extremities with intact sensory and cerebellar function. Id. at 10. He was referred to a
gastroenterologist. Id. at 10.
A hepatobiliary scan on December 28, 2016, revealed obstruction of a cystic duct and
petitioner was referred to general surgery. Pet. Ex. 2 at 92; Pet. Ex. 17 at 14-15. On December 30,
2016, he was admitted to Baptist Health for surgery of an obstructed cystic duct of the gallbladder.
Pet. Ex. 14 at 5, 12, 132. Chronic inflammation was found, and only partial gallbladder removal
could be performed with drain placement. Id. at 40-41. Flu vaccine was listed under allergies, with
GBS as the reaction. Id. at 235. Petitioner was discharged but returned later that day due to concern
about drainage from the drain. He was noted to be in a wheelchair due to GBS. Id. at 231, 234.
Petitioner’s follow-up examination with his PCP on January 12, 2017, was normal. Pet.
Ex. 17 at 17. The assessment included AIDP, type 2 diabetes without complication, long term
current use of insulin, and acute and chronic cholecystitis. Id. at 18.
Outpatient therapies resumed on January 23, 2017, with improvement noted since his initial
visit. However, petitioner still had significant deficits with fine motor control issues in his hands.
Pet. Ex. 3 at 298, 303.
On February 9, 2017, petitioner presented to his PCP for follow-up and FMLA paperwork.
Pet. Ex. 17 at 22-23. He attended the appointment in a wheelchair but was advised to walk for at
least an hour with 15-minute intervals of power walking and to engage in other exercise routines.
Neurological examination was normal. Id. Importance of glucose level monitoring was discussed.
Id. PT was to continue. Id. In an addendum, the PCP documented his discussion with petitioner’s
neurologist who advised that petitioner “developed AIDP soon after getting the flu shot, EMG, did
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have axonal loss which take[s] longer to recover from. . . .” Id. at 23.
A rehabilitation record from March 27, 2017, noted slow but ongoing progress with
mobility resulting from PT/OT. Petitioner was ambulating while holding on to a manual
wheelchair at home. He was able to walk 81 feet with a rolling walker while at PT with assistance.
Pet. Ex. 3 at 372. He had not followed up with neurology or been compliant with AFOs due to
poor fitting. The PT tried to adjust the AFOs with tape to make them more comfortable. Id. at 372-
373.
Insurance discontinued petitioner’s OT with his last visit on April 25, 2017. Pet. Ex. 3 at
462, 475. He had improved but he still had weakness. Id. at 462. His OT prescription was renewed
but denied by insurance. Id. at 475-476. Petitioner continued with PT with slow progress. He was
using a cane by July 2017 with continued weakness and imbalance by September 2017. Pet. Ex. 2
at 502; Pet. Ex. 3 at 554. He was discharged from PT on December 27, 2017, after 72 sessions. At
that time, he was ambulating in the clinic with no assistive device for more than 300 feet and he
used AFOs with improved balance. Pet. Ex. 3 at 637-638.
A rehabilitation examination on January 11, 2018, noted petitioner as being “better” with
improved function. He was walking up to 300 feet with a cane but was unable to return to work
because his employer had “no less physical options.” Pet. Ex. 3 at 640. He still had fatigue and
balance issues, but no pain. Lower extremities were near normal except for ankle flexion and great
toe strength. Id. Petitioner received referrals to vocational rehabilitation, aqua therapy, OT for
driving evaluation, mental health counseling for suspicion of depression, and a PCP. Sleep issues
and tremor were thought to be fatigue related. Id. at 644-45.
At a new OT evaluation on January 30, 2018, petitioner reported shooting pain in his
forearms and hands and decreased grip and pinching strength. Pet. Ex. 3 at 647. He received four
OT sessions and was discharged with home exercises. Id. at 661.
Improvement was noted at a May 3, 2018, rehabilitation examination, but petitioner still
had tremors causing incoordination, left hand cramps, and numbness and tingling in the ulnar nerve
distribution. Pet. Ex. 3 at 644. He still could not lift 40 pounds, which was a requirement for him
to return to his previous job. He brought FMLA paperwork for a six-month extension. He had not
secured a PCP, attended a driving evaluation, or seen a mental health specialist. Examination was
unchanged. New referrals were placed. He was started on Celexa for depression and melatonin for
sleep. Id. at 669.
Petitioner was officially terminated from his job on June 1, 2018, and he lost insurance
coverage. Pet. Ex. 4 at 2. His last OT visit was on June 4, 2018. Pet. Ex. 18 at 39. Insurance
authorized seven PT visits. Petitioner attended only five, last presenting on June 13, 2018, with
complaints of knees buckling and balance issues. He was discharged on October 15, 2018. Id. at
28.
A neurorehabilitation examination for functional recovery was conducted on October 25,
2018. The record included discharge from his job, receipt of social security, and attempt at job
placement, but petitioner reported that the salaries offered were not “adequate.” Pet. Ex. 18 at 20.
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Petitioner had continued weakness and fatigability of both upper and lower extremities. Id. His
tremor was stable and unchanged. He used bilateral dorsiflexion AFOs and a cane for ambulation.
Id. He had occasional leg cramping and neuropathic pain in his hands and he took Tylenol. Other
medications had proved ineffective and had undesirable side effects. His mood improved but he
had continued depression due to loss of function. He did not take Celexa regularly. Id. He had
fallen several times over the past six months. Id. at 22. The assessment was AIDP with residual
weakness and impaired gait and balance two years post-diagnosis with the potential for continued
improvement. Id. at 25. Petitioner did not have any flares or waxing and waning symptoms; he just
had not returned to his prior state of health. Functional outcome was difficult to predict due to
continued deficits. Outpatient therapies were recommended for maximum functional
independence. Id. at 25.
At an April 25, 2019, rehabilitation medicine follow-up, petitioner was doing well. He was
more active in the community and with family, but still unemployed with no goals of returning to
work. His mood and strength improved with more outside activities. He was receiving Medicare
and wanted to establish with a PCP. Pet. Ex. 18 at 9. He still had 4/5 strength bilaterally on ankle
flexion and extension and hand tremors. Id. He received information on vocational rehabilitation.
Id. He declined OT driving evaluation, however. Id. He also declined medication and counseling
for his mood disorder. Id. He was referred for neurology evaluation. Id. at 14. At that time, he had
no pain and walked with a cane. Id. at 15.
C. Petitioner’s Affidavits
Petitioner submitted four affidavits. Pet. Exs. 4, 5, 21, and 35.
In his first affidavit, petitioner affirmed being previously healthy and the sole financial
provider for his family, which included his wife, son, and three grandchildren. Pet. Ex. 4 at 1. He
detailed his daily activities, which included working the night shift as a restaurant manager
supervising eight to ten people, doing inventory, hiring, customer service, and supporting his team.
Id. He would arrive home about 8:30 AM, attend to home tasks, sleep from 10:00 AM to 3:00 PM,
pick up his grandchildren from school and his wife from work, take a nap, then go back to work.
Id. He was 49 years old at the time of the flu vaccination.
Following the vaccination, petitioner experienced paralysis from his waist down as well as
in his hands. Pet. Ex. 4 at 1-2. He required constant care and could do little for himself which
greatly affected his family, marriage, and ability to work. Id. at 2. His illness placed a financial
burden on his family. He lost his job and insurance, and suffered from depression, insomnia, mood
swings, and outbursts. Id. Petitioner detailed all the activities in which he engaged prior to the
vaccination and his work with an income of $50,000 per year. Id. at 3-4. Petitioner affirmed that
he lost his job on June 1, 2018, due to his vaccine-related injuries. However, his company paid
most of his medical bills. He detailed some out-of-pocket medical costs and affirmed that he was
in the process of obtaining Medicaid. Id. at 4. The “Sequence of Events” he provided following
receipt of the flu vaccination was consistent with what he reported to physicians upon presentation.
Id. at 5-6.
Petitioner’s second affidavit was an affirmation that no civil action was pending, and that
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petitioner had not received compensation for his vaccine related injuries. Pet. Ex. 5.
In a third affidavit filed on September 27, 2020, petitioner provided a timeline of events
starting with his receipt of the flu vaccine on Friday, October 21, 2016, between 4:00 and 5:00 PM
and ending with his presentation to the hospital on October 25, 2016. See generally Pet. Ex. 21.
This account included noticing weakness in his hands at around 10:00 PM on October 23, 2016,
and having trouble unbuttoning his pants. Id. at 1. By the following morning, petitioner noted an
inability to lift his feet and loss of strength in his hands. By Tuesday, he could not walk or stand
and had no hand strength at all. He was paralyzed from the waist down. Id. at 2. He was carried to
a vehicle and taken to the hospital. Id. at 2.
In a fourth affidavit, petitioner detailed his 15-year work history at Whataburger as of June
2016. Pet. Ex. 35 at 1. He worked ten hours a day, 50 or more hours a week, with 95% of his time
spent on his feet. Id. He had no prior medical or health complications that prohibited him from
performing his job. Id. Further, upon completing 15 years with the company in June 2016, he
received recognition. Petitioner would have been eligible for retirement at 20 years, though he
intended to keep working. Id. He dreamed of opening his own restaurant. Id.
Petitioner affirmed being diagnosed with GBS on October 25, 2016, following the flu
vaccine. Pet. Ex. 35 at 1-2. He was “hospitalized for 25 days with paralysis from [his] waist down
and in [his] hands.” Id. at 2. He was “unable to return to work” and was “wheelchair-bound for 18
months. In 2017 [he] was unable to return to work due to [his] paralysis.” In June 2017, he reached
16 years with his employer, and “was able to stay employed due to . . . accumulated sick time . . .
and vacation time.” Id. at 2. He was then put on FMLA and received long-term, but not short-term,
disability. Id.
According to petitioner, by 2018, he was still in a wheelchair. Pet. Ex. 35 at 2. Petitioner
underwent extensive physical therapy and progressed to using a walker. Id. He was terminated
from his job on June 1, 2018, before completing 17 years. Id. His health issues increased by the
end of that year. Id. He had a leg brace to maintain his balance and used a cane for support. Id. He
started seeing a psychiatrist to help with insomnia, anxiety, and depression in 2019.22 Id. As of
2020 he continued his therapy and visits to his doctor and psychiatrist. Id.
In 2021, he still had tremors, used an AFO on his foot and leg, was unable to walk without
falling, and had chronic fatigue and depression. Pet. Ex. 35 at 2. He could not stand for more than
20 minutes before getting tired and needing to sit down. He often took naps. Id.
Petitioner affirmed that he has received Medicare, which covers 80% of his therapies, as
of April 2019. Pet. Ex. 35 at 3. He received long term disability of $836 per month, which at the
time of his affidavit had been extended for another year. Id. Lastly, he received social security
benefits and long-term disability payments which made up the difference of his pay. Id. at 3.
22 No psychiatry records were filed in this matter.
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III. Expert Opinions
What follows is a broad overview of each expert’s opinions and conclusions. The details
of each expert’s reports are discussed more fully in Section V below.
A. Petitioner’s Experts
1. Dr. Marcel Kinsbourne23
Dr. Kinsbourne wrote five reports. Pet. Exs. 45, 47, 49, 53, and 54.24
Dr. Kinsbourne began by summarizing petitioner’s medical history. He claimed that
petitioner’s diagnosis of GBS is undisputed, as is “the proposition that influenza vaccination can
trigger GBS.”25 Pet. Ex. 45 at 4. For this reason, Dr. Kinsbourne did not address Prong I in his first
report. Id. He generally deferred to petitioner’s immunology expert, Dr. Akbari, for his analysis of
how the flu vaccine can cause GBS. Dr. Kinsbourne agreed with Dr. Akbari that “molecular
mimicry and induction of inflammasome are credible medical theories linking the flu vaccination
to injuries that [petitioner] experienced.” Pet. Ex. 49 at 4.
Dr. Kinsbourne acknowledged that the Vaccine Table provides for symptom onset of GBS
following flu vaccination within three to 42 days but claimed that the three- to 42-day onset was
an “interval [] imposed by a committee, for administrative rather than medical reasons.” Pet. Ex.
45 at 4. Epidemiological studies impose a risk interval of zero to 42 days with no exclusions of
onset within the first two days. Id.; Pet. Ex. 45 Ref No. 5;26 Pet. Ex. 45 Ref No. 4.27 Most
importantly, Park, et al. found that “[m]ore than half the cases (54%) occurred within 2 days after
the vaccination.” Pet. Ex. 45 at 5 (citing Pet. Ex. 45 Ref No. 428 at Fig. 1). Thus, petitioner’s onset
of 54-58 hours post-vaccination satisfies Prong III.
Dr. Kinsbourne also addressed the issue of potential alternative causes. He first noted that,
23 Dr. Kinsbourne graduated from Oxford University in England with a B.M., B.Ch., the equivalent of an American
M.D. He became licensed in the United States in 1967. Dr. Kinsbourne has served as an associate professor in
pediatrics and neurology and a senior research associate at Duke University Medical Center before holding a series of
academic positions, including professorships in pediatrics, neurology, and psychology. His clinical experience
includes serving as a senior staff physician in Ontario from 1974-1980 and a clinical associate in neurology at
Massachusetts General Hospital from 1981-1991. See generally Pet. Ex. 44.
24 The National Vaccine Injury Compensation Program’s Guidelines for Practice Section II, Chapter 3(B)(12) states
that “[i]f medical literature accompanies the expert report, each article should be filed as a separate exhibit,” rather
than as attachments to the expert report. Petitioner’s medical literature should have been filed with consecutive exhibit
numbers.
25 Not so. Respondent specifically notes that he “has not conceded Althen prong one is all flu/GBS cases because of
respondent’s decision to add flu/GBS to the Table or because respondent has decided not to defend certain flu/GBS
cases.” Resp. Br., ECF No. 130 at 29.
26 Lawrence B. Schonberger, et al., Guillain-Barre Syndrome Following Vaccination in the National Influenza
Immunization Program, United States, 1976-1977, 110 Am. J. of Epidemiology 105 (1979), filed as “Pet. Ex. 45 Ref
No. 5” and “Resp. Ex. A-17.”
27 Yong-Shik Park, et al., Clinical Features of Post-Vaccination Guillain-Barré Syndrome (GBS) in Korea, 32 J. of
Korean Med. Sci. 1154 (2017), filed as “Pet. Ex. 45 Ref No. 4,” “Pet. Ex. 43 Ref No. 23,” and “Pet. Ex. 48 Ref No.
3.”
28 Id.
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while petitioner’s records diagnose him with a flu-like illness on October 5, 2016, Pet. Ex. 7 at 2,
petitioner tested negative for influenza A and B. Pet. Ex. 45 at 5. Petitioner also did not present
with respiratory symptoms and did not have a cough, running nose, or shortness of breath. Id.
Thus, “[t]here is no evidence supporting the presence of respiratory or gastrointestinal virus
infection.” Id. at 8.
Petitioner then presented on October 9, 2016, with what Dr. Kinsbourne argued was
“plainly [] a gastrointestinal issue, with nausea, vomiting, cramps and diarrhea, as well as
continued fever” which were symptoms of mild acute pancreatitis. Id. Dr. Kinsbourne
distinguished two studies which observed cases of pancreatitis followed by GBS or polyneuritis,
both of which presented as severe cases of pancreatitis with accompanying complications. Id.; Pet.
Ex. 45 Ref No. 1;29 Pet. Ex. 45 Ref No. 2.30 He thus found that “[t]he antecedent acute pancreatitis
has not been shown to trigger GBS.” Pet. Ex. 45 at 8.
Dr. Kinsbourne concluded that petitioner’s onset is “fully consistent with empirical
evidence in the medical literature on GBS” and that there was no plausible alternative cause for
petitioner’s GBS other than the flu vaccine. Pet. Ex. 45 at 8.
2. Dr. Omid Akbari31
Dr. Akbari wrote four reports. Pet. Ex. 43; Pet. Ex. 46; Pet. Ex. 48; Pet. Ex. 52.
Dr. Akbari is a Ph.D. in Cellular and Molecular Immunology. Pet. Ex. 42.
After providing a brief summary of petitioner’s medical history, Dr. Akbari detailed the
“commonly implicated mechanism” of molecular mimicry to explain how the flu vaccine can
cause GBS. Pet. Ex. 43 at 6. Molecular mimicry occurs when there is a “sharing of antigens
between a host and a microorganism.” Id. More specifically, this theory is implicated when “the
host and the microbe share an immunologic epitope by either sequence or conformational
homology.” Id.; Pet. Ex. 43 Ref No. 3.32 Dr. Akbari posited that significant protein peptide
sequence similarity between the host and the microorganism is no longer recognized as necessary
to induce molecular mimicry. Pet. Ex. 43 at 7. Rather, “conservation of only a few crucial residues
can allow for cross-reactivity of immune cells.” Id.
29 M.L.P. Gross, et al., Peripheral Neuropathy Complicating Pancreatitis and Major Pancreatic Surgery, 51 J. of
Neurology, Neurosurgery, and Psychiatry 1341 (1988), filed as “Pet. Ex. 45 Ref No. 1.”
30 Aswathi Harikumar, et al., An Interesting Case of Acute Polyneuropathy in the Context of Acute Pancreatitis, 7 U.
J. of Med. And Med. Specialties 1 (2021), filed as “Pet. Ex. 45 Ref No. 2.”
31 Dr. Omid Akbari received his undergraduate degree and his M.S. in Medical and General Microbiology at University
College London. He received his Ph.D. in Cellular and Molecular Immunology from the National Institute for Medical
Research in London and was a postdoctoral fellow at Stanford University. He is currently a tenured Professor of
Immunology in the Department of Molecular Microbiology and Immunology and the Department of Medicine at the
Keck School of Medicine at the University of Southern California, Los Angeles, an Adjunct Professor of Immunology
and Medicine at the Department of Immunology at Chiba University, and an Adjunct Professor of Pediatrics-Medicine
at the David Geffen School of Medicine at the University of California-Los Angeles-Harbor. See generally Pet. Ex.
42.
32 Robert S. Fujinami, et al., Molecular Mimicry, Bystander Activation, or Viral Persistence: Infections and
Autoimmune Disease, 19 Clinical Microbiology Rev. 80 (2006), filed as “Pet. Ex. 43 Ref No. 3.”
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Vaccination causes an inflammatory reaction that is mediated by the cells of the innate
immune system. Pet. Ex. 43 at 7. The immune system’s ability to recognize and eliminate foreign
antigens, induce immunologic memory, and develop tolerance to self-antigens results in effective
homeostasis. When homeostasis is disrupted and the immune system responds in favor of
activation, as in response to vaccination, the host is susceptible to autoimmunity. Id. at 14. In GBS,
research indicates that this balance is being disrupted leaving the host susceptible to an adverse
autoimmune reaction upon stimulation of the immune system from infection or vaccination,
mediated by activation of inflammasome.
Dr. Akbari identified six amino acids in the flu vaccine that have “high homology” to the
“myelin basic protein sequence.” Pet. Ex. 43 at 14. He also cited to studies which he argues
“suggest that the influenza vaccine that [petitioner] received contains a protein that cross-reacts
with myelin based antigens in humans who had demyelinating disease.” Id. at 13; Pet. Ex. 43 Ref
No. 34;33 Pet. Ex. 43 Ref No. 35.34
Dr. Akbari also opined that petitioner’s “history of inflammation, diarrhea and subsequent
development of pancreatitis” sensitized petitioner prior to his flu vaccination which made him
more likely to develop GBS as a result of the flu vaccine. Pet. Ex. 43 at 19.
Lastly, Dr. Akbari argued that highly activated T cells which secrete proinflammatory
cytokines can, within as soon as 36 hours following the inciting event, cause injury and
demyelination. Pet. Ex. 43 at 19; Pet. Ex. 43 Ref No. 56.35 These T cells, together with innate like
lymphocytes (“ILLs”) which can produce cytokines and cause adverse effects within a few hours
of stimulation, can cause fast-acting symptoms like those experienced by petitioner. Pet. Ex. 43 at
9-10, 19.
Thus, Dr. Akbari argued that petitioner met each of the three Althen prongs.
B. Respondent’s Experts
1. Dr. Dara Jamieson36
Dr. Jamieson wrote three reports. Resp. Exs. A, C, and F.
33 Silva Markovic-Plese, et al., High Level of Cross-Reactivity in Influenza Virus Hemagglutinin-Specific CD4+ T-
Cell Response: Implications for the Initiation of Autoimmune Response in Multiple Sclerosis, 169 J. of
Neuroimmunology 31 (2005), filed as “Pet. Ex. 43 Ref No. 34.”
34 Kai W. Wucherpfennig and Jack L. Strominger, Molecular Mimicry in T Cell-Mediated Autoimmunity: Viral
Peptides Activate Human T Cell Clones Specific for Myelin Basic Protein, 80 Cell 695 (1995), filed as “Pet. Ex. 43
Ref No. 35.”
35 Richard M. Ransohoff, et al., Three or More Routes for Leukocyte Migration into the Central Nervous System, 3
Nature Rev. Immunology 569 (2003), filed as “Pet. Ex. 43 Ref No. 56.”
36 Dr. Jamieson received her A.B. from George Washington University with honors in zoology and physics in 1976.
In 1982, she received her M.D. from the University of Pennsylvania School of Medicine and underwent postgraduate
study at the University of Pennsylvania’s Department of Biochemistry and Biophysics. Dr. Jamieson worked as a
neurologist at various hospitals between 1989 and 2018, and as the Director of the Section of Neurovascular Neurology
and Cerebrovascular Neurosurgery at Wills Eye Hospital from 1997 to 1999, and the Co-Director of the Neurovascular
Laboratory at New York Presbyterian Hospital from 2009 to 2018. Dr. Jamieson is currently licensed to practice in
New York state. See generally Resp. Ex. A-1.
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Dr. Jamieson summarized petitioner’s medical history and detailed his presentation on
October 5, 2016, as body aches, fever, chills, eye burning, and decreased appetite. Resp. Ex. A-2
at 2; Pet. Ex. 7 at 1-5. She added that a form filled out for that visit included fever, chills, pain with
deep breath, weakness in petitioner’s arms and legs, eye pain and pressure, watery or itchy eyes,
throat pain, hoarseness, chest pain, muscle aches, change in appetite, abdominal pain, and
excessive thirst. Resp. Ex. A-2 at 2; Pet. Ex. 7 at 1-2. Petitioner was febrile with a 102° fever, was
tachycardic with decreased blood pressure, and was congested and notably sweating. A
handwritten note included “flu-like symptoms” with a billing code for influenza. The evaluation
was done by a nurse practitioner who prescribed Bentyl. An influenza A/B test was negative.
Continuing, petitioner was admitted to the hospital on October 9, 2016, for five to six days
for abdominal pain and cramps, nausea, and diarrhea. He reported drinking six-packs of beer over
the weekend. Examination revealed right upper quadrant tenderness. Lipase was elevated.
Ultrasound of the gallbladder and CT scan of the abdomen and pelvis were unremarkable. Resp.
Ex. A-2 at 2; Pet. Ex. 20 at 124-125. The assessment was acute pancreatitis with diarrhea, treated
with bowel rest, morphine, and fluids. Resp. Ex. A-2 at 2; Pet. Ex. 20 at 13-14. The discharge
summary included acute pancreatitis of uncertain etiology, possibly related to viral infection,
resolved gastroenteritis, also suspected to be viral in etiology, newly discovered type 2 diabetes,
and a history of binge drinking. Resp. Ex. A-2 at 2; Pet. Ex. 20 at 2-3.
Dr. Jamieson then described GBS as a group of autoimmune disorders with acute
inflammatory demyelinating polyneuropathy (“AIDP”) being the most common in the United
States. Resp. Ex. A-2 at 7. GBS and AIDP are thus often referred to interchangeably. Id. GBS is
often triggered by infection, presents with rapid and progressive onset, and is monophasic. Id.
About two-thirds of patients report respiratory or gastrointestinal symptoms within four weeks of
onset of weakness, and typically within 10 to 14 days. Id.; Resp. Ex. C at 4; Resp. Ex. F at 2; Resp.
Ex. A-4;37 Resp. Ex. A-5;38 Resp. Ex. A-6.39 One-third of patients have no identified antecedent
event. Resp. Ex. A-2 at 7; Resp. Ex. C at 4.
Dr. Jamieson asserted that vaccination against respiratory infections has not been
consistently proven to be associated with GBS, unlike respiratory infection itself. Resp. Ex. A-2
at 9. While the risk of GBS increased during the influenza pandemic of 1976, the increased risk
was not associated with vaccination. Id.; Resp. Ex. A-11.40 See Resp. Ex. A-1241 and Resp. Ex.
A-1942 for studies finding slight or no increases in GBS risk upon vaccination. But see Resp. Ex.
37 Hugh J. Willison, et al., Guillain-Barré Syndrome, 388 Lancet 717 (2016), filed as “Resp. Ex. A-4.”
38 Peter D. Donofrio, Guillain-Barré Syndrome, 23 Continuum 1295 (2017), filed as “Resp. Ex. A-5.”
39 Helmar C. Lehmann, et al., Guillain-Barré Syndrome After Exposure to Influenza Virus, 10 Lancet Infectious
Diseases 643 (2010), filed as “Resp. Ex. A-6.”
40 Alexander D. Langmuir, et al., An Epidemiologic and Clinical Evaluation of Guillain-Barré Syndrome Reported in
Association with the Administration of Swine Influenza Vaccines, 6 Am. J. of Epidemiology 841 (1984), filed as “Resp.
Ex. A-11.”
41 J.O.T. Sipilä & M. Soilu-Hänninen, The Incidence and Triggers of Adult-Onset Guillain-Barré Syndrome in
Southwestern Finland 2004-2013, 22 Eur. J. of Neurology 292 (2015), filed as “Resp. Ex. A-12.”
42 Daniel A. Salmon, et al., Association Between Guillain-Barré Syndrome and Influenza A (H1N1) 2009 Monovalent
Inactivated Vaccines in the USA: A Meta-Analysis, 381 Lancet 1461 (2013), filed as “Resp. Ex. A-19,” “Pet. Ex. 48
Ref No. 1,” and “Pet. Ex. 43 Ref No. 22.”
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A-2043 for a study finding a “small but statistically significant association,” Resp. Ex. A-2 at 9,
between influenza vaccination and GBS. Studies have found that the risk of developing GBS
during the 42-day period following an acute gastrointestinal or acute respiratory infection was
increased compared to that of an infection-free period. The risk of developing GBS was found to
be comparable for both types of infection, like the infections that petitioner suffered prior to
developing GBS. Resp. Ex. A-2 at 10; Resp. Ex. A-16.44
Dr. Jamieson added that the risk interval of GBS is between three to 42 days as provided
by the Program. Resp. Ex. C at 1-2. She disagreed that 53 to 54 hours, or 2.2 days after vaccination,
provided a causative correlation between vaccination and symptom onset. Resp. Ex. A-2 at 10-11;
Resp. Ex. A-17.45 “The consensus has been, based on logical and immunological arguments, that
the period of presumed risk starts on day 3, not on day 2 as in the case of [petitioner].” Id. at 3.
Dr. Jamieson submitted that petitioner had “multiple systemic viral and bacterial infections,
including a flu-like illness, gastroenteritis, pancreatitis, bacteriuria, and cholecystitis” in the weeks
prior to vaccination with documented fever, tachycardia, low normal pulse oxygenation, sweating,
and congestion. Resp. Ex. A-2 at 12. The records noted that this infection was more likely the
triggering event for petitioner’s GBS than the flu vaccination. Resp. Ex. A-2 at 12; Resp. Ex. C at
3-4; Pet. Ex. 7 at 1-5; Pet. Ex. 20 at 197-199; Pet. Ex. 20 at 2-3. Dr. Jamieson added that two
months later, petitioner was treated with antibiotics for acute and chronic acalculous hemorrhagic
cholecystitis. Resp. Ex. A-2 at 12; Pet. Ex. 4 at 178. She argued that petitioner had AMAN, or
acute motor axonal neuropathy, a subset of GBS particularly associated with gastrointestinal
infections as the triggers: “His multiple preceding infections, including gastrointestinal infections,
are a more usual and accepted trigger for AMAN, than is vaccination.” Resp. Ex. A-2 at 12.
Dr. Jamieson disagreed that petitioner’s symptoms were attributed to an abundance of
inflammation consistent with the inflammatory nature of acute pancreatitis. Resp. Ex. C at 3-4;
Resp. Ex. F at 4. She asserted that petitioner “had multiple respiratory and systemic symptoms
indicative of a flu-like infection and he was congested on examination, not indicative of
pancreatitis.” Resp. Ex. C at 3.
Dr. Jamieson submitted that petitioner suffered from a flu-like illness, pancreatitis,
gastroenteritis, cholecystitis, and a non-ST-elevation myocardial infarction (“NSTEMI”) in the
three weeks prior to developing motor/axonal GBS which were the triggers for developing AMAN.
The flu vaccination 53 to 54 hours, or two days, prior to onset was not the “plausible trigger for
AMAN” or a cause of his neurological symptoms. Resp. Ex. A-2 at 13-14; Resp. Ex. F at 4, 14.
Petitioner continues to have neurological deficits from AMAN with superimposed diabetic
peripheral neuropathy diagnosed in 2021 and mainly sensory symptoms. His current disability is
a combination of diabetic neuropathy, which will worsen with age, and the mild residual effects
of AIDP that will improve with time. Resp. Ex. F at 2; Resp. Ex. A-2 at 13.
43 L.H. Martín Arias, et al., Guillain-Barré Syndrome and Influenza Vaccines: A Meta-Analysis, Vaccine (2015), filed
as “Resp. Ex. A-20.”
44 Clémence Grave, et al., Seasonal Influenza Vaccine and Guillain-Barré Syndrome: A Self-Controlled Case Series
Study, 94 Neurology 2168 (2020), filed as “Resp. Ex. A-16.”
45 Schonberger, et al., supra, note 26.
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“To a reasonable degree of medical probability, if [petitioner] had not received the flu
vaccine, he still would have developed GBS triggered by the preceding infections.” Resp. Ex. A-
2 at 13.
2. Dr. Stephen Tompkins46
Dr. Tompkins wrote three reports. Resp. Exs. B-1, D-2, and G.
Dr. Tompkins, like Dr. Akbari, is a Ph.D. with a specialty in immunology and molecular
pathogenesis. Resp. Ex. B-1 at 1.
Dr. Tompkins did not dispute petitioner’s diagnosis of GBS because he is not a clinician.
Resp. Ex. B-1 at 2-3. Dr. Tompkins disagreed that any evidence exists to support molecular
mimicry as the mechanism by which inactivated influenza vaccines can trigger GBS. Id. at 5-8.
He further disagreed that an inactivated flu vaccine could activate inflammasomes which would in
turn activate Th17 T cells triggering GBS. Id. at 8-10; Resp. Ex. D-2 at 7-13. Finally, Dr. Tompkins
disagreed that an onset of GBS could occur in fewer than three days. Rather, there were alternative
causes for petitioner’s GBS. Resp. Ex. G at 2-3.
Dr. Tompkins asserted that most relevant to this case is the more recent surveillance of
GBS conducted by Arya, et. als. which assessed risk windows of one to 42 days and eight to 21
days for all types of influenza vaccine during the 2015-16 and 2016-17 flu seasons and found no
excess risk for more than 13 million Medicare recipients of flu vaccines per risk period. Resp. Ex.
B-1 at 4; Resp. Ex. B-6.47 The components of the flu vaccines during these seasons were similar
to those Dr. Akbari suggested were responsible for triggering GBS in this case. Resp. Ex. B-1 at
4; Pet. Ex. 43 at 6, 13, 14, 18, 19. The proposed mechanisms by petitioner’s experts, including
molecular mimicry and inflammasome activation, that would accelerate vaccine-specific immune
responses simply do not substantiate a causal link. Resp. Ex. G at 11.
In contrast, Dr. Tompkins argued that upper respiratory and gastrointestinal infections are
strongly associated with GBS, with a peak interval of two to three weeks after antecedent event.
Petitioner’s medical records show that he suffered from both in the two to three weeks prior to the
onset of his GBS. Resp. Ex. B-1 at 10-11; Resp. Ex. D-2 at 13; Resp. Ex. G at 8, 12; Pet. Ex. 15
at 14; Pet. Ex. 45 Ref No. 5.48 Dr. Tompkins referenced the National Institute of Neurological
Disorders and Strokes to show that most cases of GBS occur a few days or weeks following
respiratory or gastrointestinal viral infection. Resp. Ex. B-1 at 10; Resp. Ex. B-18.49 Therefore,
petitioner’s interval onset of GBS “falls squarely within the accepted interval for onset of GBS
46 Dr. Tompkins received his B.S. in Microbiology from the University of Illinois in 1990 and his Ph.D. in Immunology
from Emory University in 1997. He performed post-doc research in immunology and virology at Northwestern
University Medical School and at CBER/FDA. Dr. Tompkins currently serves as the Director of the Center for
Influenza Disease and Emergence Research and as the Assistant Department Head of the Department of Infectious
Diseases in the College of Veterinary Medicine at the University of Georgia. See generally Resp. Ex. B-2.
47 Deepa P. Arya, et al., Surveillance for Guillain-Barré Syndrome After 2015-2016 and 2016-2017 Influenza
Vaccination of Medicare Beneficiaries, 37 Vaccine 6543 (2019), filed as “Resp. Ex. B-6.”
48 Schonberger, et al., supra, note 26.
49 Guillain-Barré Syndrome Fact Sheet, Nat’l Inst. of Health (Last Reviewed Apr. 25, 2022), NIH Publication No. 18-
NS-2902.
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following an antecedent event,” and “also falls within a reasonable timeline for an immune
response to the infection to elicit clinical disease.” Resp. Ex. B-1 at 10. The anti-ganglioside GD1b
and GM1 antibodies detected on October 27, 2016, would have had the time necessary to be
elicited by an infection beginning about 21 days before. Id.; Pet. Ex. 18 at 1520.
Rather than responding to the Court’s question of whether “it [was] more probable that the
combination of all of petitioner’s health issues along with his receipt of the flu vaccine during that
three-and-a-half-week period resulted in his development of GBS,” Dr. Tompkins raised two
questions of his own: 1) Could any of the events noted in petitioner’s medical history result in the
onset of GBS between two days and two to three weeks later without requiring an additional
exacerbating event?, and 2) Could multiple infections, uncontrolled diabetes, and/or
catheterization have been in the process of eliciting GBS such that receipt of the influenza vaccine
rapidly, in less than three days, triggered petitioner’s GBS? Resp. Ex. G at 2; ECF No. 110 at 2.
Dr. Tompkins, responding to his own first question, asserted that infections are the most
common triggers of GBS in 75% of cases. Resp. Ex. G at 2. He added that influenza A/B testing
is only 73% to 78% accurate and petitioner’s test may have showed a false negative, failing to rule
out his suffering an influenza illness two to three weeks before vaccination. Resp. Ex. B-1 at 10;
Resp. Ex. B-20.50
Dr. Tompkins asserted that his own second question was difficult to answer because, while
the mechanisms for how viral infections can cause GBS are generally accepted, how flu
vaccination could trigger GBS is significantly less so. Resp. Ex. G at 3. He relied on Baxter, which
reviewed the recurrence of GBS in 550 cases following vaccination and observed that “‘[w]ith
over 30 million person-years of follow-up over the study period and nearly 1,000 vaccines
administered after a diagnosis of GBS (including over 400 influenza vaccinations), we did not
observe a single recurrent case of GBS that could be considered associated with vaccination.’” Id.
at 3; Resp. Ex. G-4.51 He conceded that there were no other studies of recurrence for GBS after flu
vaccination but cited to studies involving potential exacerbation of multiple sclerosis and
myasthenia gravis. Resp. Ex. G at 4; Resp. Ex. G-6;52 Resp. Ex. G-7;53 Resp. Ex. G-8;54 Resp. Ex.
G-9;55 Resp. Ex. G-11.56 Dr. Tompkins added that the American Academy of Neurology
recommends flu vaccination to MS patients. Resp. Ex. G at 4; Resp. Ex. G-10.57 He concluded
that, taken together, these publications support that inactivated flu vaccination does not exacerbate
50 Sofia Influenza A+B FIA, Quidel.
51 Roger Baxter, et al., Recurrent Guillain-Barré Syndrome Following Vaccination, 54 Clinical Infectious Diseases
800 (2012), filed as “Resp. Ex. G-4.”
52 A.E. Miller, et al., A Multicenter, Randomized, Double-Blind, Placebo-Controlled Trial of Influenza Immunization
in Multiple Sclerosis, 48 Neurology 312 (1997), filed as “Resp. Ex. G-6.”
53 Christian Confavreaux, et al., Vaccinations and the Risk of Relapse in Multiple Sclerosis, 344 New Eng. J. of Med.
319 (2001), filed as “Resp. Ex. G-7.”
54 Eitan Auriel, et al., Seasonal and H1N1v Influenza Vaccines in MS: Safety and Compliance, 314 J. of the
Neurological Sci. 102 (2012), filed as “Resp. Ex. G-8.”
55 Jacques De Keyser, et al., Effects of Influenza Vaccination and Influenza Illness on Exacerbations in Multiple
Sclerosis, 159 J. of the Neurological Sci. 51 (1998), filed as “Resp. Ex. G-9.”
56 Lorne Zinman, et al., Safety of Influenza Vaccination in Patients with Myasthenia Gravis: A Population-Based
Study, 40 Muscle & Nerve 947 (2009), filed as “Resp. Ex. G-11.”
57 Mauricio F. Farez, et al., Practice Guideline Update Summary: Vaccine-Preventable Infectious and Immunization
in Multiple Sclerosis, 93 Neurology 584 (2019), filed as “Resp. Ex. G-10.”
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autoimmune disease. And more specifically, Baxter showed that flu vaccination does not trigger
GBS. Resp. Ex. G at 4.
Dr. Tompkins concluded that respiratory and/or gastrointestinal infections are established
causes of GBS without an additional triggering event. Infections are the most common cause of
GBS. There is an absence of evidence to support relapse or exacerbation of GBS or other
autoimmune disease following influenza vaccination. Therefore, it is not plausible that petitioner’s
flu vaccination was the final insult in the cause of [petitioner’s] GBS. “Taken together, the
infections reported in the medical records two to three weeks prior to onset of petitioner’s GBS
remain the most likely cause of his autoimmune disease and fall within a reasonable window to
allow for the infection-elicited immune responses to trigger clinical symptoms of GBS.” Resp. Ex.
G at 4.
IV. Standards for Adjudication
A petitioner is required to establish their case by a preponderance of the evidence.
§ 13(1)(a). The preponderance of the evidence standard requires a “trier of fact to believe that the
existence of a fact is more probable than its nonexistence before [they] may find in favor of the
party who has the burden to persuade the [judge] of the fact’s existence.” Moberly v. Sec’y of
Health & Hum. Servs., 592 F.3d 1315, 1322 n.2 (Fed. Cir. 2010) (citations omitted). Proof of
medical certainty is not required. Bunting v. Sec’y of Health & Hum. Servs., 931 F.2d 867, 873
(Fed. Cir. 1991).
Distinguishing between “preponderant evidence” and “medical certainty” is important
because a special master should not impose an evidentiary burden that is too high. Andreu v. Sec’y
of Health & Hum. Servs., 569 F.3d 1367, 1379-80 (Fed. Cir. 2009) (reversing a special master’s
decision that petitioners were not entitled to compensation); see also Lampe v. Sec’y of Health &
Hum. Servs., 219 F.3d 1357 (Fed. Cir. 2000); Hodges v. Sec’y of Health & Hum. Servs., 9 F.3d
958, 961 (Fed. Cir. 1993) (disagreeing with the dissenting judge’s contention that the special
master confused preponderance of the evidence with medical certainty). At the same time, mere
conjecture or speculation is insufficient under a preponderance of evidence standard. Snowbank
Enters. v. United States, 6 Cl. Ct. 476, 486 (1984).
The Vaccine Act provides two avenues for petitioners to receive compensation. First, a
petitioner may demonstrate a “Table” injury—i.e., an injury listed on the Vaccine Injury Table
that occurred within the provided time period. 42 U.S.C. § 300aa-11(c)(1)(C)(i). “In such a case,
causation is presumed.” Capizzano v. Sec’y of Health & Hum. Servs., 440 F.3d 1317, 1320 (Fed.
Cir. 2006); see § 13(a)(1)(B). Second, where the alleged injury is not listed on the Vaccine Injury
Table, a petitioner may demonstrate an “off-Table” injury, which requires that the petitioner
“prove by a preponderance of the evidence that the vaccine at issue caused the injury.” Capizzano,
440 F.3d at 1320; see § 11(c)(1)(C)(ii); see also Wright v. Sec’y of Health & Hum. Servs., 22 F.4th
999, 1006 (Fed. Cir. 2022) (defining the term “residual effects” in the Act, as “detrimental
conditions within the patient, such as lingering or recurring signs and symptoms” of the alleged
vaccine injury, which are compensable). A petitioner need not show that the vaccination was the
sole cause, or even the predominant cause, of the alleged injury; showing that the vaccination was
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a “substantial factor” and a “but for” cause of the injury is sufficient for recovery. Pafford v. Sec’y
of Health & Hum. Servs., 451 F.3d 1352, 1355 (Fed. Cir. 2006); Shyface, 165 F.3d at 1352.
Petitioners are not required “to eliminate alternative causes as part of establishing [their]
prima facie case.” Doe v. Sec’y of Health & Hum. Servs., 601 F.3d 1349, 1357-58 (Fed. Cir. 2010);
see Walther v. Sec’y of Health & Hum. Servs., 485 F.3d 1146, 1152 (Fed. Cir. 2007) (holding that
a “petitioner does not bear the burden of eliminating alternative independent potential causes”).
Once a petitioner has proven causation by preponderant evidence, “the burden then shifts to the
respondent to show by a preponderance of the evidence that the injury is due to factors unrelated
to the administration of the vaccine.” Deribeaux ex rel. Deribeaux v. Sec’y of Health & Hum.
Servs., 717 F.3d 1363, 1367 (Fed. Cir. 2013) (citing 42 U.S.C. § 300aa-13(a)(1)(B)).
To prove causation, a petitioner must satisfy the three-pronged test established in Althen v.
Sec’y of Health & Hum. Servs., 418 F.3d 1274 (Fed. Cir. 2005). Althen requires that a petitioner
show by preponderant evidence that a vaccination they received caused their injury “by providing:
(1) a medical theory causally connecting the vaccination and the injury; (2) a logical sequence of
cause and effect showing that the vaccination was the reason for the injury; and (3) a showing of
a proximate temporal relationship between vaccination and injury.” Id. at 1278. Together, these
prongs must show “that the vaccine was ‘not only a but-for cause of the injury but also a substantial
factor in bringing about the injury.’” Stone v. Sec’y of Health & Hum. Servs., 676 F.3d 1373, 1379
(Fed. Cir. 2012) (quoting Shyface, 165 F.3d at 1352-53). Causation is determined on a case-by-
case basis, with “no hard and fast per se scientific or medical rules.” Knudsen v. Sec’y of Health
& Hum. Servs., 35 F.3d 543, 548 (Fed. Cir. 1994). Petitioners are not required to identify “specific
biological mechanisms” to establish causation, nor are they required to present “epidemiologic
studies, rechallenge, the presence of pathological markers or genetic disposition, or general
acceptance in the scientific or medical communities.” Capizzano, 440 F.3d at 1325 (quoting
Althen, 418 F.3d at 1280). “[C]lose calls regarding causation are resolved in favor of injured
claimants.” Althen, 418 F.3d at 1280.
Each Althen prong requires a different showing. Under the first prong, a petitioner must
provide a “reputable medical theory” demonstrating that the vaccine received can cause the type
of injury alleged. Pafford, 451 F.3d at 1355-56 (citation omitted). To satisfy this prong, a
petitioner’s “theory of causation must be supported by a ‘reputable medical or scientific
explanation.’” Andreu, 569 F.3d at 1379 (quoting Althen, 418 F.3d at 1278). This theory need only
be “legally probable, not medically or scientifically certain.” Id. at 1380 (emphasis omitted)
(quoting Knudsen, 35 F.3d at 548). Nevertheless, “petitioners [must] proffer trustworthy testimony
from experts who can find support for their theories in medical literature.” LaLonde v. Sec’y of
Health & Hum. Servs., 746 F.3d 1334, 1341 (Fed. Cir. 2014).
The second Althen prong requires proof of a “logical sequence of cause and effect.”
Capizzano, 440 F.3d at 1326 (quoting Althen, 418 F.3d at 1278). Even if the vaccination can cause
the injury, a petitioner must show “that it did so in [this] particular case.” Hodges v. Sec’y of Health
& Hum. Servs., 9 F.3d 958, 962 n.4 (Fed. Cir. 1993) (citation omitted). “A reputable medical or
scientific explanation must support this logical sequence of cause and effect,” Id. at 961 (citation
omitted), and “treating physicians are likely to be in the best position to determine whether a
logical sequence of cause and effect show[s] that the vaccination was the reason for the injury,”
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Paluck v. Sec’y of Health & Hum. Servs., 786 F.3d 1373, 1385 (Fed. Cir. 2015) (quoting Andreu,
569 F.3d at 1375). A petitioner is not, however, required “to eliminate alternative causes as part of
establishing [their] prima facie case.” Doe, 601 F.3d at 1357-58; see Walther, 485 F.3d at 1152
(holding that a “petitioner does not bear the burden of eliminating alternative independent potential
causes”).
The third Althen prong requires that a petitioner establish a “proximate temporal
relationship” between the vaccination and the alleged injury. Althen, 418 F.3d at 1281. This
“requires preponderant proof that the onset of symptoms occurred within a timeframe for which,
given the medical understanding of the disorder’s etiology, it is medically acceptable to infer
causation-in-fact.” de Bazan v. Sec’y of Health & Hum. Servs., 539 F.3d 1347, 1352 (Fed. Cir.
2008). Typically, “a petitioner’s failure to satisfy the proximate temporal relationship prong is due
to the fact that onset was too late after the administration of a vaccine for the vaccine to be the
cause.” Id. However, “cases in which onset is too soon” also fail this prong; “in either case, the
temporal relationship is not such that it is medically acceptable to conclude that the vaccination
and the injury are causally linked.” Id. See also Locane v. Sec'y of Health & Hum. Servs., 685 F.3d
1375, 1381 (Fed. Cir. 2012) (“[If] the illness was present before the vaccine was administered,
logically, the vaccine could not have caused the illness.”).
Finally, although this ruling discusses some but not all the literature in detail, I have
reviewed and considered all of the medical records and literature submitted in this matter. See
Moriarty ex rel. Moriarty v. Sec’y of Health & Hum. Servs., 844 F.3d 1322, 1328 (Fed. Cir. 2016)
(“We generally presume that a special master considered the relevant record evidence even though
[s]he does not explicitly reference such evidence in h[er] decision.”); Simanski v. Sec’y of Health
& Hum. Servs., 115 Fed. Cl. 407, 436 (2014) (“[A] Special Master is ‘not required to discuss every
piece of evidence or testimony in her decision.’” (citation omitted)), aff’d, 601 F. App’x 982 (Fed.
Cir. 2015).
V. Analysis
A. Althen Prong One: Reputable Medical Theory
The first Althen prong requires petitioner to provide a “reputable medical theory”
demonstrating that the vaccine(s) received can cause the type of injury alleged. Pafford, 451 F.3d
at 1355-56 (citation omitted). The mere fact that GBS resulting from flu vaccination is an on-Table
injury in certain contexts does not control the Court on Prong One of an off-Table case. Beckwith
v. Sec'y of Health & Hum. Servs., 2026 WL 669236, at *10 (Fed. Cl. Feb. 20, 2026) (citing de
Bazan, 539 F.3d at 1352) (“[T]he proposed ‘medically acceptable timeframe must align with the
theory of how the relevant vaccine can cause an injury (Althen prong one's requirement).’”). As
always, “petitioner must by a preponderance of the evidence demonstrate . . . ‘a medical theory
causally connecting the vaccination and the injury.’” Id. (quoting Althen, 418 F.3d at 1278).
Dr. Akbari described molecular mimicry as a mechanism by which the host and a microbe
share an immunologic epitope by either sequence or conformational homology. Pet. Ex. 43 at 7.
For example, it has been established that autoantibodies from patients with rheumatic fever can
cross react with cardiac myosin and induce autoimmune disease in mouse models. Id. at 7-8. The
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scientific understanding of molecular mimicry has evolved, and significant sequence-specific
requirements are no longer thought necessary for autoimmunity to result. Further, “molecular
mimicry is accepted as a theory to explain causation of autoimmune disease and showing the direct
sequence homology or cross-reactive protein involved in the process, especially in vivo, is the
exception.” Id. at 7; Pet. Ex. 43 Ref No. 4;58 Pet. Ex. 43 Ref No. 5.59
Dr. Akbari contends that commercially available vaccines were developed “without much
comprehension regarding how the vaccine activates the immune system.” Pet. Ex. 43 at 7; Pet. Ex.
43 Ref No. 6.60 He explained that receipt of a vaccine causes a local inflammatory reaction
mediated by cells of the innate immune system. Nonspecific innate immune pathways recruit other
immune cells to the area of the injection through cytokines. Dendritic cells that process foreign
antigens display a piece of the foreign antigen on their surface to activate the adaptive immune
system. Pet. Ex. 43 at 7. Once activated, the dendritic cell migrates to the lymph nodes and interacts
with B and T cells that recognize the antigen. B cells, a type of white blood cell, function in the
humoral immunity part of the adaptive immune system to produce antibody molecules which can
directly bind to a foreign antigen for later destruction and removal from the body. Id. at 7-8.
Antigens are large and complex, so antibodies can only bind to small specific areas of them.
The immune system has evolved to allow for the production of many different antibodies
by many different B-cell clones against the same foreign antigen. Pet. Ex. 43 at 8. While this
response increases the probability of reacting against pathogens, it also increases the chance of
developing an autoimmune disease from an adverse reaction of the immune system against native
self-molecules. Id. T cells are helper cells, subsets of which, Th1 and Th2, develop into effector T
cells to help eliminate different types of pathogens. Th1 cells have a pathogenic role in GBS. Id.;
Pet. Ex. 43 Ref No. 7.61 T cells mature in the thymus and are also called CD4+ cells. Peripheral
self-tolerance in CD4+ T cells is maintained by several mechanisms, most importantly suppression
by regulatory T lymphocytes, or “Tregs,” known for their active role in maintaining tolerance to
self-antigens and combating autoimmune disease. Pet. Ex. 43 at 8-9. If the suppression function
of Tregs in humans is altered, autoimmune diseases including GBS occur. Id. In patients with acute
GBS, the number of Tregs is decreased. Id. at 9; Pet. Ex. 43 Ref No. 8.62 This is likely the reason
certain people are predisposed to develop autoimmune diseases when their immune system is
activated, such as following vaccination.
Dr. Akbari explained that immune activation is required for the onset of autoimmune
disease. Normally, self-reactivity is part of regeneration and healing through removal of cellular
debris from damaged cells. The immune system plays a central role in the maintenance of these
healing processes. However, the same process that promotes self-tolerance can promote
autoimmunity. Environmental triggers are required for the induction of disease. Within hours of
58 Adam P. Kohm, et al., Mimicking the Way to Autoimmunity: An Evolving Theory of Sequence and Structural
Homology, 11 Trends in Microbiology 101 (2003), filed as “Pet. Ex. 43 Ref No. 4.”
59 Marinos C. Dalakas, Future Perspectives in Target-Specific Immunotherapies of Myasthenia Gravis, 8 Therapeutic
Advances in Neurological Disorders 316 (2015), filed as “Pet. Ex. 43 Ref No. 5.”
60 Claire-Anne Siegrist, Vaccine Immunology, in Plotkin’s Vaccines 16 (2018), filed as “Pet. Ex. 43 Ref No. 6.”
61 Shujuan Li, et al., IL-17 and IL-22 in Cerebrospinal Fluid and Plasma Are Elevated in Guillain-Barré Syndrome,
2012 Mediators of Inflammation 1 (2012), filed as “Pet. Ex. 43 Ref No. 7.”
62 Li-jun Chi, et al., Abnormality of Circulating CD4+ CD25+ Regulatory T Cell in Patients with Guillain-Barré
Syndrome, 192 J. of Neuroimmunology 206 (2007), filed as “Pet. Ex. 43 Ref No. 8.”
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vaccination, immune regulatory mechanisms such as Tregs maintain peripheral tolerance actively
suppressing autoreactive effector immune cells such as lymphocytes capable of causing injury.
While vaccines are safe inducers of an immune response, with effective mechanisms maintaining
immune homeostasis mounting immunological memory in response, adverse immune response
may occur. Pet. Ex. 43 at 20.
Dr. Akbari detailed how toll-like receptors (TRLs) can be upregulated by flu vaccination
whether adjuvanted or not through inflammasome activation and subsequent production of
interleukins and related genes. Pet. Ex. 46 at 1-5; Pet. Ex. 46 Ref No. 1;63 Pet. Ex. 46 Ref No. 2;64
Pet. Ex. 46 Ref No. 3;65 Pet. Ex. 46 Ref No. 4;66 Pet. Ex. 48 at 12-14; Pet. Ex. 48 Ref No. 14;67
Pet. Ex. 48 Ref No. 15;68 Pet. Ex. 48 Ref No. 16;69 Pet. Ex. 48 Ref No. 17;70 Pet. Ex. 48 Ref No.
18.71 Activation of the immune system following receipt of the flu vaccine causes complex
molecules known as inflammasomes to form. These inflammasomes activate the production of
active cytokines, including those of the IL-1 family, which are potent stimulators of the adaptive
immune response. Petitioner’s flu vaccine contained hemagglutinin from several strains of flu
virus including H1N1 proteins which are primary targets for inflammasomes. Pet. Ex. 46 at 4-5;
Pet. Ex. 46 Ref No. 5;72 Pet. Ex. 46 Ref No. 6;73 Pet. Ex. 46 Ref No. 7.74 The activation of cytokines
and TNF-a experimentally induce demyelination, elevate temperature, and increase lassitude,75
providing strong evidence of the important role cytokines play in the production of Th17 cells.
Pet. Ex. 48 at 14. Succinctly, flu infection and vaccination can produce inflammasomes along with
T-cell activation that can cause demyelination. Pet. Ex. 46 at 6; Pet. Ex. 48 at 14. Emerging
research has found increased levels of Th17 in patients with peripheral and central demyelinating
63 Stephen N. Crooke, et al., Inflammasome Activity in Response to Influenza Vaccination is Maintained in Monocyte-
Derived Peripheral Blood Macrophages in Older Adults, 2 Frontiers in Aging 1 (2021), filed as “Pet. Ex. 46 Ref No.
1” and “Pet. Ex. 48 Ref No. 13.”
64 Pin Wan, et al., AP-1 Signaling Pathway Promotes Pro-IL-1β Transcription to Facilitate NLRP3 Inflammasome
Activation Upon Influenza A Virus Infection, 12 Virulence 502 (2022), filed as “Pet. Ex. 46 Ref No. 2.”
65 Xing Yang, et al., KSHV-Encoded ORG45 Activates Human NLRP1 Inflammasome, 23 Nature Immunology 916
(2022), filed as “Pet. Ex. 46 Ref No. 3.”
66 Ella Hartenian & Petr Broz, Viral Protein Activates the NLRP1 Inflammasome, 23 Nature Immunology 818 (2022),
filed as “Pet. Ex. 46 Ref No. 4.”
67 Rebecca E. Tweedell, et al., A Comprehensive Guide to Studying Inflammasome Activation and Cell Death, 15
Nature Protocols 3284 (2020), filed as “Pet. Ex. 48 Ref No. 14.”
68 Lisa M. Christian, et al., Proinflammatory Cytokine Responses Correspond with Subjective Side Effects After
Influenza Virus Vaccination, 33 Vaccine 3360 (2015), filed as “Pet. Ex. 48 Ref No. 15.”
69 Weichun Tang, et al., Post-Vaccination Serum Cytokines Levels Correlate with breakthrough Influenza Infections,
13 Sci. Rep. 1174 (2023), filed as “Pet. Ex. 48 Ref No. 16.”
70 Si Ming Man & Thirumala-Devi Kanneganti, Regulation of Inflammasome Activation, 265 Immunological Revs. 6
(2015), filed as “Pet. Ex. 48 Ref No. 17.”
71 Taejoon Won, et al., Increased Interleukin 18-Dependent Immune Respondent are Associated with Myopericarditis
After COVID-19 mRNA Vaccination, 13 Frontiers in Immunology (2022), filed as “Pet. Ex. 48 Ref No. 18.”
72 Alexander Khoruts, IL-1 Acts on Antigen-Presenting Cells to Enhance the In Vivo Proliferation of Antigen-
Stimulated Naïve CD4 Cells via a CD28-Dependent Mechanism That Does Not Involve Increased Expression of CD28
Ligands, 34 European J., of Immunology 1085 (2004), filed as “Pet. Ex. 46 Ref No. 5” and “Pet. Ex. 43 Ref No. 25.”
73 Kiyoshi Takeda, et al., Toll-Like Receptors, 21 Ann. Rev. of Immunology 335 (2003), filed as “Pet. Ex. 46 Ref No.
6” and “Pet. Ex. 43 Ref No. 24.”
74 Virginie Pétrilli, et al., The Inflammasome: A Danger Sensing Complex Triggering Innate Immunity, 19 Current
Opinion in Immunology 615 (2007), filed as “Pet. Ex. 46 Ref No. 7.”
75 Lassitude refers to “weakness” or “exhaustion.” “Lassitude,” Dorland’s Illustrated Medical Dictionary 994 (33rd
ed. 2020).
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disease. Pet. Ex. 46 at 6; Pet. Ex. 46 Ref No. 8;76 Pet. Ex. 48 at 14-15; Pet. Ex. 48 Ref No. 20;77
Pet. Ex. 48 Ref No. 21;78 Pet. Ex. 48 Ref No. 22.79 See also Pet. Ex. 52 at 8-13.
Dr. Akbari continued that interleukins, or ILs, are fast-acting cells and produce cytokines
and chemokine within hours to days of flu vaccination. Pet. Ex. 46 at 13-14. Petitioner’s immune
system was already activated and in an inflammatory state from acute pancreatitis and diarrhea
prior to his vaccination. The production of proinflammatory cytokines from pancreatitis and
diarrhea sensitized his immune system which was further exacerbated by an inflammatory
response to the flu vaccination. The influx of proinflammatory cytokines played a substantial role
in the faster onset of petitioner’s GBS. Id. at 14, 24-25; Pet. Ex. 48 at 20-21, 23; Pet. Ex. 52 at 1-
2.
Dr. Tompkins disagreed that the flu vaccine can cause GBS. He detailed several issues he
took with studies cited by Dr. Akbari. He also provided a study which conducted surveillance for
GBS during two recent flu seasons and found no excess risk of GBS in either flu vaccine for either
risk window observed. Resp. Ex. B-1 at 4; Resp. Ex. B-6.80 See also Resp. Exs. B-1981 and B-2282
for additional epidemiological studies finding no elevated risk of GBS following flu vaccination
when adjusted for antecedent infections.83
Dr. Tompkins agreed that Finsterer recognized an association between flu vaccination and
GBS. Resp. Ex. G at 2; Resp. Ex. G-1.84 But he added that Petras, a meta-analysis, concluded
there was no increased risk of GBS following vaccination, only following flu-like illness, based
on 40 years of studies since 1981. Resp. Ex. G at 2-3; Resp. Ex. G-2.85 According to Dr. Tompkins,
highly purified inactivated influenza vaccines are safe with many studies showing no increased
risk of GBS following vaccination. In the studies that do show a slightly increased risk of GBS
following contemporary flu vaccination, flu and other infections were subsequently found to
account for the risk. Resp. Ex. D-2 at 13. Dr. Tompkins disagreed that inactivated flu vaccine
76 Feng-Jun Mei, et al., Th1 Shift in CIDP Versus Th2 Shift in Vasculitic Neuropathy in CSF, 228 J. of the Neurological
Sci. 75 (2005), filed as “Pet. Ex. 46 Ref No. 8.”
77 Jesus F. Bermejo-Martin, et al., Th1 and Th17 Hypercytokinemia as Early Host Response Signature in Severe
Pandemic Influenza, 13 Critical Care 1 (2009), filed as “Pet. Ex. 48 Ref No. 20.”
78 Yinyao Lin, et al., Th17 Cytokines and Vaccine-Induced Immunity, 32 Seminars in Immunopathology 79 (2010),
filed as “Pet. Ex. 48 Ref No. 21.”
79 F. Jadidi-Niaragh & A. Mirshafiey, Th17 Cell, the New Player of Neuroinflammatory Process in Multiple Sclerosis,
74 Scandinavian J. of Immunology 1 (2011), filed as “Pet. Ex. 48 Ref No. 22.”
80 Arya, et al., supra, note 47.
81 Sharon K. Greene, et al., Guillain-Barré Syndrome, Influenza Vaccination, and Antecedent Respiratory and
Gastrointestinal Infections: A Case-Centered Analysis in the Vaccine Safety Datalink, 2009-2011, 8 PLOS One
e67185 (2013), filed as “Resp. Ex. B-19.”
82 Sharon K. Greene, et al., Near Real-Time Surveillance for Influenza Vaccine Safety: Proof-of-Concept in the
Vaccine Safety Datalink Project, 171 Am. J. of Epidemiology 177 (2010), filed as “Resp. Ex. B-22.”
83 Dr. Akbari addressed these studies and noted that they sourced their data from the Vaccine Safety Datalink. Dr.
Akbari argued that the data from the VSD is flawed, as it underrepresents vaccinations administered in nontraditional
settings, do not account for uninsured vaccine recipients, and coverage rates are higher in the VSD than in the general
population. These and other factors make VSD data difficult to generalize. Pet. Ex. 46 at 7-8.
84 Josef Finsterer, Triggers of Guillain-Barré Syndrome: Campylobacter jejuini Predominates, 23 Int’l J. of Molecular
Sci. 14222 (2022), filed as “Resp. Ex. G-1.”
85 Marek Petráš, et al., Is an Increased Risk of Developing Guillain-Barré Syndrome Associated with Seasonal
Influenza Vaccination? A Systematic Review and Meta-Analysis, 8 Vaccines 150 (2020), filed as “Resp. Ex. G-2.”
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elicits cytokines, drives inflammasome activation, elicits Th27 T cells, or that they could plausibly
do so in fewer than three days. Resp. Ex. D-2 at 8; Resp. Ex. G at 8-9. He submitted that the studies
relied upon by Dr. Akbari in support of his proposed mechanisms linking flu vaccine and GBS are
insufficient. Some suggest that infection may be associated with autoimmune disease, but infection
is different from a vaccination. Resp. Ex. G at 9. See Pet. Ex. 46 Ref No. 35;86 Pet. Ex. 46 Ref No.
29;87 Pet. Ex. 46 Ref No. 26.88
Dr. Tompkins asserted that the animal study Dr. Akbari relied upon, in which mice were
seeded with millions of CD4+ and CD8+ T cells specific for the HA antigen present in the
influenza vaccine which depleted the regulatory T cells and prevented “dampening of
proinflammatory responses,” is inapplicable to this case. Resp. Ex. G at 9. The vaccine used was
a split-inactivated monovalent vaccine against the 2009 pandemic H1N1 virus and contained the
adjuvant AS03, which is not currently used in any seasonal influenza vaccine or other human
vaccine. The vaccine with the ASO3 adjuvant does significantly increase cytokine responses in
vaccinated mice and was the only vaccine to elicit Th17 T cells. The authors specifically noted
that nonadjuvanted influenza vaccines do not elicit Th17 T cells. Id. at 10; Resp. Ex. G-26.89 Dr.
Tompkins agreed that animal studies show increased cytokines and Th17 elicited with the use of
ASO3 adjuvanted vaccines, but that has no bearing on this case. Resp. Ex. G at 9. While the studies
presented may offer new insights for potential mechanisms for autoimmune disease, they fail to
provide a clear mechanism connecting contemporary inactivate flu vaccination to GBS. Id. at 10.
Further, the studies relied upon as suggesting increased cytokine levels following
inactivated or live attenuated flu vaccines did not look at onset of disease within two days of
vaccination, or tested only women with sore arms, but found TNF-α, IFN- γ, IL-6, IL-8, and IL-
10 were lower in all vaccinated groups. Resp. Ex. G at 8; Pet. Ex. 48 Ref No. 17 at 3, 4.90 See also
Pet. Ex. 48 Ref No. 1 at 11.91
Dr. Tompkins then examined Dr. Akbari’s theory of molecular mimicry. Dr. Tompkins
agreed with Dr. Akbari’s definition of molecular mimicry. However, Dr. Tompkins argued that
“there must be demonstrable evidence of the foreign antigen eliciting cross-reactive immune
responses that cause tissue damage recapitulating clinical disease.” Resp. Ex. B-1 at 5. In other
words, Dr. Tompkins, citing the Institute of Medicine, would require a showing of the precise
direct sequence homology or cross-reactive protein shared between the host and the vaccine for
molecular mimicry to be sufficiently implicated. Id.; Resp. Ex. B-3.92
86 Jing Li, et al., KIR+CD8+ T Cells Suppress Pathogenic T Cells and Are Active in Autoimmune Diseases and COVID-
19, 376 Sci. eabi9591 (2022), filed as “Pet. Ex. 46 Ref No. 35.”
87 Jocelyn G. Labombarde, et al., Induction of Broadly Reactive Influenza Antibodies Increases Susceptibility to
Autoimmunity, 38 Cell Reps. 110482 (2022), filed as “Pet. Ex. 46 Ref No. 29.”
88 Jon D. Laman, et al., Guillain-Barré Syndrome: Expanding the Concept of Molecular Mimicry, 43 Trends in
Immunology 296 (2022), filed as “Pet. Ex. 46 Ref No. 26.”
89 Karen K. Yam, et al., AS03-Adjuvanted, Very-Low-Dose Influenza Vaccines Induce Distinctive Immune Responses
Compared to Unadjuvanted High-Dose Vaccines in BALB/c Mice, 6 Frontiers in Immunology 1 (2015), filed as “Resp.
Ex. G-26.”
90 Man & Kanneganti, supra, note 70.
91 Salmon, et al., supra, note 42.
92 Kathleen Stratton, et al., Institute of Medicine, Adverse Effects of Vaccines: Evidence and Causality 57 (2012)
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The Vaccine Program however does not require scientific certainty to make a finding of
entitlement. While the IOM may require a stringent identification of identical shared mimics to
satisfy scientific rigor, here, “to require identification and proof of specific biological mechanisms
would be inconsistent with the purpose and nature of the vaccine compensation program.”
Knudsen, 35 F.3d at 549. Indeed, while not dispositive or binding, other Special Masters have
routinely found in favor of petitioners on Prong I in flu/GBS cases based in molecular mimicry.
See, e.g., Barone v. Sec'y of Health & Hum. Servs., No. 11-707V, 2014 WL 6834557, at *8 (Fed.
Cl. Spec. Mstr. Nov. 12, 2014) (citing Petronelli v. Sec'y of Health & Hum. Servs., No. 12-285V,
2013 WL 6054752, at *6 (Fed. Cl. Spec. Mstr. Oct. 25, 2013) (citing several Program flu/GBS
cases in which entitlement was found for petitioners relying on molecular mimicry)). I have also
previously noted that “[t]he association between flu vaccine and GBS is well-established in the
Vaccine Program.” McCarter v. Sec'y of Health & Hum. Servs., No 20-1490V, 2025 WL 3458768,
at *17 (Fed. Cl. Spec. Mstr. Nov. 7, 2025) (collecting cases). The Chief Special Master even
favorably compared “the extensive science supporting causation for GBS after vaccination” to the
relatively weaker evidence, in his opinion, for linking vaccination to chronic inflammatory
demyelinating polyneuropathy, or CIDP, which he described as a distinct neuropathy. Nieves v.
Sec'y of Health & Hum. Servs., No. 18-1602V, 2023 WL 3580148, at *36 (Fed. Cl. Spec. Mstr.
May 22, 2023).
Respondent ultimately argues that “there is no reliable scientific evidence – either
epidemiologic or mechanistic – that a seasonal flu vaccine can cause GBS.” ECF No. 130 at 50.
Dr. Tompkins opined that an inactivated vaccine does not elicit cytokines, drive inflammasome
activation, or elicit Th17 cells. Resp. Ex. G at 9. But if this was so, an inactivated flu vaccine
without an adjuvant could not elicit the immune response necessary to develop adaptive immunity,
which is required to be effective.
Petitioner has put forth a sound and reliable medical theory for how the flu vaccine can
cause GBS and has supported that theory with expert opinions, including that of an immunologist,
and reliable medical literature. I therefore find, based on the evidence and expert testimony, that
the influenza vaccine can cause GBS. It is undisputed that petitioner received an influenza vaccine
on October 21, 2016, and was diagnosed with GBS. Thus, Prong I, also known as the “can it
cause?” inquiry, is satisfied.
B. Althen Prongs II and III: Logical Sequence of Cause and Effect and Proximate
Temporal Relationship
The resolution of Prongs II and III in this case are intertwined and best addressed together.
1. Diagnosis and Medical History
The diagnosis of GBS is not in dispute. In dismissing petitioner’s Table claim for flu-
vaccine-related GBS, the Chief Special Master concluded, based on all the evidence, that the onset
of petitioner’s GBS occurred in fewer than the three days required by the Vaccine Injury Table.
ECF No. 50 at 5. This was undisputed by petitioner who, in his brief in support of onset wrote, “‘it
appears the weakness in [his] hands 54-55 hours of [sic] vaccination may represent the first
objective sign of GBS/AIDP alleged to be caused by vaccination.’” ECF No. 50 at 7 (quoting ECF
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No. 47 at 2). Further, in his affidavits and reports to his medical providers, petitioner consistently
reported receipt of the flu vaccine on Friday, October 21, 2016, between 4:00 and 5:00 PM,
weakness in his hands on Sunday night, October 23, 2016, at around 10:00 PM, difficulty walking
by Monday, October 24, 2016, and inability to walk on Tuesday, October 25, 2016. Pet. Ex. 4 at
5; Pet. Ex. 21 at 1-2; Pet. Ex. 11 at 199. Thus, petitioner’s onset of GBS was between 54 to 58
hours post-vaccination.
The medical records support the following findings. Petitioner was born on June 26, 1967.
He was 49 years old when he received the subject flu vaccination. Pet. Ex. 1 at 1. He had no known
medical conditions before October of 2016. Pet. Ex. 7 at 21-26, 14-19, 20. His prior medical history
was not questioned.
Petitioner presented on October 5, 2016, with body aches, chills, eye burning, throat pain,
hoarse voice, pain on inspiration, chest and stomach pain, excessive thirst, decreased appetite, and
fever of 102°. Pet. Ex. 7 at 1-2. Examination was normal, an influenza A/B test was negative, and
the diagnosis was “flu-like” symptoms. He was prescribed Bentyl for stomach cramping. Id. at
1,4. Four days later, he presented to the ER with five to six days of abdominal pain, fever, chills,
and diarrhea following binge drinking over the weekend. Pet. Ex. 15 at 14. He had upper abdominal
tenderness upon examination but no fever. Id. at 17, 24. CT and ultrasound of the stomach revealed
a fatty liver and gallstones without inflammation. Id. Stool sample revealed fecal leukocytes
indicative of infection or inflammation but no campylobacter infection, parasites, or toxin. Id. at
120. His blood work was abnormal with elevated inflammatory markers, glucose, AIC, AST, and
lipase. Id. at 116-119. He was diagnosed with diabetes for the first time and acute pancreatitis of
unknown cause. Id. at 14. He was given Cipro for suspected C-diff but he tested negative with
resolution of abdominal pain the following day. Id. at 119. The diagnosis on discharge was acute
pancreatitis without necrosis or infection, viral intestinal infection not otherwise specified, and
DM, for which Metformin and Glipizide were prescribed. Pet. Ex. 15 at 2-4, 13-14, 17, 97.
On October 15, 2016, petitioner presented with chest pain, back pain, and shortness of
breath. Pet. Ex. 15 at 197, 201. Blood work showed elevated cardiac regulatory proteins and
elevated WBC. Id. at 446, 181. Cardiac catheterization showed coronary artery disease, but the
echocardiogram and stress test were normal. Id. at 295, 364, 370, 471. His CT was unchanged, and
he was discharged with a diagnosis of acute pancreatitis. Id. at 181-82.
At a follow-up on October 21, 2016, petitioner had no complaints and had normal strength
and intact sensory on examination. Pet. Ex. 17 at 3. He was taking medication for his recent
diabetes diagnosis. Id. at 3-5. His blood work that day was abnormal with many highly elevated
inflammatory markers, including but not limited to CRP, interleukin 6 and 8, and mildly elevated
WBC. Id. at 101, 98-99. The subject flu vaccination was administered at about 4:00 to 5:00 PM.
Id. at 4. Sunday night, October 23, 2016, at around 10:00 PM, petitioner noted weakness in his
hands. The next morning, he walked slowly. By Tuesday, he could not walk at all. At that time,
examination revealed weakness and diminished or absent reflexes. He was diagnosed with GBS.
Pet. Ex. 11 at 199, 202, 203; Pet. Ex. 4 at 5. Petitioner’s laboratory findings included but were not
limited to strong positive GM1 Ab 180 and GD1b Ab, elevated lipase, and inflammatory markers.
Pet. Ex. 11 at 69-70, 187, 64, 81. Lumbar puncture and EMG/NCS studies were consistent with
GBS. Id. at 168, 155-156. The clinical summary included GBS following vaccination. Id. at 2.
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2. Expert Reports
Petitioner’s experts opined that the flu vaccine triggered petitioner’s GBS, either directly
or in combination with inflammatory processes caused by the acute pancreatitis and cholelithiasis,
or gallstones, he suffered in the weeks prior to his receipt of the flu vaccine. Pet. Ex. 45 at 6; Pet.
Ex. 45 Ref No. 6.93 On the day of his flu vaccination, petitioner had a normal examination and no
complaints, but his blood work showed elevated inflammatory markers including CRP, interleukin
6, and interleukin 8, with mildly elevated white blood cells and elevated platelets. Pet. Ex. 17 at
3-5, 101, 98-99. Petitioner’s experts opined that the flu vaccine can cause GBS on its own and was
a substantial factor in his development of GBS. And given petitioner’s already systemic
inflammatory state, receipt of the flu vaccination resulted in an earlier-than-typical onset of GBS
within 54 to 58 hours, less time than the three days provided for by the Vaccine Table.
Conversely, respondent’s experts argued that petitioner suffered from respiratory and
gastrointestinal viral infections two to three weeks prior to the onset of GBS, as well as diabetes,
recent surgery, and alcoholism. All of these are known causes of GBS and occurred within the risk
interval for the onset of GBS. Therefore, the flu vaccination played no role in his GBS. See
generally Resp. Exs. A-2, B-1, C, D-2, F, and G.
Petitioner’s experts also responded to the alternative causes of alcoholic neuropathy,
diabetes mellitus, and surgery raised by respondent’s experts. However, respondent later
disclaimed these as potential alternative causes. ECF No. 130 at 60-61 (“Petitioner also argues at
length that petitioner’s alcoholic neuropathy and diabetic neuropathy did not cause his GBS.
Respondent does not assert that these conditions caused petitioner’s GBS.”). Thus, petitioner’s
arguments rebutting these potential alternative causes will not be addressed in full. Instead,
respondent argues that petitioner suffered from a respiratory infection and/or a gastrointestinal
infection, and that one of those more likely than not was the cause of petitioner’s GBS.
i. Petitioner’s Experts
Dr. Kinsbourne explained that petitioner’s “flu-like” and gastrointestinal symptoms
between October 5 and October 9, 2016, were manifestations of the inflammation caused by acute
pancreatitis. They were not symptoms of flu virus, gastroenteritis, or bacteriuria. Pet. Ex. 45 at 5-
6; Pet. Ex. 45 Ref No. 3;94 Pet. Ex. 47 at 3-4, 5-6; Pet. Ex. 47 Ref No. 11;95 Pet. Ex. 49 at 1-2; Pet.
Ex. 53 Ref No. 1;96 Pet. Ex. 53 Ref No. 2.97 He added that bacteriuria is a complication of
93 Sekimoto, et al., JPN Guidelines for the Management of Acute Pancreatitis: Epidemiology, Etiology, Natural
History, and Outcome Predictors in Acute Pancreatitis, 13 J. of Hepato-Biliary-Pancreatic Surgery 10 (2006), filed
as “Pet. Ex. 45 Ref No. 6.”
94 A. Mora, et al., Activation of Cellular Immune Response in Acute Pancreatitis, 40 Gut 794 (1997), filed as “Pet. Ex.
45 Ref No. 3.”
95 Theo J. Verheij, et al., Clinical Presentation, Microbiological Aetiology and Disease Course in Patients with Flu-
Like Illness: A Post Hoc Analysis of Randomised Controlled Trial Data, 72 British J. of Gen. Prac. e217 (2022), filed
as “Pet. Ex. 47 Ref No. 11.”
96 Robert A. Balk, Systemic Inflammatory Response Syndrome (SIRS): Where Did It Come from and Is It Still Relevant
Today?, 5 Virulence 20 (2014), filed as “Pet. Ex. 53 Ref No. 1.”
97 J. Toouli, et al., Guidelines for the Management of Acute Pancreatitis, 17 J. of Gastroenterology and Hepatology
S15 (2002), filed as “Pet. Ex. 53 Ref No. 2.”
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pancreatitis, not a cause of it. He also noted that petitioner was never diagnosed with
gastroenteritis. Pet. Ex. 47 at 4; Pet. Ex. 48 at 1-2; Pet. Ex. 7 at 1-5. Petitioner demonstrated all
four of the hallmark signs of acute pancreatitis: raised temperature, elevated pulse rate, low blood
pressure, and low oxygenation. Pet. Ex. 49 at 3; Pet. Ex. 49 Ref No. 3.98 Further, acute pancreatitis
has not been shown to be a trigger of GBS. A few cases of GBS have been reported in those with
severe long-term pancreatitis, but no mechanism has been plausibly posited, suggesting that there
were other causes for GBS in those patients. Pet. Ex. 45 at 6, 8; Pet. Ex. 45 Ref No. 6;99 Pet. Ex.
45 Ref No. 1;100 Pet. Ex. 45 Ref No. 2.101
Dr. Kinsbourne also noted that petitioner had a negative influenza A/B antigen test on
October 4, 2016, but with symptoms referred to as “flu like” despite not having a cough, running
nose, or shortness of breath. Pet. Ex. 45 at 5. He referred to Ryu, et al., which showed that the flu
test petitioner underwent had 94.5% sensitivity level for influenza A and 91.7% for influenza B.
Pet. Ex. 47 at 10; Pet. Ex. 47 Ref No. 6.102 He disagreed that petitioner had an influenza infection
and that the influenza testing was a false negative. Pet. Ex. 47 at 10.
Subsequently, on October 9, 2016, petitioner’s illness “declared itself plainly as a
gastrointestinal issue, with nausea, vomiting, cramps and diarrhea, as well as continued fever”
which was ultimately diagnosed as acute pancreatitis with abdominal symptoms resolving by
October 11, 2016. Id. at 5-6.
Dr. Kinsbourne explained that acute pancreatitis is most frequently caused by alcoholism
and cholelithiasis, or gallstones. Pet. Ex. 45 at 6; Pet. Ex. 45 Ref No. 6 at 1.103 While Gross, et al.
reported four cases of GBS following pancreatitis, the patients involved were seriously ill with
severe long-lasting pancreatitis, not acute pancreatitis that resolved quickly as in petitioner. Pet.
Ex. 45 at 6. See generally Pet. Ex. 45 Ref No. 1.104 Further, in those cases, the GBS appeared
months after treatment was initiated, prompting the authors to suggest alternative triggers for the
patients’ GBS. Pet. Ex. 45 at 6; Pet. Ex. 45 Ref No. 1 at 1.105 Harikumar, et al. also reported
polyneuritis in a patient with severe pancreatitis who later died. Pet. Ex. 45 at 6. See generally Pet.
Ex. 45 Ref No. 2.106 The patients in these studies were distinguishable from petitioner due to the
uncertainty surrounding their diagnoses with no attempt by the authors to explain the mechanism
of the polyneuropathy they suffered. Therefore, these cases of GBS following pancreatitis fall
short of providing an alternative cause for petitioner’s GBS. Pet. Ex. 45 at 6.
Dr. Kinsbourne added that the discovery of petitioner’s “severe biliary tract disorder,” or
98 Per-Olof Nyström, The Systemic Inflammatory Response Syndrome: Definitions and Etiology, 41 J. of Antimicrobial
Chemotherapy 1 (1998), filed as “Pet. Ex. 49 Ref No. 3.”
99 Sekimoto, et al., supra, note 93.
100 Gross, et al., supra, note 29.
101 Harikumar, et al., supra, note 30.
102 Sook Won Ryu, et al., Comparison of Three Rapid Influenza Diagnostic Tests with Digital Readout Systems and
One Conventional Rapid Influenza Diagnostic Test, 32 J. of Clinical Lab Analysis e22234 (2018), filed as “Pet. Ex.
47 Ref No. 6.”
103 Sekimoto, et al., supra, note 93.
104 Gross, et al., supra, note 29.
105 Id.
106 Harikumar, et al., supra, note 30.
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cholecystitis, in late December during surgery could explain his acute pancreatis. Pet. Ex. 45 at 7-
8. He explained how the cystic duct joins with the pancreatic duct to form the common bile duct.
An obstruction of the bile duct by a gallstone is the most common cause of acute pancreatitis. The
obstruction often leads to reflux of bile acids into the pancreatic duct, causing inflammation in the
pancreatic acinar cells, which are the functional unit of the exocrine pancreas that synthesizes,
stores, and secretes digestive enzymes. Activation of digestive enzymes before they get to the
duodenum leads to acute pancreatitis. Pet. Ex. 45 at 7; Pet. Ex. 45 Ref No. 7 at 1-2.107 If the
gallstone dislodges, then the acute pancreatitis would resolve. Pet. Ex. 45 at 7. The diarrhea that
accompanied petitioner’s onset of acute pancreatitis “appears to have been part of the same disease
process” or perhaps secondary to the duodenum involvement with a widespread chronic
inflammatory process revealed during surgery. Id. at 8. No respiratory or gastrointestinal viral
infections were found and there was no evidence of any additional event other than severe biliary
system inflammation that contributed to petitioner’s acute pancreatitis. Id. Mora, et al. showed
inflammatory mediators that have been implicated as a component of acute pancreatitis onset. Id.;
Pet. Ex. 45 Ref No. 3.108 According to Dr. Kinsbourne, the immune activation caused by acute
pancreatitis could have lingered to precipitate an earlier onset of GBS. Pet. Ex. 45 at 8.
Dr. Kinsbourne detailed the “extensive medical literature [that] demonstrates that an acute
systemic inflammatory response is integral to the onset of acute pancreatitis.” Pet. Ex. 47 at 6-7;
Pet. Ex. 47 Ref No. 1;109 Pet. Ex. 47 Ref No. 2;110 Pet. Ex. 47 Ref No. 4;111 Pet. Ex. 47 Ref No.
14.112 See also Pet. Ex. 53 Ref No. 1.113 The symptoms petitioner reported – abdominal pain,
nausea, vomiting, and fever – were all due to inflammation mediated by inflammatory cytokines
attendant to the onset of acute pancreatitis but often mistaken for flu-like symptoms. Pet. Ex. 47
at 4-6; Pet. Ex. 45 Ref No. 3;114 Pet. Ex. 53 Ref No. 1 at 2115 (referring to “SIRS,” systemic
inflammatory response syndrome, a concept used to describe the complex pathophysiologic
response to an insult which includes pancreatitis). He added that the concept of SIRS “describes
the complex, physiological response to an insult such as infection, trauma, burns, pancreatitis or a
variety of other injuries. These clinical parameters are not unique to the septic patient and may be
present in a diverse group of clinical disorders that result in a proinflammatory response.” Pet. Ex.
53 at 2. Frossard explained that “‘significant evidence has accumulated that synthesis and release
of pro-inflammatory cytokines and chemokines is also responsible for local injury and systemic
dispersion of the inflammatory mediators. Thus, inflammatory mediators produced within the
gland increase pancreatic injury and radiate to distant organs.’” Pet. Ex. 47 at 7 (quoting Pet. Ex.
107 Guo-Jun Wang, et al., Acute Pancreatitis: Etiology and Common Pathogenesis, 15 World J. of Gastroenterology
1427 (2009), filed as “Pet. Ex. 45 Ref No. 7.”
108 Mora, et al., supra, note 94.
109 Zilvinas Dambrauskas, et al., Different Profiles of Cytokine Expression During Mild and Severe Acute Pancreatitis,
16 World J. of Gastroenterology 1845 (2010), filed as “Pet. Ex. 47 Ref No. 1.”
110 Jean-Louis Frossard & Catherine M. Pastor, Experimental Acute Pancreatitis: New Insights into the
Pathophysiology, 7 Frontiers in Bioscience d275 (2002), filed as “Pet. Ex. 47 Ref No. 2.”
111 J. Mayer, et al., Inflammatory Mediators in Human Acute Pancreatitis: Clinical and Pathophysiological
Implications, 47 Gut 546 (2000), filed as “Pet. Ex. 47 Ref No. 4.”
112 Simon P. Young & Jonathan P. Thompson, Severe Acute Pancreatitis, 8 Continuing Educ. In Anaesthesia, Critical
Case & Pain 125 (2008), filed as “Pet. Ex. 47 Ref No. 14.”
113 Balk, supra, note 96.
114 Mora, et al., supra, note 94.
115 Balk, supra, note 96.
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47 Ref No. 2 at 2116). Petitioner’s inflammatory response was sterile, “as is the case in acute
pancreatitis.” Id.
According to Dr. Kinsbourne, petitioner’s GBS “was not caused by ‘the triggering effect
of respiratory and gastrointestinal infections,’ as Dr. Jamieson insists,” but by “part of the process
of acute pancreatitis itself. . . . The relatively brief interval between the vaccination and the onset
of the Guillain-Barre syndrome remains medically reasonable.” Pet Ex. 47 at 8; Pet. Ex. 49 at 2.
Cruz-Santamaria, et al. explained the “onrush of symptoms” that is part of acute pancreatitis. Pet.
Ex. 49 at 2; Pet. Ex. 49 Ref No. 1.117 Nyström, et al. referred to the diverse inflammatory
manifestations of acute pancreatitis as evidence of SIRS. SIRS is symptomatically like sepsis and
includes a reaction by endogenous mediators to non-infectious systemic inflammation resulting
from trauma, burns, or acute pancreatitis. Pet. Ex. 49 at 2-3; Pet. Ex. 49 Ref No. 3.118 Singh, et al.
showed that acute pancreatitis is diagnosed by two or more of the following: raised temperature,
elevated pulse rate, low blood pressure, and low oxygenation. Here, petitioner had all four. Pet.
Ex. 49 at 3; Pet. Ex. 49 Ref No. 4.119 Kamisawa, et al. reported that 64% of acute pancreatitis
patients have lacrimal gland dysfunction including burning, painful, watery, itchy eyes, or dry
mouth. Pet. Ex. 49 at 3; Pet. Ex. 49 Ref No. 2.120 Wu reported that patients with acute pancreatitis
have an onset of sudden severe epigastric pain that may radiate to their back, frequently with
nausea, vomiting, fever and/or sweating. Pet. Ex. 49 at 6; Pet. Ex. 47 Ref No. 13.121 The synchrony
of the disease onset and rapid remission confirms that petitioner’s symptoms were concomitants
of petitioner’s acute pancreatitis. Vlachou, et al. showed that the extra-pancreatic manifestations
of acute pancreatitis derive from other organs such as the bile ducts, gallbladder, kidneys,
retroperitoneum, mesentery, thyroid, lacrimal glands and orbits, salivary glands, lymph nodes,
lungs, gastrointestinal tract, and blood vessels. Pet. Ex. 49 at 3; Pet. Ex. 49 Ref No. 5. 122
Even if petitioner suffered from an upper respiratory or gastrointestinal virus, not every
viral infection is associated with GBS. Finsterer listed 13 viruses and five vaccines, including the
flu vaccine, associated with GBS out of hundreds of different respiratory and gastrointestinal
viruses with no known connection to GBS. Id.; Resp. Ex. G-1.123 It is known that the flu vaccine
can rarely trigger GBS, and there is no evidence submitted to the contrary. Pet. Ex. 54 at 2; Resp.
Ex. G-1;124 Pet. Ex. 54 Ref No. 3.125 See also Pet. Ex. 54 Ref No. 1126 for a meta-analysis of the
116 Frossard & Pastor, supra, note 110.
117 Dulce M. Cruz-Santamaría, et al., Update on Pathogenesis and Clinical Management of Acute Pancreatitis, 3
World J. of Gastrointestinal Pathophysiology 60 (2012), filed as “Pet. Ex. 49 Ref No. 1.”
118 Nyström, supra, note 98.
119 Vikesh K. Singh, et al., Early Systemic Inflammatory Response Syndrome is Associated with Severe Acute
Pancreatitis, 7 Clinical Gastroenterology and Hepatology 1247 (2009), filed as “Pet. Ex. 49 Ref No. 4.”
120 Terumi Kamisawa, et al., Lacrimal Gland Function in Autoimmune Pancreatitis, 48. Internal Med. 939 (2009),
filed as “Pet. Ex. 49 Ref No. 2.”
121 Bechien U. Wu & Peter A. Banks, Clinical Management of Patients with Acute Pancreatitis, 144 Gastroenterology
1272 (2013), filed as “Pet. Ex. 47 Ref No. 13.”
122 Paraskevi A. Vlachou, et al., IgG4-Related Sclerosing Disease: Autoimmune Pancreatitis and Extrapancreatic
Manifestations, 31 RadioGraphics 1379 (2011), filed as “Pet. Ex. 49 Ref No. 5.”
123 Finsterer, supra, note 84.
124 Finsterer, supra, note 84.
125 Lotte Sahin Levison, Guillain-Barré Syndrome Following Influenza Vaccination: A 15-Year Nationwide
Population-Based Case-Control Study, 29. Eur. J. of Neurology 3389 (2022), filed as “Pet. Ex. 54 Ref No. 3.”
126 Arias, et al., supra, note 43.
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risk of seasonal GBS between 1981 and 2014, which affirms an association between influenza
vaccines and GBS. In this case, petitioner’s medical records do not support an influenza infection,
ruling it out with a negative Sofia test. Pet. Ex. 54 at 1. No gastrointestinal virus was identified
either. Petitioner’s abdominal pain and diarrhea were linked to his acute pancreatitis with both
resolving when the pancreatitis resolved. Petitioner’s pancreatitis was not caused by a virus but
rather chronic inflammation of the gallbladder and cystic duct. Pet. Ex. 54 at 4.
Dr. Kinsbourne disagreed that petitioner’s GBS was caused by viral or bacterial infections
in the one to three weeks before onset. Pet. Ex. 47 at 2-3; Pet. Ex. 48 at 1. He added that Dr.
Jamieson’s “robust” list of triggers for GBS excluded flu vaccination and failed to explain how
any of those triggers could be the cause of GBS in this case. “Certainly, [petitioner’s] treating
physicians did not trot out any of these allegedly robust ‘known triggers’; they attributed the GBS
to the closely antecedent influenza vaccination.” Pet. Ex. 53 at 2.
Petitioner tested negative for influenza A/B and did not have upper respiratory symptoms
of cough, problems breathing, or a gastrointestinal infection. His elevated inflammatory markers
were due to acute pancreatitis which included diarrhea as part of the inflammatory process. Pet.
Ex. 47 at 3; Pet. Ex. 7 at 22, 2; Pet. Ex. 48 at 2. Dr. Kinsbourne described a “flu-like illness” as an
“illness that could clinically be mistaken for influenza.” Pet. Ex. 47 at 4. Verheij, et al. defined flu-
like symptoms as the “sudden onset of self-reported fever, with at least one respiratory symptom
(cough, sore throat, or running or congested nose) and one systemic symptom (headache, muscle
ache, sweats or chills, or tiredness) with a symptom duration of ≤72 hours during a seasonal flu
epidemic.” Id.; Pet. Ex. 47 Ref No. 11;127 Pet. Ex. 48 at 2. Here, the Texas Medical Clinic diagnosis
of “flu like” illness was “patently false” with no record of any such symptoms around the time of
onset of petitioner’s acute pancreatitis. Pet. Ex. 47 at 4; Pet. Ex. 48 at 1. Dr. Kinsbourne argued
that petitioner’s fever of 102°, chills, and night sweats were manifestations of the inflammatory
factors associated with his acute pancreatitis that “spilled to extra-pancreatic locations” and
resolved when the acute pancreatitis resolved two days later. Pet. Ex. 47 at 4; Pet. Ex. 7 at 12.
“Contrary to notations in the medical records, [petitioner] did not have a flu-like illness at that
time.” Pet. Ex. 47 at 4.
Dr. Kinsbourne disagreed with Dr. Tompkins’ opinions regarding the immunology but
deferred to Dr. Akbari. But given that Dr. Tompkins did not deny that studies showed an increased
rate of GBS following the 1976 U.S. flu vaccination campaign, Dr. Kinsbourne questioned what
changed about the vaccine or the studies to make Dr. Tompkins prefer more contemporaneous
studies. Pet. Ex. 47 at 8-9; Pet. Ex. 54 at 1; Pet. Ex. 48 at 4. Dr. Kinsbourne disagreed that
epidemiologic studies are sufficiently powered to detect rare events. Pet. Ex. 47 at 8-9; Pet. Ex. 48
at 4. He added that Dr. Tompkins seemed to discount that the VICP included GBS as a known
consequence of the flu vaccine and a Table injury. Pet. Ex. 48 at 4. He disagreed that the accuracy
of the Influenza A/B tests was questionable citing to Ryu, et al., which published a 94.5%
sensitivity level for influenza A and 91.7% for influenza B on testing. Pet. Ex. 47 at 10; Pet. Ex.
47 Ref No. 6.128 He disagreed that petitioner actually suffered from a flu infection and that the
testing could have had a false negative result. Id.
127 Verheij, et al., supra, note 95.
128 Ryu, et al., supra, note 102.
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Dr. Kinsbourne relied on Schonberger, et al. to show that, while the highest incidence of
GBS was within the second and third week following flu vaccination, there were cases with onset
between zero and one day, with the greater number between two and three days. Pet. Ex. 45 at 5.
See generally Pet. Ex. 45 Ref No. 5.129 Dr. Kinsbourne cited Park, et al. which showed that, of 48
GBS patients studied, more than half had onset within two days post-vaccination. Pet. Ex. 45 at 5;
Pet. Ex. 45 Ref No. 4 at 5.130 Petitioner’s onset was 2.5 days after flu vaccination. Pet. Ex. 45 at 4.
In sum, Dr. Kinsbourne referred to respondent’s proposed alternative causation theories as
based upon a fictional and unspecified viral infection cobbled together from a report of non-
specific inflammatory symptoms with no evidence in the medical record. This unspecified
infection is then identified by respondent as ushering in petitioner’s pancreatitis which in turn
caused his GBS. Pet. Ex. 47 at 11; Pet. Ex. 53 at 1; Pet. Ex. 54 at 1. There was no evidence of
infection in the risk period for petitioner’s GBS and no evidence of alternative cause for his GBS.
The flu vaccine was the only viable cause of the GBS in evidence. Pet. Ex. 47 at 11; Pet. Ex. 48 at
5. Petitioner’s treating physicians diagnosed him with GBS “following vaccination” with no other
diagnoses offered. Pet. Ex. 53 at 3; Pet. Ex. 11 at 2, 12, 14, 24, 150, 172, 175, 181, 192, 200.
“There was no expression of uncertainty about vaccination as being the trigger. There was no
search for any other trigger.” Pet. Ex. 53 at 2.
Dr. Kinsbourne concluded that petitioner developed GBS 2.5 days after receipt of a flu
vaccination consistent with “empirical evidence in the medical literature on GBS.” Pet. Ex. 45 at
8. Acute pancreatitis has not been shown to be a trigger for GBS and there was no evidence of
viral infection in this case that could have done so. Id. Flu vaccination is an accepted cause or
trigger of GBS. There is no viable alternative in the evidence but the flu vaccine as the cause of
petitioner’s GBS. Id.
Next, Dr. Akbari described how the immune system functions in maintaining homeostasis
while mounting an immunological memory response and how that same process can promote
autoimmunity by aberrant response to a challenge, whether vaccination, infection, or another
environmental trigger. Pet. Ex. 43 at 20. Dr. Akbari explained that, upon receipt of a flu vaccine,
complex molecules called inflammasomes activate the production of cytokines, including those in
the interleukin family which are potent stimulators for adaptive immune response. Pet. Ex. 43 at
5; Pet. Ex. 46 at 1-5; Pet. Ex. 46 Ref No. 1;131 Pet. Ex. 46 Ref No. 2;132 Pet. Ex. 46 Ref No. 3;133
Pet. Ex. 46 Ref No. 4;134 Pet. Ex. 46 at 5-7; Pet. Ex. 48 at 12-14; Pet. Ex. 48 Ref No. 14;135 Pet.
Ex. 48 Ref No. 15;136 Pet. Ex. 48 Ref No. 16;137 Pet. Ex. 48 Ref No. 17;138 Pet. Ex. 48 Ref No.
18.139 The activation of cytokines, particularly ILs, can occur quickly, within hours to days of
129 Schonberger, et al., supra, note 26.
130 Park, et al., supra, note 27.
131 Crooke, et al., supra, note 63.
132 Wan, et al., supra, note 64.
133 Yang, et al., supra, note 65.
134 Hartenian & Broz, supra, note 66.
135 Tweedell, et al., supra, note 67.
136 Christian, et al., supra, note 68.
137 Tang, et al., supra, note 69.
138 Man & Kanneganti, supra, note 70.
139 Won, et al., supra, note 71.
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vaccination. Cytokines work in combination with the tumor necrosis factor, or TNF-a, to
experimentally induce demyelination, fever, and increased lassitude providing strong evidence for
the role these cytokines play in the production of Th17 cells. Pet. Ex. 46 at 13-14, 24-25; Pet. Ex.
48 at 20-21, 23; Pet. Ex. 52 at 1-2. Both flu infection and flu vaccination can produce
demyelinating inflammasomes and cytokines. Pet. Ex. 46 at 6; Pet. Ex. 48 at 14. There are often
notably increased levels of Th17 cells in patients with peripheral and central demyelinating
disease. Pet. Ex. 46 at 6; Pet. Ex. 46 Ref No. 8;140 Pet. Ex. 48 at 14-15.
According to Dr. Akbari, highly activated T cells can enter the nervous system within hours
after being in the periphery, exerting effector function on the nervous system by secreting
proinflammatory cytokines and interleukins. This process likely resulted in the symptoms
petitioner described in the days following his flu vaccination. Pet. Ex. 46 at 25. Petitioner already
had activated ILs from pancreatitis and diarrhea prior to his receipt of the flu vaccination. The
addition of the flu vaccination to a system already in an inflammatory state resulted in a quicker
onset and was a substantial factor in petitioner’s development of GBS. Pet. Ex. 46 at 13-14, 24-
25; Pet. Ex. 48 at 20-21, 23; Pet. Ex. 52 at 1-2. Dr. Akbari noted that no scientific data exists to
support a correlation between pancreatitis and GBS. Pet. Ex. 46 at 14. But studies have reported
GBS within two to three days of immunization. Pet. Ex. 46 at 14; Pet. Ex. 48 at 1-6 (detailing each
article showing onset of two to three days for GBS); Pet. Ex. 43 Ref No. 12;141 Pet. Ex. 43 Ref No.
23;142 Pet. Ex. 43 Ref No. 24;143 Pet. Ex. 43 Ref No. 25.144
Further, Schonberger reported several cases in which the onset of GBS was within two
days of vaccination, blurring the distinction between three and two days as an acceptable
timeframe for onset. Dr. Akbari added that Dr. Jamieson dismissed the occurrence of GBS in
54.2% of patients in the Park report within 48 hours yet provided no robust evidence to refute
these findings. Pet. Ex. 52 at 3. “Taken together all these data indicate that a recall response to
H1N1 influenza and/or Influenza A antigens that cross-reacted with myelin can occur within a
time interval of 54 hours or earlier from the flu immunization.” Pet. Ex. 43 at 19-20; Pet. Ex. 46
at 25. Dr. Akbari agreed that the onset of symptoms “56-58 hours post-vaccination[] is atypical
but consistent with established literature particularly regarding fast acting immune cells, GBS and
flu vaccine.” Pet. Ex. 52 at 19. Therefore, “[s]cience cannot definitively rule out that the flu vaccine
administered to [petitioner] was not a substantial causal factor in the induction of demyelinating
disease.” Pet. Ex. 48 at 21. Within a reasonable degree of medical probability, had petitioner not
received the flu vaccine, he would not have developed GBS. Pet. Ex. 43 at 20.
And in Park, GBS occurred within 48 hours in 54.2% of the patients studied, a study which
Dr. Jamieson dismissed. Pet. Ex. 52 at 3; Pet. Ex. 48 Ref No. 3 at 1, 3.145 According to Dr. Akbari,
when all the data is taken together recall response to H1N1 influenza and/or influenza A antigens
that cross react with myelin can occur within a time interval of 54 hours or earlier following flu
vaccination. Pet. Ex. 43 at 19-20; Pet Ex. 46 at 25. Agreeing that onset of symptoms in 56-58 hours
140 Mei, et al., supra, note 76.
141 José Francisco Zambrano-Zaragoza, Th17 Cells in Autoimmune and Infectious Diseases, 2014 Int’l J. of
Inflammation (2014), filed as “Pet. Ex. 43 Ref No. 12.”
142 Park, et al., supra, note 27.
143 Takeda, et al., supra, note 73.
144 Khoruts, et al., supra, note 72.
145 Park, et al., supra, note 27.
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post-vaccination is atypical, Dr. Akbari argued that it is consistent with established literature,
particularly regarding fast-acting immune cells, GBS, and the flu vaccine. Pet. Ex. 52 at 19. He
added that immunology is complex. Because “nothing in science is ever proven,” the assertion that
the flu vaccine caused petitioner’s GBS by a preponderance of the evidence meets scientific rigor.
Pet. Ex. 48 at 22. “Science cannot definitively rule out that the flu vaccine administered to
[petitioner] was not a substantial causal factor in the induction of demyelinating disease.” Id. at
21.
ii. Respondent’s Experts
Dr. Tompkins summarized petitioner’s medical record and concluded that he suffered from
respiratory and gastrointestinal infections, both known to cause GBS, in the two to three weeks
prior to the onset of GBS. Therefore, the flu vaccine was not a factor in the development of
petitioner’s GBS. Resp. Ex. B-1 at 10.
Dr. Tompkins then addressed each study on which petitioner relied in support of onset in
fewer than three days, claiming that once the confounders were removed, so was the risk. Resp.
Ex. B-1 at 4. Schonberger studied the 1976 swine flu vaccination but failed to consider prior
infection, despite the peak attack rate for GBS occurring in December 1967. This study established
the risk window for GBS as seven to 21 days following the antecedent event. Resp. Ex. B-1 at 4;
Pet. Ex. 45 Ref No. 5;146 Pet. Ex. 43 at 4, 11. Polakowski noted a slight increase in risk, with the
greatest risk observed eight to 21 days after vaccination but did not account for infections within
six weeks prior to GBS onset. Resp. Ex. B-1 at 4; Pet. Ex. 43 Ref No. 20 at 8-9.147 Perez-Vilar did
not detect an increase in GBS in the one-to-42- or the eight-to-21-day risk windows.148 Resp. Ex.
B-1 at 4-5; Pet. Ex. 43 Ref No. 21 at 1.149 Salmon noted a slight insignificant risk of GBS following
H1N1 vaccine with confounding effects of respiratory infection prior to onset. Resp. Ex. B-1 at 5;
Pet. Ex. 43 Ref No. 22 at 5, 6.150 Therefore, the publications relied upon by petitioner actually
provided strong evidence for a risk window starting one week after the antecedent event. Any
observations of onset sooner had confounding factors in the studies that weakened any conclusions
regarding the risk from vaccination or early onset. Resp. Ex. B-1 at 5; Resp. Ex. D-2 at 7-13.
Dr. Tompkins later agreed that Salmon and Polakowski reported two to three cases of GBS
within two days of receipt of the flu vaccine. However, “[b]eyond the absence of any statistical
support for these cases to be significant, the authors and Dr. Akbari cannot demonstrate that these
individual cases were causally associated with influenza vaccination. Rather, they were diagnosed
with GBS following receipt of the 2009 H1N1 vaccine.” Resp. Ex. G at 4-5; Resp. Ex. G-22;151
Pet. Ex. 43 Ref No. 20.152 Dr. Tompkins further criticized Park as having several problems
146 Schonberger, et al., supra, note 26.
147 Laura L. Polakowski, Chart-Confirmed Guillain-Barré Syndrome After 2009 H1N1 Influenza Vaccination Among
the Medicare Population, 2009-2010, 178 Am. J. Epidemiology 962 (2013), filed as “Pet. Ex. 43 Ref No. 20.”
148 Dr. Akbari incorrectly attributed these findings to Park.
149 Silvia Perez-Vilar, et al., Guillain-Barré Syndrome After High-Dose Influenza Vaccine Administration in the United
States, 2018-2019 Season, 223 J. of Infectious Diseases 416 (2021), filed as “Pet. Ex. 43 Ref No. 21.”
150 Salmon, et al., supra, note 42.
151 Daniel A. Salmon, et al., Guillain-Barré Syndrome Following Influenza Vaccines Affords Opportunity to Improve
Vaccine Confidence, 223 J. of Infectious Diseases 355 (2021), filed as “Resp. Ex. G-22.”
152 Polakowski, et al., supra, note 147.
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undermining the impact of the findings, including selection and data biases. Park used only
individuals who received compensation for vaccine-related injuries, with more than a third of the
participants not meeting the Brighton Criteria for GBS, and with onset of less than three days in
children compared to a much longer period in adults with no explanation for the differences. “[T]he
fact that older individuals had a much greater interval between vaccination and symptom onset
reduces the suggested importance of this observation.” Resp. Ex. G at 5; Pet. Ex. 48 Ref No. 3.153
Further, studies by Wise, Kwong, and Marks showed onset within the first week following
vaccination using data collected from the 2009 H1N1 pandemic vaccination campaign, the 1976
H1N1 vaccination campaign, or the Korea National Vaccine Injury Compensation Program from
the 2009 pandemic, providing little reliable evidence for the two-day onset in this case. Resp. Ex.
G at 5; Pet. Ex. 48 Ref No. 5;154 Pet. Ex. 48 Ref No. 6;155 Pet. Ex. 48 Ref No. 7.156
Dr. Tompkins concluded that while the studies presented by petitioner may offer new
insights for potential mechanisms for autoimmune disease, they fail to provide a clear mechanism
connecting the current inactivated flu vaccination with GBS. Resp. Ex. G at 5. Further, the studies
relied upon as suggesting increased cytokine levels following inactivated or live attenuated flu
vaccines either did not look at onset within two days of vaccination or tested only women with
sore arms and found TNF-α, IFN- γ, IL-6, IL-8, and IL-10 to be lower in all vaccinated groups. Id.
at 8; Pet. Ex. 48 Ref No. 17 at 3, 4.157 See also Pet. Ex. 48 Ref No. 1 at 11.158
Finsterer discussed triggers for GBS including six bacteria, 13 viruses, and five vaccines
that range from highly prevalent to rarely associated with GBS. Id.; Resp. Ex. G-1.159 Finsterer
noted that while GBS has been causally related to several vaccinations, other studies do not
confirm this. Resp. Ex. G at 2. Further, 30% of GI and respiratory infections become asymptomatic
prior to the onset of GBS. Dr. Tompkins concluded that infection is the most common trigger for
GBS and that infection alone was sufficient to trigger the majority of GBS cases. Id.
Dr. Tompkins maintained that the repeated viral infections described in petitioner’s
medical records “are not only the most likely triggers for [petitioner’s] GBS, they are also
individually sufficient to trigger GBS.” Resp. Ex. G at 3.
Dr. Jamieson also opined that in the weeks prior to the onset of his GBS, petitioner suffered
from “multiple systemic viral and bacterial infections, including a flu-like illness, gastroenteritis,
pancreatitis, bacteriuria, and cholecystitis” which were more likely the triggering event for his
GBS than the flu vaccination. Resp. Ex. A-2 at 12; Pet. Ex. 7 at 1-5. She referenced petitioner’s
153 Park, et al., supra, note 27.
154 Matthew E. Wise, et al., Guillain-Barré Syndrome During the 2009-2010 H1N1 Influenza Vaccination Campaign:
Population-Based Surveillance Among 45 Million Americans, 175 Prac. of Epidemiology 1110 (2012), filed as “Pet.
Ex. 48 Ref No. 5.”
155 Jeffrey C. Kwong, et al., Risk of Guillain-Barré Syndrome After Seasonal Influenza Vaccination and Influenza
Health-Care Encounters: A Self-Controlled Study, 13 Lancet Infectious Diseases 769 (2013), filed as “Pet. Ex. 48 Ref
No. 6.”
156 James S. Marks & Thomas J. Halpin, Guillain-Barré Syndrome in Recipients of A/New Jersey Influenza Vaccine,
243 JAMA 2490 (1980), filed as “Pet. Ex. 48 Ref No. 7.”
157 Man & Kanneganti, supra, note 70.
158 Salmon, et al., supra, note 42.
159 Finsterer, supra, note 84.
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medical records which documented “flu-like illness,” acute pancreatitis possibly related to viral
infection, and resolved gastroenteritis. Resp. Ex. A-2 at 12; Pet. Ex. 7 at 1-5; Pet. Ex. 20 at 197-
199; Pet. Ex. 20 at 2-3. She added that, two months later, petitioner was treated with antibiotics
for acute and chronic acalculous hemorrhagic cholecystitis. Resp. Ex. A-2 at 12; Pet. Ex. 4 at 178.
Further, she argued that petitioner had AMAN particularly associated with gastrointestinal
infections as the triggers. “His multiple preceding infections, including gastrointestinal infections,
are a more usual and accepted trigger for AMAN, than is vaccination.” Resp. Ex. A-2 at 12; Resp.
Ex. C at 3-4.
Dr. Jamieson added that viral infections are diagnosed clinically without specific viral
pathogen “so the absence of a specific identified virus by a an [sic] assay or culture is not
dispositive.” Id. at 3. Moreover, the presence of inflammation did not preclude viral infection since
inflammation is often triggered by infection with multiple types of pathogens. Id. Further, since
only two-thirds of patients with GBS report an antecedent event, leaving one-third developing
GBS without any antecedent event, “[p]utting aside the copious evidence of [petitioner’s]
antecedent infections, Dr. Kinsbourne’s argument is belied by the accepted truth about infections
preceding GBS in only approximately two thirds of cases of GBS, as well as the shortened period
of time of perceived risk.” Id. at 4.
Dr. Jamieson next asserted that Dr. Akbari’s discussion on onset did not align with his
references in support of a zero-to-two-day onset after the flu vaccination. Resp. Ex. C at 5-6; Resp.
Ex. A-18.160 See also Resp. Ex. A-19161 (finding no increase of GBS in the first six days post-
vaccination); Pet. Ex. 43 Ref No. 20162 (analyzing data from Medicare for the 2009 monovalent
H1N1 influenza vaccine of those admitted to the hospital with GBS in the 126-day period post-
vaccination, but not providing information about early risk after vaccination with seasonal
vaccination); Resp. Ex. G-21163 (performing a claims-based self-controlled risk interval analysis
and finding no statistically significant increased risk for GBS in the one-to-42-day risk windows).
She added that studies cited by petitioner were inapposite. The Schonberger study studied swine
flu, while the Park, et al. study did not have normative data for comparison and could not be
replicated by other papers including Schonberger. Resp. Ex. A-2 at 12; Resp. Ex. A-17;164 Resp.
Ex. A-18.165 She argued that simply because ranges of onset include outliers occurring on either
end of a bell-shaped curve, this does not suggest that inclusion of every time point on either end
of the range automatically validates causation at all timeframes. Resp. Ex. C at 3. Dr. Jamieson
concluded that none of these studies prove that the flu vaccine can cause GBS in under three days.
Resp. Ex. C at 6; Resp. Ex. F at 3.
Dr. Jamieson did not find Dr. Akbari’s conclusions about immune system stimulation
following vaccination a persuasive and credible medical theory causally linking flu vaccination
with the development of peripheral neuropathy and GBS in petitioner. The short timeframe
between petitioner’s vaccination and the multitude of other, more plausible triggers for his
160 Park, et al., supra, note 27.
161 Salmon, et al., supra, note 42.
162 Polakowski, supra, note 147.
163 Silvia Perez-Vilar, et al., Surveillance for Guillain-Barré Syndrome After Influenza Vaccination Among U.S.
Medicare Beneficiaries During the 2017-2018 Season, 37 Vaccine 3856 (2019), filed as “Resp. Ex. G-21.”
164 Id.
165 Park, et al., supra, note 27.
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GBS/AMAN preclude finding that causal link.
3. Discussion
Petitioner’s medical records provide no indication that he suffered from any health
problems or from alcohol abuse prior to October 2016. However, his records during the month of
October 2016 reflect several weeks of unfortunate medical events beginning on October 4, 2016.
Petitioner experienced a host of symptoms ultimately determined to be acute pancreatitis, the onset
of diabetes requiring medication, the need for cardiac catheterization, and ultimately gallstones
with a blockage requiring surgery in December. Pet. Ex. 45 at 1-2; Pet. Ex. 53 at 2; Pet. Ex. 20 at
15; Pet. Ex. 2 at 45-46; Pet. Ex. 20 at 448-49; Pet. Ex. 4 at 5-6. On the day he received the flu
vaccination, petitioner was finally feeling well, had no complaints, and had normal strength with
sensory intact on examination. However, his blood work on that date revealed elevated ILs and
other inflammatory markers at the time he received the subject flu vaccination meant to activate
the immune system.
Case law is clear that a petitioner sustains their burden by demonstrating that the
vaccination was a “substantial factor” and a “but for” cause of the injury, even if the vaccination
was not the sole cause. Pafford, 451 F.3d at 1355; Shyface, 165 F.3d at 1352. In Shyface, petitioner
Cheyenne Shyface was vaccinated with whole-cell DPT at the time he was developing an E. coli
infection. Both the vaccine and the E. coli infection could and did cause a fever, which rose to
110°, resulting in his death four days later. Shyface, 165 F.3d. at 1345. Respondent defended the
case arguing that the E. coli infection was the cause of Cheyenne’s fever and death. Cheyenne’s
treating physician testified that both the vaccine and the infection were equally responsible for his
fever and death. The Federal Circuit held that each of the two triggers, the vaccine and the
infection, were substantial factors in causing Cheyenne’s very high fever and death. But for the
vaccination, Cheyenne would not have had the high fever and would not have died. Because it was
not possible to determine whether the vaccine or the infection was the predominant factor, the
Federal Circuit found that both were substantial factors in bringing about Cheyenne’s death.
Shyface, 165 F.3d at 1352-53.
Special masters have since found that where there is a concurrent infection with
vaccination, both are substantial factors in bringing about the injury alleged. Herkert v. Sec’y of
Health & Human Servs., No. 97-518V, 2000 WL 141263, at *12 (Fed. Cl. Spec. Mstr. Jan. 19,
2000) (finding petitioner proved the DTaP vaccine and cytomegalovirus infection were both
substantial factors in causing his son’s transverse myelitis); Nash v. Sec’y of Health & Human
Servs., No. 00-149V, 2002 WL 1906501, at *19 (Fed. Cl. Spec. Mstr. June 27, 2002) (finding both
meningitis infection and DPT vaccination were substantial factors in causing the child’s
condition). I have found that concurrent factors of infection and vaccination are both substantial
factors in the resulting injuries or death. See, e.g., Lehrman v. Sec’y of Health & Human Servs.,
No. 13–901, 2018 WL 1788477, at *19 (Fed. Cl. Spec. Mstr. Mar. 19, 2018); Matten v. Sec’y of
Health & Human Servs., No. 12-155V, 2021 WL 5768148, at *39 (Fed. Cl. Spec. Mstr. Nov. 2,
2021). In Lehrman, I also found that petitioner’s GBS onset was in fewer than three days post-
vaccination because of the already inflammatory state of petitioner’s immune system at the time
he received the flu vaccine. Respondent’s expert in Lehrman agreed that under those conditions a
shorter onset period was feasible. 2018 WL 1788477 at *18.
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Here, petitioner’s inflammatory markers were elevated resulting from acute pancreatitis
and other conditions in the days and weeks prior to the subject vaccination and on the day of the
vaccination. Therefore, the flu vaccination was administered to a petitioner whose immune system
was already in an inflammatory state. This would account for the onset of GBS within 54 to 58
hours post-vaccination, rather than the typically expected three days. Based on the foregoing, I
find that petitioner’s flu vaccination was a substantial factor in the development of his GBS. I also
find that petitioner’s systemic inflammatory condition at the time he received the flu vaccine is the
reason he suffered an onset of GBS within 54 to 58 hours of vaccination. Accordingly, I find that
petitioner has provided preponderant evidence to satisfy Prongs II and III.
C. Burden Shifting: Respondent Must Show an Alternative Cause of Injury.
A petitioner who satisfies all three prongs of the Althen test has established a prima facie
showing of causation. Hammitt v. Sec’y of Health & Human Servs., 98 Fed. Cl. 719, 726 (2011).
Consequently, the burden now shifts to the government to prove that an alternative cause, unrelated
to the administration of the vaccine, was the “sole substantial factor” in causing the alleged injury.
de Bazan, 539 F.3d at 1354; see also Hammitt, 98 Fed. Cl. at 726 (explaining that respondent’s
burden is to show that the “factor unrelated” was the “sole substantial factor” in causing the injury).
Additionally, a factor unrelated “does not include any idiopathic, unexplained, unknown,
hypothetical, or undocumentable cause, factor, injury, illness, or condition.’” § 13(a)(2). See also
Doe/11 v. Sec’y of Health & Human Servs., 83 Fed. Cl. 157 (2008) (holding that an idiopathic
diagnosis cannot be a “factor unrelated,” as it is idiopathic).
As detailed above, petitioner was ultimately diagnosed with acute pancreatitis and diabetes
and underwent cardiac catheterization in the three weeks prior to his receipt of the flu vaccine. Dr.
Kinsbourne showed that the symptoms with which petitioner presented on October 4 and 9, 2016,
were symptoms of acute pancreatitis resulting in the elevation of various inflammatory markers
on petitioner’s blood work. Respondent’s experts unpersuasively argued that petitioner suffered
from upper respiratory and gastrointestinal infections and that those infections were the cause of
his GBS. They did not dispute that petitioner’s blood work on the day of the flu vaccination showed
continued elevated inflammation. However, they maintained that petitioner’s medical issues two
to three weeks prior to his receipt of the vaccination were within a medically appropriate timeframe
for the development of GBS and were the sole cause of his GBS. Regardless, as detailed above, I
have found that petitioner’s receipt of the flu vaccine, when combined with his already
inflammatory state, as evidenced by the blood work performed that day, resulting from the
inflammatory medical conditions from which he suffered in the two to three weeks prior to his
vaccination, was a substantial factor in bringing about his GBS. Thus, respondent cannot sustain
his burden in proving that any of petitioner’s prior medical conditions were the sole substantial
factor in causing his GBS.
VI. Conclusion
Petitioner has put forth preponderant evidence that the influenza vaccine that he received
on October 21, 2016, contributed to and was a substantial factor in the development of his Guillain-
Barré Syndrome. Therefore, petitioner has demonstrated entitlement to compensation. This case
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shall proceed to the damages phase.
IT IS SO ORDERED.
s/ Mindy Michaels Roth
Mindy Michaels Roth
Special Master
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