II. Description of the protocol and hypothesis with pilot data:

To date, individuals suffering from Long-COVID still do not have a specific proven
treatment for this disease as a whole; however, an OMT sequence that was generated for
prolonged post-COVID olfactory dysfunction was shown to generate significant increase in
smell intensity after one treatment. Below is the abstract for a pilot trial:

Osteopathic Manipulative Therapy Effects on Prolonged Post-COVID Olfactory Dysfunction In
2019, the emergence of SARS-CoV2 created countless threats to public health that were
unique to the pathogen. One of the first cardinal symptoms of infection is a sudden loss
of smell and taste. Most people who survive their infection regain their sense of smell;
however, a small amount of the population have prolonged decrease, complete absence, or
abnormalities of smell long after the infection has resolved. This study represents a
single-blinded pilot trial conducted during 2021 to examine the effects of a single
treatment with OMT in individuals who have self-identified prolonged post-COVID anosmia,
hyposmia or parosmia (n=20). This study was conducted at 2 locations within Ohio
University.

Patients were randomly assigned to either the OMT group or a placebo/light touch/sham
group by a flip of the coin and subsequently underwent pre-treatment smell testing of 4
items (Orange, Red Onion, Bourbon, and Perfume) they were then treated based on group
selection, and subsequently underwent post-treatment smell testing to determine change in
olfactory function. It was hypothesized that the OMT group would have a greater
improvement in olfactory function when compared to the placebo group. A Mann-Whitney test
indicated that the post and pre-treatment differences in the correct smell intensity
scores of red onions were significantly higher for participants who received OMT
treatment (Mdn = 2.00) compared to participants who received a non-osteopathic treatment
(Mdn=1.00), U=20, p=0.019, r=5. There was a correlation of an increase in smell intensity
in 2 out of the 3 remaining smell items, the mean difference between pre-smell treatment
and post-smell treatment in the OMT group was higher than the placebo group. This therapy
is a potential treatment for individuals suffering from this PASC related symptom and
should be investigated further to determine the magnitude of OMT's effects on prolonged
post-COVID olfactory dysfunction.

Side effects from the treatment group in the above study were minor but included
light-headedness, drowsiness. After one treatment, there was significant improvement in
olfactory dysfunction in participants in the treatment group as outlined by the study
above. A poster presentation for the above study was accepted at 3 national conferences
(American Academy of Osteopathy, American Academy of Physical Medicine and
Rehabilitation, and American College of Physicians in San Diego) this past year.

The OMT sequence generated for the above trial is reproducible and safe. The OMT protocol
designed for the above trial was as follows:

1. Rib Raising: A patient sits on edge of a treatment table, the physician faces the
patient and places hands on the posterior aspect of the thorax (focus of palpation
being on the vertebral-chondral junction), following patient inspiration and
expiration the physician elevated and depresses the rib cage in tandem. This is
classically hypothesized to engage the Sympathetic chain and cause an initial
stimulation followed by a decrease in sympathetic tone via decreasing restriction of
the anatomical space.

2. Suboccipital Release: The patient lies supine. The physician places the pads of
their phalanges slightly inferior to the occiput and then applies a slight
therapeutic force to the area to stimulate CN-X. The physician stops applying
pressure when a "release" of the fascial plane is appreciated by the physician. This
is classically hypothesized to engage the parasympathetic nervous system and
stabilize parasympathetic tone via decreasing restriction of the anatomical space.

3. Thoracic Inlet Release: The patient lies supine. The physician places each hand on
the ipsilateral aspect of the thoracic inlet and then engages the anatomical space
in three different planes of motions (Flexion/extension,
Lateralization(Rt)/Lateralization (Lt), and Rotation(Clockwise/counterclockwise)).
Once the physician engages all planes, they then place the thoracic aperture into
restriction in relations to the above planes of motion and hold the position until
there is a "release" or an increase in pulse of the carotids which implies a fascial
plane changing to a state of decrease tone. This is classically hypothesized to
decrease restriction to flow in which it relates to the thoracic inlet for lymphatic
drainage.

4. Miller Pump: The patient lies supine. The physician places each hand on the
ipsilateral ribs 2-4 on the anterior aspect of the thorax. The patient is instructed
to inhale and exhale through their mouth. On exhalation the physician places a force
into the thorax to slightly compress the thorax. During the inhalation phase of the
respiratory cycle the physician maintains pressure to prevent the rib cage from
expanding. On the following exhalation phase, the physician applies force to the
thorax to "take up slack" that the thorax would physiologically generate on the
following inhalation motion. The physician then repeats 2-3 more times pending on
the patient's compliance of the physician introduced force/thorax restriction. On
the following inhalation, the physician releases the force and the thorax rebounds
to physiological range of motion. This is classically hypothesized to generate a
negative pressure gradient that generates a rebound thoracic expansion that
correlates to an influx of lymphatic drainage within the thoracic cavity via the
thoracic inlet.

5. Pedal Pump: The patient lies supine. The physician places each hand on the dorsum of
the patient's feet and moves the feet into dorsi-flexion followed by plantar flexion
3 times. This is classically hypothesized to assist with venous pooling in the lower
extremity and "pump" venous flow as well as lymphatic flow into the greater
circulation.

6. Suboccipital Release: This is repeated as this was part of the initial protocol. It
is unethical to not include this step as individuals who benefitted from the initial
protocol underwent this repeat maneuver and received symptomatic relief from
prolonged post-COVID olfactory dysfunction. This stage is also hypothesized to
continually stimulate the parasympathetic nervous symptom through re-engagement of
the vagus nerve as listed above.

7. Cranial Sequence of Sinus Effleurage followed by indirect force within vault hold:
This is the final aspect and hypothetically the most important aspect of the
sequence. The description of this protocol will be divided in two parts (the actions
required to complete and the experimental hypothesis that differentiates the
classical hypothesis)

1. The patient lies supine. The physician places the pads of their phalanges overtop of
the lambdoid suture. The physician then applies a slight therapeutic force on the
suture until a "release" of the fascial plane is appreciated by the physician. A
"release" is sometimes felt as an increase in pulsatile activity. The physician then
places the pads of their phalanges just lateral to the posterior-aspect of the
sagittal suture until a "release" of the fascial plane is appreciated by the
physician. The physician then places the pads of their contralateral thumbs just
lateral to the posterior-aspect of the sagittal suture and spreads the fascia
abutting the suture laterally until a "release" of the fascial plane is appreciated
by the physician. The physician then places the pads of their phalanges just lateral
to the midline of the frontal bone to apply a slight therapeutic spreading force
until a "release" of the fascial plane is appreciated by the physician. The
physician then engages the skull in the "vault hold" in which the 5th digit of each
hand is overlying the ipsilateral squamous aspect of the occiput, the 4th digit is
overlying the mastoid process of the temporal bones, the 3rd digit is overlying the
zygomatic process of the temporal bones, the 2nd digit is overlying the greater
wings of the sphenoid and the 1st digit is overlying the cranium. The physician then
holds this position lightly until the cranial respiratory motion (the phenomenon of
paired skull bones motion along suture lines) is appreciated. This allows the
physician to determine how the sphenoid is moving relative to the occiput and
parietal bones, depending on the motion that is appreciated, the physician moves the
structures to the least amount of restriction and moves the bones back to their
physiological baseline of which a "release" is appreciated.

2. The vault hold is classically hypothesized to be sensing the "pulse" of CSF movement
as it moves through the CNS. This is where the hypothesis that is used in this study
differentiates from the classical hypothesis.

- The classical hypothesis seems incorrect. CSF is produced and consumed in
"steady state". The choroid plexus generates CSF as a continuous function and
arachnoid granulations absorb CSF in a continuous function. There is no "pump"
as there is with the heart to generate forward blood flow. The real question
is, what is generating the paired skull bones movement along suture lines, and
why did this maneuver help improve olfactory function?

- This research team is hypothesizing that this pulse appreciated on paired
cranial bones on suture lines could be a pulse of the sympathetic nervous
system. This is not proven, nor is it described in classical Osteopathic or
Allopathic literature. This hypothesis is supported more in-depth below.

The original pilot study was designed to engage the olfactory region and correlated
lymphatic and vascular drainage. Below is a brief discussion of the hypothesis for the
pilot study:

The pathology of SARS-CoV-2 viral particles has been studied extensively; however, there
are still speculations regarding how the virus causes a prolonged olfactory dysfunction.
There is significant evidence that the SARS-CoV-2 viral particle has a spike protein (S2)
that gains entrance to the human host via attaching Angiotensin-Converting-Enzyme 2
(ACE-2) receptor and is endocytosed into the cell in respiratory epithelium. It has also
been determined that the Transmembrane Serine Protease Gene 2 (TMPRSS2) gene is also
responsible for viral entry into the host [1]. The ACE-2 receptor and TMPRSS2 are
distributed in high concentration throughout the nasal respiratory tract [1],[2].

In general, there are 4 main hypothesized mechanisms surrounding SARS-CoV-2 olfactory
dysfunction:

1. general nasal obstruction due to rhinorrhea

2. olfactory neuron destruction

3. viral CNS infiltration affecting olfactory neurons

4. injury to support cells within the nasal epithelium [3].

A significant number of individuals who were infected with SARS-CoV-2 and have olfactory
dysfunction do not report rhinorrhea or nasal congestion [4]. The timeline of recovery
from anosmia does not align with the timeline for regeneration of olfactory neurons and
support cells, causing this hypothesis to be less likely [3]. In addition, the CNS
infiltration via entrance through olfactory neurons has limited evidence based on the
lack of brain tissue alteration observed via magnetic resonance imaging [3].

Injury to the support cells has increasing evidence as the most likely mechanism of
action in SARS-CoV-2 causing olfactory dysfunction. These support cells have significant
TMPRSS2 and ACE-2 receptor expression as discussed above. It has been shown that the
infection of the golden Syrian hamster with SARS-CoV-2 has shown significant damage to
olfactory epithelium (OE). Bryche, et al. determined that the damages to the OE were due
to significant infection of a large proportion of the sustentacular cells (OE support
cells) and that there was no viral load detected within the olfactory bulb itself. They
also observed significant inflammation within the sustentacular cells that they
determined to be a potential cause of the OE desquamation. [5]

The pilot trial proceeded with the hypothesis that significant inflammation caused by
SARS-CoV-2 damages the sustentacular cells and OE, causing prolonged olfactory
dysfunction. Inflammation causes cytokine release to recruit immune cells and to fight
off invading pathogens. This inflammation can be prolonged if there is not adequate blood
flow to or from the inflamed area. Cytokine release causes immune cell recruitment which
releases more cytokines and stimulates a chain reaction of inflammation. This positive
feedback loop generates excellent recruitment of immune cells and is the basis for the
body's successful immune response. Inadequate clearing of immune cells and cytokines
could potentially continue this positive feedback loop long after the pathogen has been
cleared.

The olfactory zone is relatively small as well as the vasculature related to it. Due to
the significant inflammation caused by SARS-CoV-2 infection, it was hypothesized that the
reason individuals have prolonged olfactory dysfunction is due to inadequate drainage and
clearing of inflammation. The vascular and lymphatic drainage associated with
sustentacular cells are not being cleared of inflammation and cellular debris, which in
turn continues to contribute to individuals' prolonged olfactory dysfunction.

The research team used Osteopathic Manipulative Therapy (OMT) in an attempt to increase
venous and lymphatic drainage from the olfactory region to rid the system of the positive
feedback loop. OMT is a minimally invasive treatment modality that is currently in use
for a variety of ailments. When being done by an experienced physician, there are minimal
side effects and the therapeutic effects are felt by the patient in a relatively short
time period. OMT has been shown to increase lymphatic drainage [6] as well as
hypothesized to increase venous sinus drainage of the cranium and more importantly
stimulate cavernous sinus drainage which is responsible for a significant amount of the
olfactory region's venous return. By using OMT, the physician can alter the fluid
mechanics of this fluid static region and allow the olfactory area to re-establish the
sense of smell.

After the conclusion of the original pilot study and evidence that the therapy offered
benefit; others who were suffering with other Long-COVID symptoms requested the above OMT
sequence and had subjective improvement of other non-olfactory symptoms. It was quite
surprising to find these individuals would regain function and have a decrease in
symptoms related to long-COVID even though the treatment sequence was designed to target
the olfactory zone to reduce a positive feedback loop of inflammation.

This anecdotal evidence of individuals having improvement in function related to other
long-COVID symptoms with the same protocol that was targeted to treat olfactory
dysfunction suggests the hypothesis of why this OMT treatment protocol works should
change. Although the treatment protocol used in the original pilot study is designed to
improve lymph and vascular drainage, there could be another effect the treatment protocol
is having on the body resulting in decrease in Long-COVID symptom burden.

SARS-CoV-2 infection is notorious for causing widespread sympathetic hyperactivity. In
the early stages of the pandemic, individuals who were in critical condition succumbed to
Acute Respiratory Distress Syndrome (ARDS). It is thought that the pathophysiology behind
ARDS is related to sympathetic hyperactivity following an insult. This sympathetic
hyperactivity generates "leaky" capillaries that cause extravasation of lymph to fight
infection. In ARDS this increase in vascular wall permeability leads to lymph filling the
viscera and inhibiting lung compliance and gas exchange which in turn generates
respiratory failure.

This hypothesis has changed in regard to why people get relief from this OMT sequence and
therefore the pathophysiology of Long COVID. Although there is likely a component of
residual inflammation in the body related to a fluid mechanics model, anecdotal evidence
would suggest a stronger driving force is leading to Long COVID symptoms. Could prolonged
sympathetic hyperactivity be the root-cause of Long COVID?

This treatment protocol could generate a significant decrease in sympathetic tone quickly
as well as improve lymphatic and vascular flow. This would explain why participants in
the original pilot study had a significant increase in smell only 10 minutes after the
treatment. This hypothesis would also explain why others treated with the sequence had a
significant improvement in their non-related olfactory symptoms within 10 minutes of one
treatment.

III. Trial Design:

The clinical trial design is a modified cross over study performed over an 8-week period
to assess the effects of OMT on Long-COVID. This study would evaluate individuals with
Long-COVID symptom burden through The Symptom Burden Questionnaire™ for Long COVID
(SBQ™-LC) [7] which is to be taken before treatment. SBQ™-LC is a validated tool
generated to assess for Long-COVID symptom burden generated by the University of
Birmingham in the UK. A user license has been granted to the research team to utilize the
SBQ™-LC. This user license allows the research team to electronically design and
implement this survey independently, this will be done through Red-Cap.

In addition to the survey, the research team will acquire blood pressure (BP) and heart
rate (HR) from all participants before and after treatment, as a proxy measurement of
sympathetic activity. BP and HR are elevated in increased sympathetic tone states and
therefore could be a relative measurement of sympathetic tone in a non-invasive and low
risk manner.

There will be 2 groups: an OMT group (experimental) and a sham-OMT/placebo group
(control). The control group will receive an OMT treatment that is not designed to
stimulate the sympathetic nervous system, but is designed to make participants feel that
they have received OMT which they will. The sham/placebo treatment regiment is listed
below. The experimental group will receive the therapeutic OMT treatment as listed above.
Participants will be placed into respective groups via randomization software or coinflip
if software is unavailable. after completing their consent form.

The experimental group will receive OMT on week 1 and week 2. The control group will
receive the sham-OMT for 1 week and then will receive OMT for 1 week. This design will
allow comparison of treatment vs no treatment as well as 1 treatment vs 2 consecutive
treatments.

This trial will have participants complete SBQ™-LC a total of 4 times. The 1st being upon
consent and prior to any treatment (baseline). The 2nd being upon arrival for the second
treatment (7 days after the first treatment). The 3rd being 7 days after their second
treatment. The 4th survey will be 8 weeks post initial treatment. Goal is N=20. Based on
median effect size of initial pilot data, using a treatment group and an control/sham
group, the median observed effect size was 1.2 leading to an ideal n=8 per group,
followed by an approximate 20% attrition rate will give n=10 per group which is a total
of N=20.

The primary endpoint for this study will be the 8-week mark post initial treatment.

The OMT-Sham treatment is listed below:

1. Bilateral Trapezius Direct Myofascial Release

a. Patient is lying supine with physician seated at the head of the bed. The
physician places 2-3 digits on the superior aspect of the trapezius and engages with
slight pressure until the fascial layer is engarged. Next the physician moves the
fascia while maintaning enough pressure to ensure there is no slippage of the dermis
in contact with the physician's finger pads and moves the myofascial plane in 3
planes of motion (Superior/inferior, Lateral/medial, and clockwise/counterclockwise
rotation) the physician will then determine which of the 3 directions are restricted
to movement, the physician will then engage all planes of motion into the
restriction until a release is palpated.

2. Still's technique of the First rib Bilaterally:

a. Patient is lying supine with physician standing on the side of the rib being
treated. The physician grasps the forearm on the side of the rib being treated while
placing the physician's other hand over the posterolateral aspect of the rib in
question at the T1/Rib 1 costal articulation. The physician positions the patient's
arm anteriorly and adducted. Then the physician will lift the arm into flexion and
abduction in a circumduction motion, continuing the motion with the arm posterior
(behind the trunk) and then back down to the side of the patient.

3. Hamstring Muscle Energy

1. Patient lies supine. Physician stands on the same side that is being treated.
The hip is flexed and knee extended to the point of the restriction. The
physician will hold the leg in this position and will ask the patient to flex
their knee and extend their hip while the physician resists this force for 3-5
seconds. The patient will then relax, and the physician will "take up the
slack" by slightly increasing the hip flexion and knee extension. Repeat this 3
times. Have patient relax and gently set their leg back on the table.

IIIa. Inclusion and Exclusion criteria: As with any research this is difficult,
especially in the setting of Long-COVID. To date there are no official
diagnostic criteria for Long-COVID or the Post-Acute Sequlae of COVID-19. It is
a diagnosis of exclusion and comes from a pertinent medical history and signs
and symptoms presented by an individual suffering from this ailment.

In the light of above, the following is inclusion and exclusion criteria:

- Individuals must claim they have had a prior positive SARS-CoV-2 test at
least 6-weeks before the consenting process to proceed with the study

- Individuals must claim they have at least one of the following symptoms
greater than 6-weeks post infection that is affecting their daily
life(these symptoms correlate with the SBQ™-LC):

Table II: Symptoms of Long Covid Inclusion Criteria:

Shortness of breath or Difficulty Breathing Difficulty with Movement (balance
or tremor) Muscle Pain or stiffness Changes in sexual desire Worsening
Generalized Pain Difficulty with Sleep Changes in Mood (anxiety or depression)
Changes in Erectile function (Biological males only) Palpations (irregular
heart beats) Altered Taste Changes in your Hair Changes in urination Dizziness
Altered Smell Changes in Skin Changes in bowels Fatigue Indigestion Dry or
irritated eyes Changes in sweating Difficulty with Cognition (memory or
thinking) Stomach Pain Changes in menstruation (Biological females only) Chills
or shivering

- If anyone denies the above before consent, they will be excluded from the
trial

- They will also be excluded from the trial if they have suffered any
fractured bones in the last 3 months (this will further decrease risk to
the patient as the patient will be moved by the physician during the
treatment protocol)

- Participants who are enrolled in other Long-COVID trials that have an
intervention during their participation in this trial will be excluded.
However, if they have a history of enrollment in a long-covid trial that
has no interventions during this trial, they will not be excluded based on
their history of acquiring experimental treatment.

IV: Statistical Analysis Plan:

The data acquired from the SBQ™-LC will be used to determine changes in long
covid symptom burden and change relative to treatment participant received. As
of right now, the team has secured the licensure to use the physical paper
SBQ™-LC; there are current attempts to acquire a digital version to help assist
with logistics and bring down burden on the research participants relative to
data collection. All participants will take the survey a total of 4 times, the
first being administered on arrival and consenting process as a baseline
followed by one administered every 7 days. The survey will be uploaded via
RedCap and sent to participants electronically.

The SBQ™-LC has n=123 symptoms in 17 different scales measured with the target
population being Adults (18+ years) living with post-COVID condition, also
known as post-acute sequelae of COVID-19 (PASC), or Long COVID. In addition,
the fact that there are multiple different scales within the SBQ™-LC, there can
be analysis based on this treatment efficacy based on different symptom
constellations. For example: this treatment may only be helpful for olfactory
function and not gastro-intestinal symptoms, this survey will help
differentiate this question.

There will be one experimental group to control group survey that will give
info on benefit of one vs no treatment. Then there will be a 2 consecutive
treatment group to 1 treatment comparison. This will help identify if
participants benefit from multiple treatments or if only one treatment is
enough for symptom management as well as assist with assessing the placebo
effect.

Finally, BP and HR will be acquired for participants while in the clinic. This
will give us proxy information to see if there is an impact on this treatment
relative to participants sympathetic tone.

Statistical Analysis: Continuous variables will be summarized using mean and
standard deviation if they are normally distributed or using median and
interquartile range if they are not normally distributed. The
Smirnov-Kolmogorov test will be used to evaluate normality. Categorical
variables will be summarized with frequency count and percentage. Linear mixed
models will be used to evaluate the change pre-post treatment in symptoms'
scores as well as the difference of that change between different groups. The
mixed models will include a group variable (with 2 categories: OMT, sham), a
timepoint variable (pre-post treatment), and their intersection. Random
intercept and slope will be included for each participant to account for
individual variability and change. Linear contrasts will be built on the
interaction term to obtain estimates of different comparisons for the study.
All tests will be 2-sided. The significance level will be set to 5%. If the
linear model assumptions are not satisfied, variable transformations will be
explored. To account for multiple comparisons, the p-values will be adjusted
accordingly using Bonferroni correction or similar methods, and care will be
taken in the interpretation of the results.

Power Analysis: In the analysis, the pre-post treatment changes will be
compared between the treatment group (OMT) and the sham group. In the pilot
study, we have observed an effect of OMT of effect sizes of 0.63-1.9. We would
like to detect the median of those effect sizes, 1.2 classified as huge on the
Sawilowsky's extension of Cohen criteria. Group sample sizes of 8 for OMT and 8
for sham achieve over 80% power to detect this effect size using a 2-sided
Mann-Whitney U test assuming a double exponential data distribution of the data
(a conservative option) with a significance level of 0.05. To account for
potential loss of data, we will enroll 20% participants in each group, i.e. 10
participants per group for a total of 20.

IVa. Risks to patients:

- Lightheadedness/dizziness post-treatment

- Drowsiness post-treatment

- Potential frustration related to no improvement of symptoms

IVb. Risk Mitigation system:

- There will be a 10-minute timer after each treatment before vitals are
assessed.

- Participants will be asked to report any side effects

- All adverse events will be recorded and submitted to University of
Louisville IRB in concordance with IRB adverse event identification
protocol.

IVc. Good Clinical Practices and Good Laboratory Practices All participants
will have adequate time to be consented as well as ask any questions regarding
the project. University of Louisville IRB approval will be completed prior to
initiating the research. Participants will be made aware of all side effects
prior to treatment. All participants will be made aware that participation in
this trial is voluntary and they can exit the trial at any time.

IVd. Discussion of major anticipated challenges:

The largest challenge in this study will be maintaining follow up with these
participants. The research team will generate an electronic SBQ™-LC survey to
make participant participation have a higher likelihood of completion due to
decreased physical logistical burden.

V Informed Consent Process:

Consent will be obtained upon participant physical arrival to the study site.
Consent documents will be given to participant prior to any survey distribution
or vital signs acquirement. After consent is obtained, participant will begin
survey prior to vital signs or treatment is initiated. An approved study team
member will be acquiring consent for all participants.

Citations

[1] Mollica V, Rizzo A, Massari F. The pivotal role of TMPRSS2 in coronavirus
disease 2019 and prostate cancer. Future Oncol. 2020;16(27):2029-2033.
doi:10.2217/fon-2020-0571

[2] Gengler, I, Wang, JC, Speth, MM, Sedaghat, AR. Sinonasal pathophysiology of
SARS-CoV-2 and COVID-19: A systematic review of the current evidence.
Laryngoscope Investigative Otolaryngology. 2020; 5: 354- 359.
https://doi.org/10.1002/lio2.384

[3] Butowt R, von Bartheld CS. Anosmia in COVID-19: Underlying Mechanisms and
Assessment of an Olfactory Route to Brain Infection [published online ahead of
print, 2020 Sep 11]. Neuroscientist. 2020;1073858420956905.
doi:10.1177/1073858420956905

[4] Lechien, Jerome R et al. "Olfactory and gustatory dysfunctions as a
clinical presentation of mild-to-moderate forms of the coronavirus disease
(COVID-19): a multicenter European study." European archives of
oto-rhino-laryngology: official journal of the European Federation of
Oto-Rhino-Laryngological Societies (EUFOS): affiliated with the German Society
for Oto-Rhino-Laryng

[5] Bryche B, St Albin A, Murri S, et al. Massive transient damage of the
olfactory epithelium associated with infection of sustentacular cells by
SARS-CoV-2 in golden Syrian hamsters. Brain Behav Immun. 2020;89:579-586.
doi:10.1016/j.bbi.2020.06.032

[6] Knott EM, Tune JD, Stoll ST, Downey HF. Increased lymphatic flow in the
thoracic duct during manipulative intervention. J Am Osteopath Assoc. 2005
Oct;105(10):447-56. PMID: 16314677.

[7] Hughes SE, Haroon S, Subramanian A, McMullan C, Aiyegbusi OL, Turner GM,
Jackson L, Davies EH, Frost C, McNamara G, Price G, Matthews K, Camaradou J,
Ormerod J, Walker A, Calvert MJ. Development and validation of the symptom
burden questionnaire for long covid (SBQ-LC): Rasch analysis. BMJ. 2022 Apr
27;377:e070230. doi: 10.1136/bmj-2022-070230.