It's also be great if it reduced pain at the injection site
By PLOS
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Despite their high efficacy against SARS-CoV-2, mRNA-based COVID-19 vaccines are associated with adverse post-vaccination effects, such as fatigue. How can this be avoided?
In a new study publishing today (May 31st, 2022) in the open-access journal PLOS Biology, Ayesa Syenina of the Duke–NUS Medical School in Singapore and colleagues report that a new analysis of blood samples from people vaccinated for COVID-19 has identified distinct molecular characteristics linked to an increased likelihood of post-vaccination fatigue.
Additionally, experiments in mice suggest that
switching the vaccine injection strategy could potentially ease such adverse
effects.
Adverse
post-vaccination effects may influence people’s willingness to get vaccinated
or receive a booster dose, hampering efforts to reduce the spread and severity
of COVID-19. However, the molecular underpinnings of adverse post-vaccination
effects have been unclear.
To improve understanding, Syenina and colleagues analyzed blood samples from 175 healthcare workers who received BNT162b2, the Pfizer-BioNTech COVID-19 vaccine. Specifically, they used the blood samples to analyze a snapshot of each participant’s gene expression, or which genes are turned on or off.
This
analysis revealed that people who experienced moderately severe fatigue after
vaccination were more likely to have higher baseline expression of genes
related to the activity of T cells and natural killer cells—two key cell types
in the human immune system.
The researchers also tested two different vaccination injection strategies in mice. Some mice received BNT162b2 through intramuscular injection, the current method used for human patients, in which the vaccine is injected into the muscles. Other mice received a subcutaneous injection, in which the vaccine is injected into tissue just under the skin.
After
vaccination, compared to mice that received intramuscular vaccination, mice
that received subcutaneous vaccination showed immune-system responses that are
in line with a lower likelihood of adverse effects such as fatigue. However,
subcutaneous injection did not appear to compromise the protective effects of
vaccination.
Further
research will be needed to build on these findings and explore their clinical significance.
Still, they boost understanding of post-vaccination fatigue and offer a
potential strategy to reduce its likelihood.
Coauthor
Eng Eong Ooi adds, “This study provides a first insight into the molecular
basis of a side effect that many have experienced following mRNA vaccination.
We hope that this finding would spur more studies to fully understand the
underpinning mechanisms behind vaccine-associated side effects and collectively
contribute to developing even more tolerable vaccines.”
Reference:
“Adverse effects following anti–COVID-19 vaccination with mRNA-based BNT162b2
are alleviated by altering the route of administration and correlate with
baseline enrichment of T and NK cell genes” 31 May 2022, PLOS Biology.
DOI: 10.1371/journal.pbio.3001643
Funding:
This study was supported by the National Medical Research Council (NMRC) Open
Fund-Large Collaborative Grant (OFLCG19May-0034) and Senior Clinician-Scientist
Award (MOH-000135-00) to E.E.O, and the Open Fund-Young Investigator Research
Grant (MOH-OFIRG18nov-0004) to R.D.A. The funders had no role in study design,
data collection and analysis, decision to publish, or preparation of the
manuscript.
