Internal and Emergency Medicine (2021) 16:1113–1119 
https://doi.org/10.1007/s11739-021-02793-x

IM-POINT OF VIEW

Vaccine‑induced thrombotic thrombocytopenia: the elusive link 
between thrombosis and adenovirus‑based SARS‑CoV‑2 vaccines

Rossella Marcucci1 · Marco Marietta2 

Received: 16 May 2021 / Accepted: 9 June 2021 / Published online: 30 June 2021 
© Società Italiana di Medicina Interna (SIMI) 2021

Abstract
The amazing effort of vaccination against COVID-19, with more than 2 billion vaccine doses administered all around the 
world as of 16 June 2021,  has changed the history of this pandemic, drastically reducing the number of severe cases or deaths 
in countries were mass vaccination campaign have been carried out. However, the people’s rising enthusiasm has been blunted 
in late February 2021 by the report of several cases of unusual thrombotic events in combination with thrombocytopenia 
after vaccination with ChAdOx1 nCov-19 (Vaxzevria), and a few months later also after Ad26.COV2. S vaccines. Of note, 
both products used an Adenovirus-based (AdV) platform to deliver the mRNA molecule - coding for the spike protein of 
SARS-CoV-2. A clinical entity characterized by cerebral and/or splanchnic vein thrombosis, often associated with multiple 
thromboses, with thrombocytopenia and bleeding, and sometimes disseminated intravascular coagulation (DIC), was soon 
recognized as a new syndrome, named vaccine-induced immune thrombotic thrombocytopenia (VITT) or thrombosis with 
thrombocytopenia syndrome (TTS). VITT was mainly observed in females under 55 years of age, between 4 and 16 days 
after receiving only Adenovirus-based vaccine and displayed a seriously high fatality rate. This prompted the Medicine 
Regulatory Agencies of various countries to enforce the pharmacovigilance programs, and to provide some advices to restrict 
the use of AdV-based vaccines to some age groups. This point-of view is aimed at providing a comprehensive review of 
epidemiological issues, pathogenetic hypothesis and treatment strategies of this rare but compelling syndrome, thus helping 
physicians to offer an up-to dated and evidence-based counseling to their often alarmed patients.

Keywords  COVID-19 · Vaxzevria · Vaccine-Induced Thrombotic Thrombocytopenia · Heparin-Induced 
Thrombocytopenia · COVID-19 Vaccine Janssen

Background

The still ongoing history of vaccination against COVID-19 
looked like a roller coaster ride for people’s expectations.

The unprecedented fast development of vaccines has kin-
dle hope of  having finally found the way out of pandemic. 
The rising enthusiasm has been blunted in late February 
2021 by the report of several cases of unusual thrombotic 
events in combination with thrombocytopenia after vaccina-
tion with ChAdOx1 nCov-19 (Vaxzevria).

 *  Marco Marietta 
  marco.marietta@unimore.it

1  Department of Experimental and Clinical Medicine, 

“Careggi” University Hospital, University of Florence, 
Florence, Italy

2  Hematology Unit, Azienda Ospedaliero-Universitaria, via del 

Pozzo 71, 41124 Modena, Italy

Following that report, in mid-March, several European 
countries  paused  distribution  of  the  COVID-19  vaccine 
made by the University of Oxford and the pharmaceutical 
firm AstraZeneca.

The review of data analyses from European system of 
pharmacovigilance EudraVigilance (EUDRA) pointed to 
signals of atypical thromboembolism (i.e., cerebral vein 
sinus [CVT] and/or splanchnic vein thrombosis [SVT] and 
arterial thrombosis [AT]), with or without thrombocytope-
nia, mainly occurring in women below 60 years old, with a 
typical time-to-onset within 2 weeks following vaccination.
On 7 April 2021, European Medicines Agency’s (EMA) 
Pharmacovigilance Risk Assessment Committee (PRAC) 
concluded that a causal relationship between vaccination 
with Vaxzevria and adverse events of thrombosis in combi-
nation with thrombocytopenia (TTS) was at least a reason-
able possibility but confirmed that the overall benefits of 
Vaxzevria in the prevention of COVID-19 outweighed the 

Vol.:(0123456789)

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Internal and Emergency Medicine (2021) 16:1113–1119

risks from adverse events including thrombosis in combina-
tion with thrombocytopenia [1].

The  European  countries  then  resumed  vaccinations, 
although Germany, Spain and Italy restricted the use of 
Vaxzevria to people over 60 years, UK to those over 30 and 
France to subjects more than 55 years old.

By April 12, 2021, 6 cases of CVST with thrombocytope-
nia were identified among the recipients of approximately 7 
million Ad26.COV2. S vaccine doses in the US, resulting in 
a temporary pause in vaccination with this product on April 
13, 2021 in US and Europe [2]

Following a thorough safety review, the U.S. Food and 
Drug Administration (FDA), the U.S. Centers for Disease 
Control and Prevention (CDC) and the PRAC determined 
that the use of the Ad26.COV2. S vaccine should resume.

As a precautional measure, the Italian Medicine Agency 
(AIFA) recommended the preferential use also of this vac-
cine in people more than 60 years old.

What are we talking about?

A recent paper from Denmark showed that, altogether, the 
cases of venous thromboembolisms reported in relation to 
the Vaxzevria vaccine did not exceed the expected incidence 
rate [3].

However, very rare cases of a peculiar syndrome, charac-
terized by cerebral and/or splanchnic vein thrombosis, often 
associated with multiple thromboses, with thrombocytope-
nia and bleeding, and sometimes disseminated intravascular 
coagulation (DIC), occurring in otherwise healthy subjects 
have been reported [4–8].

This syndrome, named vaccine-induced immune throm-
botic thrombocytopenia (VITT) or thrombosis with throm-
bocytopenia  syndrome  (TTS),  was  mainly  observed  in 
females under 55 years of age, between 4 and 16 days after 
receiving the Vaxzevria and in a few more cases after Ad26.
COV2. S vaccine [9] and displayed a seriously high fatality 
rate.

But the true question is: how actually rare is this rare 
syndrome, very intriguing for researchers, but very troubling 
for common people?

COVID-19 vaccines have been tested in clinical trials 
with thousands of participants before governments author-
ized their widespread use. However, even the largest clini-
cal trials are not sized to detect extremely rare side effects, 
which  might  occur  in  fewer  numbers  than  one  case  per 
100,000 vaccinations. Now, more than a billion of people 
have been vaccinated against COVID-19, and it is not sur-
prising that even very rare adverse events, such as VITT, can 
appear in safety reports.

Table 1 summarizes the cases of major thromboembolic 

events reported by the involved Regulatory Agencies.

These data deserve some further comments.
First, the incidence of VITT reported in Table 1 refers to 
the entire population of vaccinated subjects. A higher inci-
dence rate following the first dose of Vaxzevria has been 
reported  in  the  younger  adult  age  groups  (18–49  years) 
compared to the older ones (over 50 years): 18.0 vs. 10.2 
per million doses, respectively. Moreover, there is evidence 
that the incidence rate is higher in females compared to men, 
although this is not seen across all age groups and the dif-
ference remains small.

On the other hand, in balancing risks and benefits, it 
should be also considered that COVID-19 seems per se 

Table 1   Cases of VITT reported by Regulatory Agencies

MHRA Cases as of May, 26

EUDRA Cases as of April, 21 VAERS Cases as of May,7

VAXZEVRIA
128 cases (average age 46 years)

VAXZEVRIA

Ad26.COV2. S
28 cases (median age 40 years; range 18–59 years)

220 (average age 54.5 years)

142 cases

–

Cerebral venous sinus 

thrombosis with throm-
bocytopenia

Other major thrombo-
embolic events with 
thrombocytopenia

Estimated Case incidence 13.6 per million doses (348/24.3 

5.68 per million doses 

3.2 per million doses (28/8.7 million  dosesc)

million  dosesa)

(142/25 million  dosesb)

MHRA  UH  Government  Medicines  &  Healthcare  products  Regulatory  Agency;  EUDRA  European  system  of  pharmacovigilance  EudraVigi-
lance; VAERS U.S. Vaccine Adverse Event Reporting System
a 18 cases reported per 13.4 million second doses (estimated case incidence: 1.3 per million doses). https:// www. gov. uk/ gover nment/ publi catio ns/ 
coron avirus- covid- 19- vacci ne- adver se- react ions/ coron avirus- vacci ne- summa ry- of- yellow- card- repor ting
b Data  as  of  May,  1.  https:// www. ema. europa. eu/ en/ docum ents/ refer ral/ use- vaxze vria- preve nt- covid- 19- artic le- 53- proce dure- asses sment- report_ 
en. pdf
c https:// www. cdc. gov/ vacci nes/ acip/ meeti ngs/ slides- 2021- 05- 12. html

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to increase the risk of atypical venous thromboembolism. 
Indeed, an incidence of first-diagnosed CVT in COVID-
19  patients  of  35.3  per  million  (95%  CI  22.6–55.2)  has 
been found, significantly higher than that observed in a 
matched cohort of patients with influenza (RR = 3.83, 95% 
CI 1.56–9.41, P < 0.001) or people who received an mRNA 
vaccine (RR = 6.67, 95% CI 1.98–22.43, P < 0.001) [4 ]. 
In the same study, the incidence of first-diagnosed Portal 
Vein Thrombosis (PVT) in COVID-19 patients was 175.0 
per million (95% CI 143.0–214.1), significantly higher than 
that reported in a matched cohort of patients with influenza 
(RR = 1.39, 95% CI 1.06–1.83, P = 0.02) and people who 
received an mRNA vaccine (RR = 7.40, 95% CI 4.87–11.24, 
P < 0.001) [10].

In this context, a causal relationship between vaccination 
and these adverse events has been considered “plausible” by 
the PRAC of the EMA Agency [11].

This cautious approach makes sense, because the VITT 
only partially meets the Bradford Hill’s Criteria convention-
ally requested to “pass from an observed association to a 
verdict of causation” [12].

Among them, that of biological plausibility is probably 
the most intriguing one, as raises the issue of which mecha-
nism could induce an apparently paradoxical coexistence of 
thrombosis and thrombocytopenia.

What could the connection be 
between blood clots and vaccines?

The association between thrombocytopenia and thrombo-
sis, with a catastrophic clinical picture demonstrating both 
venous and arterial thromboses, raised rapidly the atten-
tion of clinicians. It was soon clear that we were facing a 
new disease, probably associated with a trigger linked to 
Adenovirus-Based SARS-CoV-2 Vaccines. The fact that 
these clinical pictures were not observed after mRNA vac-
cines put adenoviruses in the dock. The subsequent reports 
of similar cases associated with Janssen Vaccine, reinforced 
this hypothesis.

The  binomial  constituted  by  thrombocytopenia  and 
thrombosis is very rare in medicine. We can recognize it 
in  (a)  Thrombotic  thrombocytopenic  purpura–together 
with  anemia  and  hemolysis  signs;  (b)  Heparin-induced 
thrombocytopenia and autoimmune HIT; (c) Catastrophic 
Antiphospholipid Syndrome [13]; (d) disseminated intravas-
cular coagulation—together with signs of clotting factors 
consumption. The latter, however, represents a condition 
which can complicate several diseases associated with clot-
ting activation, and does not represent a ‘per se’ disease.

Quickly it emerged the HIT hypothesis as the most plau-
sible one. The time window for symptoms onset—between 

4 and 16 days—comparable to that seen in HIT corroborated 
the hypothesis.

HIT is a rare immune-mediated adverse drug reaction 
occurring after exposure to heparin [14]. It is a serious and 
potentially fatal condition, which may be associated with the 
development of arterial or venous thrombotic events. From 
a pathophysiologic point of view, circulating molecules of 
heparin bind to platelet factor 4 (PF4), a plasmatic positively 
charged protein released upon platelet activation. PF4 nor-
mally binds to negatively charged glycosaminoglycans on 
the endothelium, displacing anti-thrombin and thus activat-
ing coagulation. However, PF4 binds with greater affinity 
to heparin/PF4 complexes, which become “neoantigens” 
and induce the formation of antibodies against them. Hep-
arin-PF4-IgG immune complexes activate platelets through 
their FcγRIIA receptors, causing their activation, aggrega-
tion and the additional release of PF4, thus determining a 
positive feedback loop of further platelet activation. Pre-test 
clinical probability, screening for anti-PF4/heparin antibod-
ies and documentation of their platelet activating capacity 
are the cornerstones of diagnosis. Both immunoassays—to 
detect the presence and quantify the titer of PF4-heparin 
antibodies—and functional assays—to assess the ability of 
anti-PF4-heparin antibodies to bind and activate platelets in 
the presence of heparin, are needed to confirm the diagnosis.
The  time  window  for  symptoms  onset,  the  presence 
of  both  thrombocytopenia  and  thrombosis,  with  venous 
and arterial localizations, are the points which are simi-
lar between HIT and VITT. In the first cases described in 
Europe, the lethality was very high (about 20%) differently 
from that we usually observe in HIT. Furthermore, in a sig-
nificant proportion of patients with VITT, the disease was 
complicated by DIC, with the presence of very low levels 
of platelet count (in the majority of cases < 20,000/mmc). 
These characteristics make this clinical entity more similar 
to autoimmune HIT with respect to classical HIT. Autoim-
mune HIT [15], in fact, is often complicated by DIC and it 
is characterized by a very low platelet count. Autoimmune 
HIT is the term adopted to define form of HIT in which the 
previous exposure to heparin is not always present: in these 
cases, we can demonstrate the presence of both heparin-
dependent and heparin-independent antibodies activating 
platelets. In autoimmune HIT, some case reports [16] docu-
ment the clinical efficacy of high-dose IgG administration 
which, conversely, is not routinely used in classical HIT. PF4 
also binds to polyanions expressed on the cell wall of a wide 
variety of Gram-negative and Gram-positive bacteria and 
plays a role in bacterial host defense. Binding of PF4 to poly-
anions results in its conformational change. These antibodies 
are associated in the general population with the presence 
of chronic bacterial infections such as periodontal disease 
[17]. There is a continuum of clinical sequelae resulting 
from anti-PF4/polyanion antibodies (anti-PF4/P-ABS): the 

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Internal and Emergency Medicine (2021) 16:1113–1119

majority of individuals remain asymptomatic, while in HIT, 
anti-PF4/P-ABS activate platelets and the clotting system, 
resulting in life-threatening thrombotic complications when 
patients receive the polyanion heparin. Anti-PF4/P-ABS are 
also induced after major surgery without heparin treatment 
when mechanical compression devices are used for thrombo-
sis prophylaxis [18]. In this case, continuous tissue compres-
sion likely acts as danger signal.

The extreme sequela is autoimmune HIT, in which indi-
viduals develop multiple vessel occlusions without any drug 
exposure. Typically, in these patients, PF4/P-ABS are found 
by enzyme-linked immunoassay (EIA) at very high titers and 
activate platelets in the absence of polyanions in functional 
assays.

On April 9, 2021, two papers were published reporting 
two EU case series of patients affected by this condition, 
named for the first-time VITT [4, 5]. In both papers, authors 
were able to document the presence of circulating antibodies 
able to activate platelets.

Two very recently published paper brought some more 
knowledge about the plausible sequence of events leading 
to VITT.

Mc  Gonagle  and  Colleagues  suggested  that  the  local 
tissue micro-trauma following vaccine inoculation brings 
adenoviral DNA in contact with PF4, with substantially 
increased anti-PF4 autoantibody production in suscepti-
ble subjects [19]. The high-titer circulating autoantibodies 
against PF4 may lead to immuno-thrombosis in specific sites 
of susceptibility, such as the portal and the cerebral vein cir-
culation, where an extensive platelet factor 4 (PF4)-viruses/
microbiota interaction is already existing to ensure the nor-
mal immunity and antigen clearance.

Another postulated mechanism is based on the availability 
of soluble Spike protein variants in a systemic fashion as a 
result of alternative splice events [20]. These soluble Spike 
variants can bind to ACE2 expressing endothelial cells, which 
in turn may trigger an Antibody Dependent Cell-mediated 
Cytotoxicity (ADCC) or Complement-Dependent Cytotoxic-
ity (CDC).

It can be assumed that this pathological phenomenon most 
probably will take place in those vessels where such soluble 
Spike protein variants can accumulate because of a non-uni-
directional blood flow, i.e. the cerebral venous sinuses [20].

Whatever the pathogenic mechanism of VITT is, in order 
to document and diagnose this rare syndrome, besides clini-
cal features (thrombocytopenia plus thrombosis with mul-
tiple localizations, mainly cerebral vein thrombosis and 
splanchnic thrombosis), laboratory should demonstrate the 
presence of antibodies anti-PF4 and, possibly, the ability 
of activating platelets. Unfortunately, not all immunologi-
cal assays for detecting Ab anti-PF4/heparin have the same 
ability to detect also these VITT antibodies  (6) and the 

administration of i.v. IgG might mask the functional ability 
of activating platelets.

Which laboratory test, if any, is needed 
before or after vaccination?

No data are available on the possible utility of a laboratory 
test before vaccination. In fact, no correlation has been dem-
onstrated between the onset of this reaction and laboratory 
evaluation, for example, of markers of clotting function, such 
as PT or aPTT. Similarly, the evaluation of platelet count 
has no role in this setting before or after vaccination. We 
know that vaccination may be associated with an aspecific 
reduction in platelet count, but this mechanism is absolutely 
different from that described in VITT. Therefore, the iden-
tification of a weak reduction in platelet number should 
generate unjustified alarmism and medical intervention. In 
classical HIT, which represents our model in this context, 
a high proportion of patients exposed to heparin develop 
antibodies anti-PF4/heparin, but only a small part of them 
develop antibodies able to activate platelets and to determine 
thrombotic manifestations.

At the time of writing this paper, we have to discourage 
clinicians from any kind of laboratory test before vaccina-
tion, to possibly identify patients at higher risk of developing 
VITT.

How to manage the Vaccine‑Induced 
Thrombotic Thombocytopenia?

Faced to the severity of VITT, and to the lack of evidence 
about its management, many scientific societies provided 
guidance helping physicians to tackle such a pathophysi-
ological entity [21–23].

Table 2 summarizes the main recommendations provided 

by these societies.

It must be noted that we are dealing with weak recom-

mendations, based only on experts’ consensus.

This is expected given the rareness of this disease, that 
foreclose to collect evidences stronger than these provided 
by case series studies.

Moreover, we have to be remember that because of the 
wide spread of vaccination procedures, also physicians not 
expert in thrombo-hemorragic disorders should have to face 
patients with suspected or confirmed VITT. To this end, a 
conceptual framework like this can be very useful to allow 
a more timely and standardized approach to this compelling 
disease.

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Table 2   How to manage VITT

Suspect

Patient presenting symptoms suggestive of atypical venous or arterial thromboembolism, such as:
Cerebral sinus vein thrombosis (CSVT):
 Persistent and severe headache
 Focal neurological symptoms
 Seizures, or blurred or double vision
Pulmonary embolism or acute coronary syndrome:
 Shortness of breath or chest pain
 Splanchnic vein thrombosis
 Abdominal pain
Deep vein thrombosis or acute limb ischemia:
 Limb swelling, redness, pallor, or coldness

And
 A platelet count ≤ 150,000/mmc
 Within 28 days after COVID-19 vaccination

Confirm
 Perform rapid assessment for the presence of thrombosis at sites other than that leading to hospitalization (e.g. by total body angio-computed 
tomography scan). Please note that imaging to rule out CVST includes also vascular imaging, either with a CT head/CT venogram or MR 
head/MR venogram. This potential diagnosis should be investigated urgently with same-day neuroimaging

 Perform hemostatic screening for DIC along with a complete blood count
 Assess anti-PF4 antibodies
 Consult a Hemostasis and Thrombosis Expert

Treat
 Admit the patient to an Intensive Care or High Dependency Unit, to achieve a more intensive observation, treatment and nursing care than that 

provided in a general ward

 If platelet count is < 50,000/mmc, treat thrombocytopenia to allow starting anticoagulant therapy:
 i.v. Ig (1 g/kg/day for 2 days) and dexamethasone (40 mg/day for 4 days)
 Consider platelet transfusion after i.v. Ig in case of life-threatening bleeding
 Consider plasmapheresis or plasma-exchange in most severe cases, unresponsive to the above measures,
Avoid heparin and low-molecular weight heparin unless positivity for anti-PF4 has been ruled out
 Adjust the intensity of anticoagulant treatment according to the platelet count:
Platelet < 20.000/mmc:
Avoid anticoagulation
Platelet 20–50.000/mmc:
 Fondaparinux 2.5/5 mg (bw < / > 50 kg)
 Argatroban (aPTT Ratio 1.5; to be preferred is GFR < 30 ml/min or ICH)
Platelet 50–100.000/mmc:
 Fondaparinux 5/7.5 mg (bw < / > 50 kg)
 Argatroban (aPTT Ratio 1.5–2.5; to be preferred is GFR < 30 ml/min or ICH)
Platelet > 100.000/mmc:
 Fondaparinux 5/7.5/10 mg (bw < 50/50–100/ > 100 kg)
 Argatroban (aPTT Ratio 1.5; to be preferred is GFR < 30 ml/min or ICH)
 Direct Oral anticoagulants are not advised for being off-label for this indication in some countries, for difficult dosage management and prob-

lems of administration in unconscious subjects

 Consider FFP (15–20 ml/kg) if consumption coagulopathy with bleeding and PT or aPTT Ratio > 1.5
 Consider Fibrinogen concentrate (2 g) if the patient is actively bleeding and plasma fibrinogen level is < 1.5 g/L despite FFP administration

bw body weight; aPTT activated Partial Thromboplastin Time; GFR Glomerular Filtration Rate; ICH IntraCranial Hemorrhage; FFP Fresh Fro-
zen Plasma

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Conclusion and future perspectives

This time of pandemic has been a hard one, and an often-
confusing information has certainly contributed to make it 
even harder.

Now, one of the main physicians’ responsibilities is to 
provide patients with a scientifically sound, evidence-based 
and fair counseling to cope in the best way with their ques-
tions and concerns about the issue of vaccination.

The undeniable basis is that the expected benefits of the 
vaccines in preventing COVID-19 and serious complications 
associated with it far outweigh any currently known side 
effects, as very effectively displayed by EMA on its institu-
tional site [24].

Indeed, it should not be forgotten that COVID-19 is very 
serious disease, which per se promotes a hypercoagulable 
state leading to a substantial risk of thromboembolic events 
and death in affected patients [25].

Therefore, physicians must strongly endorse the practice 
of vaccination in all patient, trusting he reliability of Regu-
latory Agencies to assess the safety of any drugs, including 
those very speedily developed, such as the COVID-19 vac-
cines. Indeed, Pharmacovigilance Systems have displayed an 
extraordinary responsiveness in noticing even small signals 
of rare serious events related to COVID-19 vaccines.

Although  EMA’s  safety  committee  (Pharmacovigi-
lance Risk Assessment Committee, PRAC) concluded on 
April14 that a causal relationship between vaccination with 
Vaxzevria and very rare cases of VITT is plausible, several 
questions about this issue still remain unanswered, first of 
all that about the safety of the second dose of Vaxzevria or 
Ad26.COV2. S.

Indeed, an increased risk of VITT with the second dose 
could be possible due to boosting of potential anti-PF4 anti-
bodies that were elicited (subclinical) following the first 
dose.

On the other hand, persons who have not developed this 
complication following the first dose may also be less likely 
to develop it after the second dose, because of the well-
known phenomenon of depletion of susceptibles.

As reported in Table 1, the overall incidence after second 
doses was about 1.3 per million doses. Currently, no cases 
following a second dose have been reported in patients aged 
18–49 years with an estimated 2.7 million in this age group 
having received both doses, although the time for follow-up 
and identification of cases in this cohort is more limited as 
compared to that of subjects having received the first one.

Moreover, a very recent paper reported a very low preva-
lence of 1.2% (95% CI: 0.4–2.2) of antibodies to PF4/poly-
anion complexes among Norwegian health care workers after 
vaccination with the first dose of Vaxzevria (6 positive indi-
viduals among 492 health care workers tested 10–35 days 

post vaccination, all with platelet count > 150,000/mmc;). 
In the same cohort, 8 subjects had reduced platelet counts, 
all above 100,000/mmc. No subjects had severe thrombo-
cytopenia [26].

Although this data sounds quite reassuring, the Regula-
tory Agencies continue a strict monitoring of the vaccine’s 
safety, collecting more information about serious adverse 
events following vaccine administration.

By this huge effort, it will be possible to further improve 
the already excellent safety profile of vaccines, not only by a 
population point of view, but also by a more individualized 
approach, whenever specific risk factors could be reliably 
assessed.

Declarations 

Conflict of interest  The authors declare that they have no conflict of 
interest.

Statement of human and animal rights  Not applicable.

Informed consent  Not applicable.

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