Clinical Vaccine Development PDF

Summary

This document provides an overview of clinical vaccine development, outlining key principles, stages, and considerations. The document covers topics such as clinical trials, safety evaluations, and immunogenicity assessments crucial for vaccine development.

Full Transcript

Clinical vaccine development
Valentino D’Onofrio, PhD
Clinical Research Coordinator CEVAC

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Vaccine Industry
•
•
•

Small part of Pharmaceutical industry
Remarkable growth due to new innovative vaccines
Key principles
o
o
o
o
o

Assessment of disease burden (& cost) and defining target population
Medical need and cost-effectiveness (WHO CHOICE (chosing interventions that are cost-effective)
Funding vaccine programmes (e.g. GAVI, Gates Foundation, …)
Advanced market commitments (AMC)
Recent advances and technology discoveries (e.g. novel adjuvants and delivery systems)

Vaccine Development
•

Vaccine development is a complex and lengthy process

•

Cost estimates of $1 billion

•

Emphasis shift from immunogenicity and efficacy to safety and
economic considerations

o If $1 million is invested annually in R&D, approximately 1 new vaccine
every 6 to 8 years is expected

o Price of 1 dose à Private market or Government?
o But old vaccines remain profitable à new birth cohorts & few
competitors

•

High Failure rate: less than 1 in 15 vaccines achieve licensures:
o
o
o
o

Incomplete understanding biology of protection
Lack of animal models
Unpredictability of human immune response
Unpredictability of combining components

Clincial vaccine trial
•

Research project that evaluates the safety, immunogenicity and/or efficacy of a
new vaccine or improved version of an existing vaccine

•

With the aim of answering the following question(s):
o
o
o
o
o
o

Is the vaccine safe? Which adverse events does it cause, and are these acceptable?
Is the vaccine efficacious?
Which dose of the antigen (and adjuvant) are needed to induce a sufficiently strong immune
response?
How many administrations of the vaccine are needed to induce long-term protection?
What is the ideal time interval between the different doses?
Can the vaccine be safely administered to young adults? And to more vulnerable populations,
such as older adults, children, pregnant women?

•

Is preceded by pre-clinical research

•

Different phases: phase 1, 2, 3, 4

•

Different designs:
o

open, single-blind, double-blind, observator-blind

o

Randomised, controlled (placebo or an alternative, existing vaccine)

5 – 15 years

•

•
•

•
•
•

First in Human
SAFETY
immunogenicity

•
•
•

Dose & Schedule
finding
Safety
immunogenicity

•
•
•

Efficacy
Safety
immunogenicity

Regulatory submission

•

Ag definition
and
purification
Formulation
selection
Immunology
in animal
models
Mechanisms
of action
Toxicology

5 – 15 years

Regulatory submission

•

Phase 4 & Post-market surveillance

Clinical trial phases

Safety

Immunogenicity

Efficacy & effectiveness

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Declaration of Helsinki

ICH/GCP guidelines
International Conference of Harmonisation/
Good Clinical Practice
• Ethical and scientific quality should be considered when
designing, executing, analysing and reporting clinical trials.
• The rights, safety and well-being of the study participants as
well as the credibility of the study results should be guaranteed.
• Careful training of the study team and strict and frequent
controls of compliance is performed by study monitors,
auditors, inspectors.

EU Directive

The Clinical Trials Regulation aims to create an environment that is
favorable for conducting clinical trials, with the highest standards of patient
safety, for all EU Member States.
à Belgian law (07 May 2004) based on EU directive.

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Ethical Review Board

•

•

Based on royal decree of 12 August 1994:
o

minimum 5 members, males and females, min. 1 general practictioner, half of the members
+ 1: physicians, min. 1 nurse, a lawyer and an ethicist. Sufficient expertise is important.

o

More recently: addition of patient representatives

Roles of the ERB:
o

to investigate if the clinical trial does not pose a risk to the subjects, if the investigated
drug/vaccine is safe and if it has been sufficiently tested preclinically.

o

To evaluate the rights of the subjects and if privacy is respected

o

To evaluate if the rationale of the study is sufficiently supported by scientific data

•

Besides the ERB, the study documents also have to be submitted to and approved by the Federal
Agency of Medicines and Health Products (FAMHP; Federaal agentschap voor
geneesmiddelen en gezondheidsproducten, FAGG).

•

A clinical trial can only start once the ERB and FAMHP have given their approval.

•

The principal investigator (PI) is responsible for the ERB submission.

•

The sponsor is responsible for FAMHP submission (PI in case of academic trials).

Ethical Review Board
Previous Procedure:
• In case of a multicenter trial 1 ERB is appointed as ‘central’ (mostly university hospital).
This ERB reviews all documents. The other (‘local’) ERBs only evaluate the ICF.
New procedure:
Implementation of the new Clinical Trials Regulation (EU 536/2014): to simplify and
harmonise the submission and evaluation process of CT application across Europe:
• Submission via EU portal for all member states
• One country-specific and neutral ERB will review all documents
Which documents have to be submitted?
• ERB advice request form (adviesaanvraagformulier, cfr. separate document)
• Study protocol
• Investigator Brochure (IB): contains all available information on the investigational
product (IP), i.e. chemical composition, preclinical data, clinical data so far, …
• Informed Consent Form (ICF)
• Recruitment messages (flyers, posters, …)
• Other written information that is provided to the subject, e.g. diary cards, memory
aids,…

Ethical Review Board

https://www.uzgent.be/nl/overuz/commissie-voor-medische-ethiek/Paginas/documenten-industriegesponsord-onderzoek.aspx

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Rights and duties
•

Participation at a clinical study is always on a voluntary basis
(informed consent).

•

During the entire study period the participant has the right to
withdraw from the study (no reason or explanation is needed).

•

The participant should be present at the study visits on the
appointed moments and correctly inform the study team about
the use of medication, health status, possible adverse events,
(concomitant) participation at other studies, and comply with all
procedures.

•

Non-compliance can lead to exclusion from the study.

Informed Consent

It needs to be specifically mentioned that participants have the right:
•
•
•
•
•
•
•

To know that participation is voluntary
To ask questions and receive understandable answers before making a
decision
To know the degree of risk and burden involved in participation
To know if there are any benefits involved in participation
To withdraw themselves from the project at any time
To know how their data will be collected, protected during the project
and either destroyed or re-used at the end of the research if plans to reuse the data exist.
To know of any potential commercial exploitation of the research

Informed Consent
• Information and consent form always needs to be written in the language
that is best understood by the participant.
• Needs to be signed before the very first study procedure is executed
• The participant needs to be given sufficient time to ask questions and to
consider his/her participation.
• Signature of the participant:
o ≠ signing a contract
o to confirm that participation is voluntary
o to confirm that he/she has well understood all aspects of the study and that all
questions have been answered
o Name, signature, date: have to be hand-written by the participant (not pretyped)

• Signature of the study physician:
o to confirm that he/she has not exerted any pressure on the subject to participate
o to confirm that the participant has been fully informed, and all questions have
been answered.

• The participant needs to sign first, the physician next.
• If needed: witness, parent(s) or guardian

Liability and Insurance
The commissioning company (sponsor), has a no-fault
liability for possible damage inflicted to the participant
during the course of the study. It is of no relevance
whether this damage is connected directly of indirectly to
the participation at the study.
‘No-fault’ means that the participant does not have to
demonstrate a fault of the study physician or the sponsor.
The sponsor has to take out an insurance policy for this
liability.

Privacy protection
Minimal release of personal data to the sponsor
Personally Identifiable Information (PII)
Sensitive PII
• subset of PII whose unauthorised acquisition, use, modification, loss or
disclosure presents a greater risk of harm to the relevant individual.

EU GDPR
• Global Data Protection Regulation, since 25 May 2018
• Aim: to standardize and strengthen the protection of personal
data across the EU
• Changes involve:
o Significant penalties
o Data subject rights
§ Prior consent
§ Transparent plain language
§ Breach notification
§ Right to access, right of correction, restriction, right to
object
§ Right to be forgotten ßà clinical trials regulation
§ Data portability
o Privacy by design
o Data impact assessments
o New data protection officers (DPO)

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Study Protocol
• Describes:
o
o
o
o
o
o
o
o

Rationale (Diseases & Vaccine)
Objectives & endpoints
Study Design
Study population
Investigational Product
Procedures
Statistical Methods & cohorts of analysis
Administrative matters (record retention, quality assurance, posting of
information on publicly available clinical trial registers and publication
policy (clinicaltrials.gov)

• ‘Manual’ for the conduct of the study
• All members of the study team are trained by the sponsor,
generally during the site initiation visit (SIV).

Study Design

• Open, single-blind, double-blind, observator-blind
• Randomised, controlled (placebo or an alternative, existing vaccine)

Objectives & Endpoints
Research objectives describe what we expect to achieve by a project.
Endpoint is the quantitative measurements required by the objectives.
• Refers to the analyzed parameters
• the endpoint for which subjects are randomized and for which the trial
is powered.
• "Hard" endpoints are well-defined in the study protocol, definitive with
respect to the disease process, and require no subjectivity.
• "Soft" endpoints are those that do not relate strongly to the disease
process or require subjective assessments by investigators and/or
patients.
Outcome is a final product or end result; consequence; issue.
• Refers to the measured variable
Patient outcome is the condition of a patient at the end of
therapy/intervention or a disease process, including the degree of
wellness and the need for continuing care, medication, support,
counseling, or education.

Study Populations
Power calculations and sample size:
• How many patients do we need to include in the trial to answer the research
question (null hypothesis)?
• Null hypothesis: patients with intervention are the same as those without
• Alternative hypothesis: patients with interventions are not the same as those
without
à Type 1 (false-positives, reject H0 when true) and type 2 (false-negatives, accept
H0 when false)
à Power calculations determine how many patients we need to avoid these
errors
Inclusion and exclusion criteria
• Strictly define the study population
• Who can participate and who cannot?
• What clinical comorbidities are allowed to be considered ‘healthy’?
• What medications are allowed?
Subject completion and withdrawal
• Screening failure
• Subject withdrawal from the study/from the IP at any time

5 – 15 years

•

•
•

•
•
•

First in Human
SAFETY
immunogenicity

•
•
•

Dose & Schedule
finding
Safety
immunogenicity

•
•
•

Efficacy
Safety
immunogenicity

Regulatory submission

•

Ag definition
and
purification
Formulation
selection
Immunology
in animal
models
Mechanisms
of action
Toxicology

5 – 15 years

Regulatory submission

•

Phase 4 & Post-market surveillance

Clinical trial phases

Immunogenicity
Carefully defined!
• Disease specific
• Immune respons?
Study specific!

Immunogenicity
Carefully defined!
• Immune respons & Type of vaccine (antigen, conjugated…)?

Immunogenicity
Example: J&J COVID-19
Mechanism:
• COVID-19 S-protein = antigen
• Packed in adenoviral vector: Viral vector allows mimicking intracellular
infection

Phase 3 design - Efficacy
Phase 3 trial = Efficacy study
Gold standard = randomized, placebo-controlled, double blind study
•
•
•
•
•
•
•

Experimental study (<-> observational study)
Formulate the study objective and hypothesis
Calculate the sample size < specified parameters and effect size
Select a representative target population
Execute the study
Analyse results (PP and ITT) to define vaccine efficacy
Ethical aspects, including GCP
PP = Per Protocol / ITT = Intention To Treat

Phase 3 design - Efficacy
Formulate Null Hypothesis
= Study vaccine will NOT provide better protective efficacy as compared to
placebo (or active control)

𝛂 is generally set at 0,05 (5%)

power (1-𝛃) is generally
set at 80-90%, so a type II
error of 0.1

Phase 3 design - Efficacy
Specify parameter
Prespecified, before study start
• Significance level 𝛂 : 0,05 (5%)
•

Power 1-𝛃 : 0,8 or 0,9 (80% or 90%)

Unknown parameters (uncertainty)
• Standard deviation, intracluster correlation, …
• < previous studies, pre-existing data, academic literature

Phase 3 design - Efficacy
Determine the effect size
= The difference in the primary outcome measure used in the sample size
calculation that the clinical trial is designed to reliably detect
Why is this so important?
• Calculated difference < real difference: sample size is too large, ethical
problem
• Calculated difference > real difference: study is underpowered
How is the effect size estimated?
• Select a clinically relevant difference
• Select a realistic difference based on prior evidence and information
• Preferably a combination of both
Vaccine impact compared to control depends on
• Attack rate of infectious disease
• Estimated vaccine efficacy

Phase 3 design - Efficacy
Define the primary outcome measure – CASE DEFINITION
Infection:
Clinical symptoms
+ Laboratory confirmation:
• Pathogen detection (culture, PCR, …)
• Detection of the pathogen-specific humoral (or cellular) immune
response, e.g. seroconversion
Severe infection:
Clinical symptoms, complications, hospitalisation
+ Laboratory confirmation
Death:
All-cause mortality or death causally related to the infection (without any
other attributable cause)
+/- laboratory confirmation

Phase 3 design - Efficacy
Compute sample size
Formula used will depend on the study design:
Superiority, equivalence or non-inferiority trial
Sample size: 90 subjects per group
or 180 subjects in total (2 arms)

Phase 3 design - Efficacy
Compute sample size
Adjust the sample size to compensate for drop outs
Example:
Estimate of 10% drop outs (p = 0,1)
Adjusted sample size = original sample size
1–p
= 180
0,9
= 200
https://www.statsols.com/how-to-use-a-sample-size-calculator

Phase 3 design - Efficacy
Example - HERALD

Phase 3 design - Efficacy
Example - CMVictory

Phase 3 design - Efficacy
Example - CMVictory

Phase 3 design - Efficacy
What if
The effect size is very small (m1-m2)
E.g. new vaccine is only slightly more effective than the active control
vaccine
The event studied is very rare
E.g. meningococcal infection (1/100 000)
If the development of the event takes a long time
E.g. cervical cancer

Phase 3 design - Efficacy
Select representative study population
•
•
•
•
•

External validity
Age
Gender
Socio-economic status
General population or specific groups with increased infection risk

Phase 3 design - Efficacy
Results analysis
Per protocol
Only those who completed vaccination according to the protocol
Intention to treat
All participants who have been randomized and received at least 1 dose
of the vaccine
Why are both analyses important?

Phase 3 design - Efficacy
Efficacy and relative risk

Phase 3 design - Efficacy
Example – AS03 adjuvanted TIV vs TIV

Phase 3 design - Efficacy
Example – AS03 adjuvanted TIV vs TIV

Phase 3 design - Efficacy
Ethical aspects
• GCP
• Maximizing individual benefits and avoiding harm/minimizing risk
• Protection of the study participants,
e.g. avoid risky behaviour or non-compliance with recommended preventive
measures.
• SARS-CoV-2 vaccine trial
• HIV vaccine trial
• Malaria vaccine trial

Phase 4 design – Post Marketing
Post Marketing studies
•
•
•
•
•
•

In vitro studies
RCTs
Observational studies for safety and effectiveness
Impact on outcome (burden of illness)
Pharmacoeconomic studies
Investigator-initiated research in practice (e.g. in other patient groups)

Phase 4 design – Post Marketing
Observational studies
•
•
•

To study vaccine effectiveness in real world setting
(ßà vaccine efficacy in ideal setting of a phase 3 study)
Retrospective or prospective
Different study designs

E.g. Observational studies on COVID-19 vaccination (WHO list):
https://www.who.int/publications/m/item/draft-landscape-ofobservational- study-designs-on-the-effectiveness-of-covid-19-vaccination

Phase 4 design – Post Marketing

Phase 4 design – Post Marketing
Case control vs. Cohort

Phase 4 design – Post Marketing
Test-negative case control study

Phase 4 design – Post Marketing
Impact studies
In case of a very rare event and when vaccination coverage rate (VCR) is
high, e.g. MenB vaccination in UK (90% VCR), incidence MenB invasive
disease of 0,6/100 000/year, birth cohort of appx. 600 000 live births year in
UK

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Study Protocol
• Describes:
o
o
o
o
o
o
o
o

Rationale (Diseases & Vaccine)
Objectives & endpoints
Study Design
Study population
Investigational Product
Procedures
Statistical Methods & cohorts of analysis
Administrative matters (record retention, quality assurance, posting of
information on publicly available clinical trial registers and publication
policy (clinicaltrials.gov)

• ‘Manual’ for the conduct of the study
• All members of the study team are trained by the sponsor,
generally during the site initiation visit (SIV).

Study Procedures
Conduct of the study
o Regulatory and ethical considerations, including the informed
consent process
o Subject identification and randomisation of treatment
o Method of blinding
o Outline of study procedures
o Informed consent process
o Detailed description of study procedures:
§ ICF
§ Check Inclusion and exclusion criteria, ….

o Biological sample handling and analysis
§ Biological samples
§ Laboratory assays: Immunological read-outs and
haematology/biochemistry

Study Procedures
Study vaccines and administration
o
o
o
o
o
o

Description of study vaccines
Storage and handling
Dosage and administration (reconstitution instruction)
Contraindications to subsequent vaccination
Concomitant medication and vaccines
Intercurrent medical conditions that may lead to elimination of a
subject to ATP analyses

Safety

o Solicited local and systemic/general AEs
o Serious adverse events (SAE)
o AE of specific interest (ex. pIMD - potential immune-mediated
disorders)
o Pregnancy reporting
o (Emergency) unblinding
o Stopping rules and safety monitoring

Study Procedures

Visit 1: Day 0 – Randomization & 1st vaccination
Type of contact
Time points
Check inclusion/exclusion criteria
Medical history
Physical examination
Urine pregnancy test (a)
Check contraindications
Pre-vaccination body temperature
Treatment number allocation(b)
Blood sampling for safety assessment
(~5.5 mL)
Blood sampling for antibody
determination
and assay development (~20 mL)
Blood sampling for CMI response
(~20 mL)(c)
Vaccine administration
Distribution of Diary Cards(d)
Recording of AEs
Recording of SAEs
Recording of pIMDs
Recording of pregnancies
Record concomitant
medication/vaccination(h)
Record intercurrent medical conditions
requiring medical attention

Visit 1
Day 0
O
●
O
●
O
●
●
●

(a) A urine
pregnancy test will
be performed only
for women of
childbearing
potential.

●
●
●
O
●
●
●
●
●
●

(b)Treatment
number allocation
with randomization

Study Procedures

Study Procedures
Intervals between Study Visits
Interval
Screening
(Pre-Day 0)
Visit 1 (Day 0)
Visit 1 (Day 0)
Visit 1 (Day 0)
Visit 4 (Day 60)
Visit 4 (Day 60)
Visit 1 (Day 0)

® Visit 1 (Day 0)

Optimal
Allowed
length of
interval
interval (a)
5 days 1 – 28 days (b)

®
®
®
®
®
®

7 days
30 days
60 days
7 days
30 days
210 days

Visit 1 (Day 0)

® Visit 8 (Day 420)

Visit 2 (Day 7)
Visit 3 (Day 30)
Visit 4 (Day 60)
Visit 5 (Day 67)
Visit 6 (Day 90)
Visit 7 (Day 210)

7 - 9 days
30 - 40 days
60 - 70 days
7 - 9 days
30 - 40 days
210 - 230
days
420 days 420 - 440
days

Visits out of range can lead to elimination from ATP analyses.

(a) Whenever

possible the
investigator should arrange
study visits within this interval.

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

5. Study Design
6. Study Procedures

A. Reporting adverse events post-vaccination and safety
monitoring
B. Blood samples: safety and immunogenicity evaluation

7. Vaccines and vaccine management

Safety monitoring
eDiary:

Electronic (or paper)

• Who completes it?

o the subject only
o Corrections only possible after discussion with participant

• Who reviews it?

o Investigator or delegate together with the subject
o Except: relationship with IP* can only be assessed by a
physician

• Who signs it?

– The investigator/delegate who has reviewed the DiCa must
sign and date after review of its content with the subject

*IP: investigational product

Safety monitoring

Solicited Local Adverse Events
Solicited adverse events: AE that is expected to occur after vaccination and is
asked about in the daily diary
Reporting time:
•

Mostly 7 days after vaccination. Live-attenuated sometimes 14 days

Symptoms at injection site = Local AE:
•
•
•
•

Pain
Redness
Swelling
Induration

Grading:
•

Based on measurements in mm

Solicited General Adverse Events
Solicited adverse events: AE that is expected to occur after vaccination and is
asked about in the daily diary
Reporting time:
•

Mostly 7 days after vaccination. Live-attenuated sometimes 14 days

Systemic symptoms = General AE:
•
•
•
•
•

Fatigue
Headache
Myalgia/ Arthralgia
Malaise
Fever (Daily T° measurements)

Grading:
•
•
•
•

Mild: easily tolerable
Moderate: tolerable, slight disruption of activities, no medical attention
Severe: hardly tolerable, total absence of daily activities, may require medical attention
Life-threathening

Other Adverse Events
Unsolicited adverse events: all possible adverse events or changes in the
participant’s health condition in addition to the solicited (expected) local and general
adverse events.
•

Medically Attended AE in case of medical assistance needed for AE

•

Reporting time: 28 days after vaccination

Serious Adverse Event is any is undesirable medical event that:
– necessitates hospitalization (or extension thereof)
– causes persistent or serious disability or makes a person unfit to work
– is life threatening
– causes death
– is a congenital malformation

• Reporting time: until end of study
– May require follow-up after study end if no other possible cause than vaccine

Other Adverse Events
AE of Special Interest:
•

pIMD: Potential Immune Mediated Disease:
o A series of adverse events such as auto-immune diseases and other
inflammatory or neurological diseases that are not auto-immune strictu
sensu, e.g. psoriasis, Crohn’s disease, Multiple Sclerosis, ..

•

Vaccine Enhanced Diseases:
o RSV vaccination in 1967: Natural RSV disease was more severe after
vaccination

•

Other specific to vaccine:
o E.g.: Thrombosis with thrombocytopenia syndrome Vaxzevria & J&J
COVID-19 vaccine

•

Reporting time: until end of study

AE relation to vaccine
Investigators must always assess causality of any AE to the received
vaccination.
Related to study vaccine?
•

There is a reasonable possibility that the vaccine caused the AE.
o Reasonable possibility means there is evidence to suggest a causal relationship
between the drug and adverse event.

Suspected adverse reaction means any adverse event for which
there is a reasonable possibility that the drug caused the adverse
event.
Suspected adverse reaction is considered “unexpected” if it is not
listed in the investigator brochure or is not listed at the specificity or
severity that has been observed.

Safety monitoring
‘Stopping rules’
on the basis of the number of adverse events of a certain (defined)
severity it can be decided to stop the study at once, either
definitively or temporarily.
Goal of the study
for example: evaluation of different vaccine doses e.g. Staggered
design (from low dose to high dose)
Data Safety Monitoring Board (DSMB) or Safety Review
Committee (SRC)

Meetings to evaluate safety data at a certain moment (early in the study).
Decides whether the study can be continued or whether the dose can be
increased.

Staggered design & Sentinel

Mainly in first-in-human trials

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Blood sampling
VISITS: V1 / V4 / V7 / V8

Biochemistry
COLLECT:

PREPARE:

RETURN:

Humoral Immunity

Haematology

Blood sampling
Day of sampling needs to be carefully defined:
•

Dependent on immune response
o Naïve/ non-naïve subjects?
o Humoral immunity?
o Cell-mediated immunity?
o Innate responses?

Overview
1.
2.
3.
4.

What is a clinical vaccine trial?
Regulation
Ethical review board (ERB)
Study participants

A.
B.
C.
D.

Rights and duties
Informed consent
Liability and insurance
Protection of privacy and personal data of the participant

A.

Reporting adverse events post-vaccination and safety
monitoring
Blood samples: safety and immunogenicity evaluation

5. Study Design
6. Study Procedures
B.

7. Vaccines and vaccine management

Vaccine Management
Study vaccines are not commercially available
•

Frequently, a series of preparative steps are required , e.g. mixing of
the antigen (liquid or freeze-dried) with a solvent or an adjuvant

•

Strict control of transportation and conservation conditions

•

Precise registration: who receives which vaccine (keep correct records)
+ control of empty boxes or vials following administration
o Difficulties of blinding studies: unblinded researchers necessary

•

Labelling: needs to be done in the three languages (in Belgium), unless
the authorities give an exemption

•

Controlled destruction of remaining vaccines
o Study vaccines cannot be used for other purposes

GMO & Vaccines
• GMO = Genetically modified organism
o “Organism of which the genetic material has been altered in such a way
that does not occur naturally by reproduction or recombination
processes”

• Examples:
o J&J COVID-19 vaccine & Vaxzevria (AstraZeneca)
§ Adenoviral vector without natural Adenoviral DNA
§ Insert COVID-19 Spike protein DNA (reverse transcribed COVID-19
Spike protein RNA)
§ New organism with altered genetic material –> GMO
o Comirnaty (Pfizer) & Spikevax (Moderna)
§ mRNA of COVID-19 Spike protein
§ No vector, no ‘organism’ à Not a GMO

GMO & Vaccines
• Use in humans: Deliberate Release or Contained Use
• Deliberate release:

o any intentional introduction into the environment of a GMO or a
combination of GMOs for which no specific containment measures are
used to limit their contact with the general population and the environment
o Not possible without first obtaining an authorisation from the competent
authority.
o case-by-case assessment of the risks to human health and the environment
associated with the use of the GMO
o Example: J&J COVID-19 vaccine trial: no measures to stop spread to
environment

• Contained use:

o Activities involving GMOs in a "closed environment" such as laboratories,
animal units, greenhouses and production units
o Example: Poliopolis University of Antwerp, New RSV vaccine candidate in
CEVAC: additional measures include tracing of GMO in saliva, stool,
semen,….

Cold Chain Management
Storage at the investigation site
• Vaccines must be stored in a refrigerator approved by
the sponsor between 2-8°C for the duration of the
study
o All refrigerators have been assessed and can be used for storage

• Temperatures must be monitored using a device
validated by the sponsor

o All sites will work with a built-in TMD*. Vaccines should be placed as close as
possible to this TMD at all times.

• All temperature deviations must be immediately
reported to the sponsor

o electronic Temperature Deviation Form (eDTF) completed and followed-up by
unblinded staff

Vaccine Accountability
One accountability log per step is available
Customized with applicable product, lot number and expiry date

Vaccine Labelling
Open secondary labels – Example:

Study reference

Vaccine description,
lot, exp date

Reconstitution
instruction

Route/site/side

Storage
conditions

Treatment number

Key Notes
Clinical (vaccine) trials are highly regulated
• ERB, Governments
• Closely monitored by several instances, sponsor,DSMB,…
• Patient safety and welbeing is as important as scientific
purpose
Define objectives & endpoints carefully
• Protocol = manual
• Study outcomes and procedures relevant to these
endpoints only