Persistence of IPV Immunity

Poliomyelitis Clinical Trial

Official title:

Cross-sectional Study to Assess Persistence of Immunity Conferred by a Single IPV Dose Administered in the Expanded Program on Immunization(EPI) Routine Immunization Schedule

Clinical Trial Details — Status: Completed

Administrative data

• NCT number: NCT03723837
• Other study ID #: 69/2018
• Status: Completed
• Phase: Phase 4
• Start date: November 21, 2018
• Est. completion date: July 30, 2019

Study information

• Verified date: April 2020
• Source: Tribhuvan University Teaching Hospital, Institute Of Medicine.
• Contact: n/a
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

In 2015, Strategic Advisory Group of Experts in Immunization (SAGE) recommended the global switch from trivalent to bivalent oral poliovirus vaccine (OPV) that does not contain type 2 poliovirus and introduction of a single dose of inactivated poliovirus vaccine (IPV) to maintain population immunity to type 2 polio to reduce the risk of vaccine derived polio. Following SAGE recommendations, Nepal introduced one dose of IPV in routine immunization in 2015 followed by withdrawal trivalent OPV in April 2016. However, Nepal, like many other countries had to stop vaccination by the end of 2016 because of a global shortage of IPV.

Single dose of IPV induces detectable antibodies in 34% to 80% of infants, compared to >90% after three doses and most of seronegative children (84-98%) are "immunologically primed" by the first dose. Primed individuals produce protective antibody levels in serum within one week of exposure to a new dose of IPV or OPV. However, it is unknown whether seroconversion or priming responses persist, and for how long they persist after the single dose of IPV. IPV immunogenicity for vaccine delivered low-resource countries may also be inferior to that observed in clinical trials because of program factors that decrease vaccine efficacy.

This cross sectional study aims to determine whether the immune response provided by a single dose of IPV delivered through routine immunization services persists for more than a year.

The study will be implemented in three study sites in Kathmandu, Nepal during November 2018- July 2019.

Information generated from this study is expected to allow better estimation of children partially protected (primed) or fully protected against type 2 poliovirus depending on coverage and time since last IPV vaccination. These estimates will help inform the Global Polio Eradication Initiative (GPEI) on vaccine choices for responding to type 2 vaccine derived poliovirus (VDPV) outbreaks and will help guide decisions on polio immunization schedules for Nepal and for other countries in future.

Description:

Background and Rationale

Importance of Poliomyelitis and Polioviruses and vaccine

There are three polioviruses types, 1, 2 and 3, with minimal cross-immunity. About 1/200 infections (depending on the type of poliovirus) produce paralytic poliomyelitis. An estimated 5-10% of individuals with paralytic poliomyelitis die and the remaining suffer from lifelong paralysis of one or more limbs without a cure. The presence of detectable antibodies in blood against each type protects against paralytic poliomyelitis, but intestinal immunity develops only after exposure to live poliovirus (vaccine or wild). Oral poliovirus vaccines that contain attenuated poliovirus strains and inactivated poliovirus vaccine both induce humoral immunity and protect against paralysis. OPV can also immunize or boost immunity of close contacts through secondary spread and trivalent OPV (tOPV) with poliovirus types 1, 2 and 3, was the vaccine of choice for polio eradication.

The immunological response to poliovirus vaccines is evaluated by measuring type-specific poliovirus antibodies using neutralization assays and can be detected as early as 1 to 3 days after infection with WPV or receipt of OPV or IPV. Antibody titers usually decline in the first two years (10- to 100-fold reduction) and then plateau, persisting for many years. However, administration of additional doses of vaccine or new exposures to wild poliovirus, induces a quick rise in antibody titers, with a peak reached within one week after the dose due to induction of "priming" or immunological memory.

Changes in polio vaccine use with progress in global polio eradication

Global Polio Eradication Initiative (GPEI) reduced polio cases enormously with the use of the tOPV in routine immunization and campaigns and WPV circulation is now limited to a few areas of the world. However, problems related to vaccines emerged. OPV strains may occasionally cause paralysis in vaccinated children and their close contacts (vaccine-associated paralytic poliomyelitis or VAPP). OPV strains can circulate among susceptible individuals for long time in areas with absence of wild poliovirus transmission and suboptimal coverage with routine immunization resulting in low population immunity. Prolonged person-to-person transmission can result in genetic changes and the emergence of circulating vaccine-derived polioviruses (cVDPV) with neurovirulence and transmissibility characteristics of WPV. Type 2 poliovirus was responsible for about 40% of annual VAPP cases reported, and 85% paralytic cases caused by cVDPVs during 2000-2015. Based on SAGE recommendation this led to removal of type 2 by switching from tOPV to bOPV in primary immunization and introduction of "at least one dose of IPV in routine immunization" in most of the countries of the world.

Rationale for the study and expected outcomes and benefits for the GPEI

Several recent studies have demonstrated that, although a single dose would result in seroconversion to type 2 for a limited number of infants (32% to 80% depending on the age of administration and study), a high proportion (>90%) of those infants who are seronegative, may actually "primed" by that single dose. Although it is not clear whether priming may protect directly against paralysis if a type 2 cVDPV 2 outbreak emerges, primed children should develop protective antibody levels quickly following a new OPV or IPV dose provided as a response to the outbreak.

Studies assessing long-term immunity to IPV or OPV were conducted in individuals receiving three or more doses of poliovirus vaccines who could have been exposed to circulating wild or vaccine poliovirus. It is unknown whether the proportion of children who were seropositive or primed following a single dose of IPV will stay positive or primed, and for how long this immune response will persist. Additionally IPV delivered in clinics and outreach sites in low-resource countries may not produce the same response to those observed in clinical trials due to programmatic issues.

Furthermore, global shortage of IPV resulting in IPV stock out in many countries including Nepal led many children to miss out their IPV dose in routine immunization. Reliable estimates of population immunity in a country or region based upon coverage and estimated immunogenicity of the type of vaccine and vaccination schedules received, are crucial to guide programmatic decisions and manage vaccine supply for outbreak responses to type 2 poliovirus.

Therefore, a cross-sectional study is being conducted to determine whether the immune response provided by a single dose of IPV persists for more than a year, by assessing the proportion of children born after the tOPV-bOPV switch and vaccinated with a single dose of IPV at about 14 weeks in routine immunization who are still seropositive or primed at around two years of age. These new estimates will inform the GPEI on vaccine choices for responding to type 2 VDPV outbreaks and guide decisions on polio immunization schedules after cessation of all OPV types.

Objectives

The study primarily will compare the proportion of infants vaccinated with one dose of IPV after 14 weeks of age who are seropositive or primed against type 2 poliovirus, either > 21 months after vaccination (study group), or one month after vaccination (control group). Also we would determine the proportion of children seropositive to types 1 and 3 following a sequential bOPV-IPV or bOPV alone schedule, delivered through routine immunization services in a low resource country.

Study Design/ Procedures

This is an open-label phase IV clinical trial assessing immunogenicity to IPV. Study participants will be identified through screening of children who attend outpatient clinics at the study sites for well-child visits, immunization or minor illness. After screening, confirmation of eligibility and obtaining consent, children will be allocated to one of the two study arms, and given a dose of IPV after collecting clinical information and obtaining a blood sample. Children will be followed up according to the schedule for study arms to assess study objectives.

Blood sample will be centrifuged within 24 hours of collection, serum aliquoted into two cryovials and stored at Institute of Medicine (IOM) laboratory at -20*C until final shipment to Centers for Disease Control and Prevention(CDC), Atlanta. Determination of poliovirus antibodies will be conducted using a microneutralization testing. Titers below 1:8 will be considered negative and the highest detectable titer will be 1:1448.

Sample size and analytic plan:

The sample size will be powered to address the primary objective based on previous trials that have shown 90 - 100% of children to develop detectable immunity to type 2 poliovirus after IPV dose. Using a one-sided test for differences between proportions with a continuity correction Z-test using pooled variance (PASS v14), 237 children will be required in each group to detect a one-sided difference of ≥10% with 90% power and 0.05 alpha. To account for potential 5% drop-outs, the sample will be rounded up to 250 per group or 500 children total.

Recruitment information / eligibility

• Status: Completed
• Enrollment: 502
• Est. completion date: July 30, 2019
• Est. primary completion date: June 30, 2019
• Accepts healthy volunteers: No
• Gender: All
• Age group: 7 Months to 36 Months

Eligibility

Inclusion Criteria:

We will be including Nepali infants who fulfil the following criteria:

• Born after 30 April 2016

• Healthy infant or mild illness

• Age groups within one of the following age groups: 7-12 months or >24 months.

• Receipt of one dose of IPV at 3- 6 months of age (if age >24months) or zero doses (if age within 7-12 months). IPV receipt must be validated through immunization card or registry book.

• Parents that consent for participation in the full length of the study.

• Parents those are able to understand and comply with planned study procedures.

Exclusion Criteria:

• Parents and infants who are unable to participate in the full length of the study.

• A diagnosis or suspicion of immunodeficiency disorder either in the infant or in an immediate family member.

• A diagnosis or suspicion of bleeding disorder that would contraindicate parenteral administration of IPV or collection of blood by venipuncture.

• Acute infection or illness at the time of enrollment that would require infant's admission to a hospital.

• Evidence of a chronic medical condition identified by a study medical officer during physical exam.

• Known allergy/sensitivity or reaction to polio vaccines.

Discontinuation Criteria

• Withdrawal of consent for participation for any reason.

• Request by parents of participant to terminate all study procedures.

• Identification of immunodeficiency disorder, bleeding disorder or another medical condition for which continued participation, in the opinion of the principal investigator, would pose a risk to the participant to continue in the study.

• Receipt of immunosuppressive medications.

• Receipt of any polio (OPV or IPV) vaccine outside of study after enrollment (as per parent's report).

• Allergic reaction to a dose of polio vaccine.

• Unable to collect or obtain blood at enrollment.

• Premature termination of the study.

• Temporary discontinuation of study activities may occur if there is a mOPV2 campaign.

Related Conditions & MeSH terms

• Poliomyelitis

Intervention

Biological:
• Inactivated Polio Vaccine (IPV)
Children receive one or two doses of IPV based on study arm they fall in

Locations

Country	Name	City	State
Nepal	Kanti Children's Hospital	Kathmandu
Nepal	Patan Hospital	Kathmandu
Nepal	Tribhuvan University Teaching Hospital	Kathmandu

Sponsors (3)

Lead Sponsor	Collaborator
Tribhuvan University Teaching Hospital, Institute Of Medicine.	Centers for Disease Control and Prevention, World Health Organization

Country where clinical trial is conducted

Nepal, 

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* Note: There are 39 references in all — Click here to view all references

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Proportion of children with detectable immunity against type 2 poliovirus	To compare the proportion of infants vaccinated with one dose of IPV after 14 weeks of age who are seropositive or primed against type 2 poliovirus, either > 21 months after vaccination (study group), or one month after vaccination (control group)	5 weeks
Secondary	Proportion of children who seroconvert or boost antibody titers to type 2 poliovirus	To assess the proportion of children who seroconvert or boost antibody titers to type 2 poliovirus 30 days after a second dose of IPV, administered > 1 year after the first dose.	5 weeks

External Links

•   Department of Immunization Vaccines and Biologicals. WHO multi-dose vial policy (MDVP), Revision 2014. WHO/IVB/14.07
•   Global Polio Eradication Initiative. List of wild poliovirus by country and year.
•   Global Polio Eradication Initiative. Standard Operating Procedures: responding to a poliovirus event and outbreak, part 2: protocol for poliovirus type 2, 15 August 2016 (Original publication 20 april 2016)
•   Hickling J, Jones R and Nundy N. Improving the affordability of intactivated poliovirus vaccine (IPV) for use in low-and middle-income countries
•   The Global Polio Eradication Initiative. Data and monitoring
•   UNICEF Supply Division. Inactivated Poliovirus Vaccine Supply Alert