Parasite Clearance and Protection From Infection (PCPI) in Cameroon

Malaria Clinical Trial

Official title:

Effect of Single-course Malaria Chemoprevention on Clearance of and Protection From Plasmodium Falciparum Infection in the Presence of Resistance-associated Genotypes in Cameroon

Clinical Trial Details — Status: Recruiting

Administrative data

• NCT number: NCT06173206
• Other study ID #: 2022-KEP-814
• Status: Recruiting
• Phase: Phase 3
• Start date: June 10, 2024
• Est. completion date: March 15, 2025

Study information

• Verified date: June 2024
• Source: London School of Hygiene and Tropical Medicine
• Contact: Innocent Ali, BSc,MSc,PhD
• Phone: +237 659342276
• Email: dr.alinn[@]gmail.com
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

The Cameroon PCPI study will measure the effect of the parasite genotypes associated with SP resistance on parasite clearance and protection from infection when exposed to SP. The total number of participants is expected to be 900 healthy between 3 to 5 years old who have no symptoms of malaria infection of which 450 children will be assigned to the SP group, 250 to the SPAQ group, and 200 to the AS group. The results of this study will allow to measure the effect of the parasite genotypes associated with SP resistance on parasite clearance and protection from infection when exposed to SP.

Description:

The World Health Organization (WHO) recently published new malaria chemoprevention guidelines that included a recommendation for the provision of perennial malaria chemoprevention (PMC) with sulfadoxine-pyrimethamine (SP) to children resident in areas of high malaria transmission. PMC is the successor to an intervention originally known to as intermittent preventive treatment of malaria in infants (IPTi) that involved SP dosing of children at 2, 3 and 9 months of age during vaccination visits of the Essential Programme on Immunization (EPI) that coincide with the 2nd and 3rd doses of the DPT/Penta and measles vaccines. Under the new PMC guidelines, countries are now encouraged to increase the number and frequency of SP doses, and to extend the target age beyond the first year of life.1 Evidence supporting PMC comes in part from meta-analysis2 of six randomised placebo-controlled trials3-8 that demonstrated the protective effect of SP against clinical malaria, anaemia, hospital admissions due to malaria infection, and all-cause hospital admissions. Biomarkers of SP resistance, however, vary in different malaria-endemic settings and have been shown to compromise its protective effect.

In East and Southern Africa, Plasmodium falciparum parasites carry a high frequency of mutations in the Pfdhfr and Pfdhps genes with differing degrees of effect. In Mozambique, for example, SP was protective against malaria infection despite the Pfdhps A437G plus K540E double mutation circulating in over one-half, 52.3%, of P. falciparum (Pf) parasites. 5,9,10 In contrast, SP showed no protective effect in an IPTi trial in Northeastern Tanzania11 where 94.3% of Pf parasites had Pfdhps K540E. However, in this trial, the Pfdhps A581G mutation was also present in 55.0% of Pf parasites, forming the haplotype ISGEGA at codons 431, 436, 437, 540, 581 and 613.12 Thus, Pf appears to be highly resistant to SP where the A581G mutation is concurrently expressed with K540E. Fortunately, for PMC with SP there are few locations in East Africa where the combination of K540E and A581G circulate; most areas across Central, East and Southern Africa have parasites that contain the K540E without the A581G mutation (Pfdhps haplotype ISGEAA). The prevalence threshold of the ISGEAA haplotype at which SP is no longer protective is unknown. Indeed, there may not be an upper limit, although empirical studies are needed to confirm this.

In West Africa, specifically the Sahel region, there are emerging parasite genotypes that harbour a distinct haplotype of Pfdhps, VAGKGS,13,14 which lacks the K540E. These observations have come from molecular monitoring conducted alongside the delivery of intermittent preventive treatment of malaria in pregnancy (IPTp) with SP, and seasonal malaria chemoprevention (SMC) that targets children under 5 years of age with a combination of SP plus amodiaquine (AQ). The VAGKGS haplotype, and the related VAGKAS and VAGKAA, have been reported in 2-40% of Pf parasites in Cameroon, Chad, Niger and Nigeria. The current distribution of parasites harbouring these genotypes is only partially described, and the effect these mutations have on parasite susceptibility to SP remains unknown. Nevertheless, it is possible that parasites harbouring Pfdhps-VAGKGS pose a threat to the effectiveness of PMC with SP or other SP-containing chemoprevention strategies in some parts of the West African Sahel. Thus, there are two clear evidence gaps, one in East/Southern Africa and another in West Africa, which the PCPI (parasite clearance and protection from infection) protocol has been developed to fill. This particular version of the PCPI protocol has been written for use in Cameroon. Another PCPI protocol has been submitted for Zambia with different sample sizes, but with the same approach.

Our aim with the PCPI studies is to evaluate a single-dose of malaria chemoprevention where genotypes (Pfdhps haplotypes ISGEAA and VAGKGS) are associated with SP resistance among healthy and symptom-free children between 3-5 years of age with unknown parasite status. In Cameroon, our objective is to measure parasite clearance and protection from infection conferred by malaria chemoprevention over a 63-day period in the presence/absence of the Pfdhps I431V mutation.

The new WHO chemoprevention guidelines remove the upper age limit of 12 months so that countries may evaluate PMC among a broader range of ages. We selected an age range for eligibility from 3 years and 0 days to 4 years and 364 days with the rationale being that 3-4 years old are more likely to tolerate PMC dosing better than children 0-2 years old. They are also more likely to have some modest level of semi-immunity and, therefore, are less likely to develop a clinical episode of malaria during the follow-up period relative to children who are 0-2 years of age.

After screening for eligibility, asymptomatic children based on a clinical examination and temperature reading will be randomised into one of four treatment groups on Day minus 7 (see Box 1). Children randomised to Groups 1-2 will receive placebo artesunate monotherapy for seven consecutive days. On Day 0, children in Groups 1-2 will then be given antimalarial chemoprevention therapy. In contrast, children randomised into Group 3 will receive active artesunate monotherapy for seven consecutive days and SP placebo on Day 0. Group 3 will establish one sub-set of children who are parasite-free at Day 0, and allow for an accurate estimate of background incidence (reflecting transmission intensity) to which all groups will be exposed during follow up. In addition, this group allows a more accurate estimation of underlying frequency of Pfdhps 431V mutations in the parasite population. Part of the rationale, as well, is to look at parasite clearance among those who were qPCR-positive at Day 0 and time to incident infection among qPCR-negative at Day 0. This will inform parameters of models we will use in data analysis. All children in Groups 1-3 will be followed 70 days total, 63 days (9-week period total) following treatment.

Box 1: Summary of treatments and children per group Group Treatment No. Children

1. sulfadoxine-pyrimethamine (SP)1 450

2. sulfadoxine-pyrimethamine plus amodiaquine (SPAQ)1 250

3. artesunate monotherapy (AS)2 200

Sample collection will be conducted at scheduled visits on Days 0, 2, 5, 7, 14, 21, and 28 visits as children provide a pin-prick of blood for a film slide and a dried blood-spot (DBS) on filter paper. On Days 35, 42, 49, 56, and 63 visits, only DBS will be collected. A study physician will be available 24 hours a day for unscheduled visits to review study subjects who develop symptoms.

All children will be screened for malaria symptoms, including a temperature check, at all contacts - scheduled visits and unscheduled visits - during their involvement in the study. All symptomatic children will have a malaria rapid diagnostic test (RDT) administered and a blood film taken. If a child is RDT-positive at any scheduled or unscheduled visit, the RDT will be stored for future genotyping rather than collecting a separate DBS. In all instances of a positive RDT, children will receive a full course of first-line therapy, artemether-lumefantrine (AL). Children who have an RDT diagnosis will no longer contribute to any future endpoints of the trial, but they will be asked to continue with symptom screening for the full follow-up period to Day 63 and, if symptomatic, they will be tested by RDT and again treated with first-line therapy if found positive and at least 28 days have elapsed since their previous AL-treated febrile episode. Where a child has a second febrile episode within 28 days with RDT-confirmed recurrent parasitaemia, the second-line treatment in Cameroon, artesunate-pyronaridine, will be administered. This ensures quality care is equitable for all participants, regardless of treatment group allocation.

The duration of follow-up in the PCPI protocol was carefully considered. Most study designs of malaria treatment efficacy have a primary endpoint of parasitaemia (present/absent) measured by slide microscopy at Day 28 (4 weeks) with PCR correction, an approach also outlined in the new WHO chemoprevention efficacy study (CPES) protocol.15 This study is consistent with procedures for the PCPI protocol. Consequently, data derived from PCPI studies will be comparable with data from other studies, including those conducted using the CPES protocol. The CPES protocol defines chemoprevention efficacy as both the ability to clear existing parasites and prevent a new infection for a short period (of 28 days). However, PCPI studies will separate resistance effects on these two outcomes of clearance and protection and extend the follow up period to Day 63 (9 weeks). This allows for better quantification of the protective efficacy against new infections by genotype, particularly when the mean duration of protection against more sensitive strains is higher or close to 28 days. Additionally, the choice of a 63-day follow-up simulates what might be the protective efficacy in a scenario where chemoprevention is administered to children every two months. This will be increasingly important for comparison purposes through meta-analysis as longer-acting interventions, including introduction of monoclonal therapies and malaria vaccines.

Recruitment information / eligibility

• Status: Recruiting
• Enrollment: 900
• Est. completion date: March 15, 2025
• Est. primary completion date: December 15, 2024
• Accepts healthy volunteers: Accepts Healthy Volunteers
• Gender: All
• Age group: 3 Years to 5 Years

Eligibility

Inclusion Criteria:

• Be 3-5 years old

• Exhibit no symptoms of malaria

• Have parents/guardians willing to have their child participate in all follow-up visits and seek care from study staff

• Reside in the study catchment area

Exclusion Criteria:

• Have evidence of acute illness as determined by clinical examination

• Exhibit symptoms of malaria (axillary fever = 37.5 °C and / or history of fever in past 48 hours)

• Have known allergy to study medications

• Have received antimalarial treatment or azithromycin within 28 days prior to screening

• Be concomitantly receiving co-trimoxazole (trimethoprim-sulfamethoxazole)

• Be categorised as severely malnourished according to WHO child growth standards

Related Conditions & MeSH terms

• Malaria

Intervention

Drug:
• SP (Macleods Pharmaceuticals Ltd)
Children who weigh <10kg will receive Sulfadoxine-pyrimethamine paediatric formulation (250mg/12.5mg) dispersable tablets; children who weigh >10kg will receive 500mg sulfadoxine plus 25mg pyrimethamine
• SPAQ (Guilin Pharmaceuticals)
Children will receive 500mg sulfadoxine plus 25mg pyrimethamine as one tablet, and 153mg amodiaquine (as hydrochloride) as one tablet on Day 0, and Children will 153mg amodiaquine (as hydrochloride) as one tablet on days 1 and 2.
• AS (Guilin Pharmaceuticals)
Children will receive 4 mg/kg/day for 7 days

Locations

Country	Name	City	State
Cameroon	Malantouen District Hospital Catchment Area	Magba

Sponsors (1)

Lead Sponsor	Collaborator
London School of Hygiene and Tropical Medicine

Country where clinical trial is conducted

Cameroon, 

References & Publications (30)

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* Note: There are 30 references in all — Click here to view all references

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Parasite clearance	Time to clearance of parasite genotypes among SP recipients who were positive on Day 0 by qPCR (presence/absence of Pfdhps I431V) and measured to Day 63	28 days (total follow up 63 days post SP dose)
Primary	Protection from infection	(a) Mean duration of SP protection against parasite genotypes determined by Pfdhps gene sequence presence/absence of Pfdhps K540E among SP recipients who were parasite-free on Day 0 by qPCR (b) Mean duration of symptom-free status among SP recipients who were parasite free on Day 0 by qPCR, stratified by parasite Pfdhps genotype at time of febrile malaria episode	28 days (total follow up 63 days post SP dose)
Secondary	Parasite clearance	Time to clearance of parasite genotypes among SPAQ recipients positive at Day 0 by qPCR (presence/absence of Pfdhps I431V) and measured to Day 63	7 days (day 0 until day 7)
Secondary	Protection from infection	(a) Mean duration of SPAQ protection by qPCR (b) Mean duration of symptom-free status among SPAQ recipients	35 days (day 0 until day 38)
Secondary	Therapeutic efficacy outcomes	For SP: (a)Acute clinical and parasitological response (ACPR) at Day 28 by presence/absence of Pfdhps I431V (b) ACPR at Day 28 by presence/absence of Pfdhps I431V + Pfdhps A581G For SPAQ: ACPR at Day 28	28 days (day 0 until day 28)