Regulatory approval of clinical trials: is it time to reinvent the wheel?

Less than 1% of all clinical trials are conducted in Africa. In 2019, only six of 26 oncology clinical trials conducted in Africa were conducted in countries with subjects of African ancestry. There are multiple barriers that hinder the conduct of cancer clinical trials in Africa. Time to trial activation (TTA) is the administrative and regulatory process required before a study can be activated—an important metric and often a major barrier for site selection. In Kenya, TTA involves review by Institutional Review Board (IRB), Pharmacy and Poisons Board, National Commission for Science, Technology and Innovation and Ministry of Health, all in a sequential fashion. We performed a prospective review of TTA for all clinical trials initiated and began enrolment at the Aga Khan University-Clinical Research Unit between June 2020 and November 2022. TTA was defined as total time from submission of study documents (to regulatory bodies) to site activation by the sponsor. A total of 12 studies were submitted for regulatory review. Eleven (nine industry sponsored and two investigator initiated) were approved for activation. Three were COVID-19-related studies and eight were non-COVID-19-related studies. Mean TTA for COVID-related studies was 80 days (range 40–120). Mean TTA for non-COVID-related studies was 259 days (range 190–399). This TTA difference was statistically significant (p=0.02). TTA remains a significant barrier to the efficient regulatory approval of and subsequent conduct of clinical trials in Africa. COVID-19 pandemic revealed that parallel processing and expedited review of clinical trials allows efficient TTA without compromising human subject safety or data integrity. These lessons need to be applied to all clinical trials in order for African sites to become competitive and contribute data from African patients to global knowledge

A pilot phase Ib/II study of whole-lung low dose radiation therapy (LDRT) for the treatment of severe COVID-19 pneumonia: First experience from Africa

Background: Low dose radiation therapy (LDRT) has been used for non-malignant conditions since early 1900s based on the ability of single fractions between 50–150 cGy to inhibit cellular proliferation. Given scarcity of resources, poor access to vaccines and medical therapies within low and middle income countries, there is an urgent need to identify other cost-effective alternatives in management of COVID-19 pneumonia. We conducted a pilot phase Ib/II investigator-initiated clinical trial to assess the safety, feasibility, and toxicity of LDRT in patients with severe COVID-19 pneumonia at the Aga Khan University Hospital in Nairobi, Kenya. Additionally, we also assessed clinical benefit in terms of improvement in oxygenation at day 3 following LDRT and the ability to avoid mechanical ventilation at day 7 post LDRT. Methods: Patients with both polymerase chain reaction (PCR) and high-resolution computer tomogram (HRCT) confirmed severe COVID-19 pneumonia, not improving on conventional therapy including Dexamethasone and with increasing oxygen requirement were enrolled in the study. Patients on mechanical ventilation were excluded. Eligible patients received a single 100cGy fraction to the whole lung. In the absence of any dose limiting toxicity the study proposed to treat a total of 10 patients. The primary endpoints were to assess the safety/feasibility, and toxicity within the first 24 hours post LDRT. The secondary endpoints were to assess efficacy of LDRT at Day 3, 7, 14 and 28 post LDRT. Results: Ten patients were treated with LDRT. All (100%) of patients were able to complete LDRT without treatment related SAE within the first 24 hours post treatment. None of the patients treated with LDRT experienced any acute toxicity as defined by change in clinical and respiratory status at 24hr following LDRT. Majority (90%) of patients avoided mechanical ventilation within 7 days of LDRT. Four patients (40%) demonstrated at least 25% improvement in oxygen requirements within 3 days. Six patients (60%) were discharged and remained off oxygen, whereas four progressed and died (1 due to sepsis and 3 in cytokine storm). Median time to discharge (n = 6) was 16.5 days and median time to death (n = 4) was 11.0 days. Patients who ultimately died showed elevated inflammatory markers including Ferritin, CRP and D-dimers as compared to those who were discharged alive. Conclusion: LDRT was feasible, safe and shows promise in the management of severe COVID-19 pneumonia including in patients progressing on conventional systemic treatment. Additional phase II trials are warranted to identify patients most likely to benefit from LDRT

Regulatory approval of clinical trials: is it time to reinvent the wheel?

Less than 1% of all clinical trials are conducted in Africa. In 2019, only six of 26 oncology clinical trials conducted in Africa were conducted in countries with subjects of African ancestry. There are multiple barriers that hinder the conduct of cancer clinical trials in Africa. Time to trial activation (TTA) is the administrative and regulatory process required before a study can be activated—an important metric and often a major barrier for site selection. In Kenya, TTA involves review by Institutional Review Board (IRB), Pharmacy and Poisons Board, National Commission for Science, Technology and Innovation and Ministry of Health, all in a sequential fashion. We performed a prospective review of TTA for all clinical trials initiated and began enrolment at the Aga Khan University-Clinical Research Unit between June 2020 and November 2022. TTA was defined as total time from submission of study documents (to regulatory bodies) to site activation by the sponsor. A total of 12 studies were submitted for regulatory review. Eleven (nine industry sponsored and two investigator initiated) were approved for activation. Three were COVID-19-related studies and eight were non-COVID-19-related studies. Mean TTA for COVID-related studies was 80 days (range 40–120). Mean TTA for non-COVID-related studies was 259 days (range 190–399). This TTA difference was statistically significant (p=0.02). TTA remains a significant barrier to the efficient regulatory approval of and subsequent conduct of clinical trials in Africa. COVID-19 pandemic revealed that parallel processing and expedited review of clinical trials allows efficient TTA without compromising human subject safety or data integrity. These lessons need to be applied to all clinical trials in order for African sites to become competitive and contribute data from African patients to global knowledge

A phase 3 Trial of RTS,S/AS01 Malaria Vaccine in African Infants.

\ud \ud The candidate malaria vaccine RTS,S/AS01 reduced episodes of both clinical and severe malaria in children 5 to 17 months of age by approximately 50% in an ongoing phase 3 trial. We studied infants 6 to 12 weeks of age recruited for the same trial. We administered RTS,S/AS01 or a comparator vaccine to 6537 infants who were 6 to 12 weeks of age at the time of the first vaccination in conjunction with Expanded Program on Immunization (EPI) vaccines in a three-dose monthly schedule. Vaccine efficacy against the first or only episode of clinical malaria during the 12 months after vaccination, a coprimary end point, was analyzed with the use of Cox regression. Vaccine efficacy against all malaria episodes, vaccine efficacy against severe malaria, safety, and immunogenicity were also assessed. The incidence of the first or only episode of clinical malaria in the intention-to-treat population during the 14 months after the first dose of vaccine was 0.31 per person-year in the RTS,S/AS01 group and 0.40 per person-year in the control group, for a vaccine efficacy of 30.1% (95% confidence interval [CI], 23.6 to 36.1). Vaccine efficacy in the per-protocol population was 31.3% (97.5% CI, 23.6 to 38.3). Vaccine efficacy against severe malaria was 26.0% (95% CI, -7.4 to 48.6) in the intention-to-treat population and 36.6% (95% CI, 4.6 to 57.7) in the per-protocol population. Serious adverse events occurred with a similar frequency in the two study groups. One month after administration of the third dose of RTS,S/AS01, 99.7% of children were positive for anti-circumsporozoite antibodies, with a geometric mean titer of 209 EU per milliliter (95% CI, 197 to 222). The RTS,S/AS01 vaccine coadministered with EPI vaccines provided modest protection against both clinical and severe malaria in young infants. (Funded by GlaxoSmithKline Biologicals and the PATH Malaria Vaccine Initiative; RTS,S ClinicalTrials.gov number, NCT00866619.)

First results of phase 3 trial of RTS,S/AS01 malaria vaccine in african children

Background An ongoing phase 3 study of the efficacy, safety, and immunogenicity of candidate malaria vaccine RTS,S/AS01 is being conducted in seven African countries. Methods From March 2009 through January 2011, we enrolled 15,460 children in two age categories - 6 to 12 weeks of age and 5 to 17 months of age - for vaccination with either RTS,S/AS01 or a non-malaria comparator vaccine. The primary end point of the analysis was vaccine efficacy against clinical malaria during the 12 months after vaccination in the first 6000 children 5 to 17 months of age at enrollment who received all three doses of vaccine according to protocol. After 250 children had an episode of severe malaria, we evaluated vaccine efficacy against severe malaria in both age categories. Results In the 14 months after the first dose of vaccine, the incidence of first episodes of clinical malaria in the first 6000 children in the older age category was 0.32 episodes per person-year in the RTS,S/AS01 group and 0.55 episodes per person-year in the control group, for an efficacy of 50.4% (95% confidence interval [CI], 45.8 to 54.6) in the intention-to-treat population and 55.8% (97.5% CI, 50.6 to 60.4) in the per-protocol population. Vaccine efficacy against severe malaria was 45.1% (95% CI, 23.8 to 60.5) in the intention-to-treat population and 47.3% (95% CI, 22.4 to 64.2) in the per-protocol population. Vaccine efficacy against severe malaria in the combined age categories was 34.8% (95% CI, 16.2 to 49.2) in the per-protocol population during an average follow-up of 11 months. Serious adverse events occurred with a similar frequency in the two study groups. Among children in the older age category, the rate of generalized convulsive seizures after RTS,S/AS01 vaccination was 1.04 per 1000 doses (95% CI, 0.62 to 1.64). Conclusions The RTS,S/AS01 vaccine provided protection against both clinical and severe malaria in African children. (Funded by GlaxoSmithKline Biologicals and the PATH Malaria Vaccine Initiative; RTS,S ClinicalTrials.gov number, NCT00866619 .