2 research outputs found
COVID-19 in Africa: rethinking the tools to manage future pandemics
Corona virus disease 2019 (COVID-19) remains an incurable, progressive pneumonia-like illness characterized by fever, dry cough, fatigue, and headache during its early stages. COVID-19 has ultimately resulted in mortality in at least 2 million people worldwide. Millions of people globally have already been affected by this disease, and the numbers are expected to increase, perhaps until an effective cure or vaccine is identified.Although Africa was initially purported by the World Health Organization (WHO) to be severely hit by the pandemic, Africa recorded the least number of cases during the first wave, with lowest rates of infections, compared to Asia, Europe, and the Americas. This statistic might be attributed to the low testing capacity, existing public health awareness and lessons learnt during Ebola epidemic. Nonetheless, the relatively low rate of infection should be an opportunity for Africa to be better prepared to overcome this and future epidemics.In this paper, the authors provide insights into the dynamics and transmission of the severe acute respiratory syndrome corona virus (SARS-CoV-2) during the first wave of the pandemic; possible explanations into the relatively low rates of infection recorded in Africa; with recommendations for Africa to continue to fight Covid-19; and position itself to effectively manage future pandemics.
Keywords: Covid-19; Ebola; Science Leadership in Africa; Vaccine; SARS-COV-2; Preventative Health; Future Pandemics
Acid-Activated Biochar for Efficient Elimination of Amoxicillin From Wastewater
In exploring the potential of agricultural waste as an efficient adsorbent, acid-activated coconut husk biochar was prepared, characterized and applied to remove amoxicillin from wastewater. The mechanism of adsorption was also investigated through isotherm and kinetic studies. The biochar was activated with HNO3 for 2 h at 25°C and investigated under varying experimental conditions of pH (1–11), initial amoxicillin concentration (0.5–2.5 mg/L), adsorbent dosage (2–20 mg) and contact time (0–24 h). The adsorption process was characterized by rapid attainment of adsorption equilibrium and high values of adsorption capacity. Acid activation had a significant impact on the adsorptive capacity of biochar as removal efficiency improved from 90% (over an hour) to 98.9% (within 40 min). The FTIR results confirmed the characteristic adsorption peaks of C-H, =C-H, C=C, C-O, C=O and O-H, suggesting the dominant presence of aromatic and carbonyl functional groups on the surface of the biochar. Adjustments in peak shapes and transmittance were observed for these functional groups after the adsorption; highlighting the likely interaction between the biochar and the amoxicillin during the adsorption which has been succinctly proposed. The SEM micrographs showed the growth of leaf-like flakes of irregular shapes and pores essential for the adsorption. The rate and mechanism of adsorption were driven by the variable surface charge of the adsorbent and the degree of ionization of the adsorbates, which were largely controlled by the solution pH. Adsorption rates were highest in the acidic medium, peaking around a pH of 3, then remained relatively stable between pHs of 5 and 7 before reducing dramatically with increasing pH in the alkaline region. The adsorption best followed the Langmuir model of isotherm while the kinetics mimicked the pseudo–second order (PSO). The findings suggest that HNO3-activated coconut biochar is a promising, low-cost and porous adsorbent effective for amoxicillin removal
