De Novo Generated Human Red Blood Cells in Humanized Mice Support Plasmodium falciparum Infection

Immunodeficient mouse–human chimeras provide a powerful approach to study host specific pathogens like Plasmodium (P.) falciparum that causes human malaria. Existing mouse models of P. falciparum infection require repeated injections of human red blood cells (RBCs). In addition, clodronate lipsomes and anti-neutrophil antibodies are injected to suppress the clearance of human RBCs by the residual immune system of the immunodeficient mice. Engraftment of NOD-scid Il2rg[superscript -/-] mice with human hematopoietic stem cells leads to reconstitution of human immune cells. Although human B cell reconstitution is robust and T cell reconstitution is reasonable in the recipient mice, human RBC reconstitution is generally poor or undetectable. The poor reconstitution is mainly the result of a deficiency of appropriate human cytokines that are necessary for the development and maintenance of these cell lineages. Delivery of plasmid DNA encoding human erythropoietin and interleukin-3 into humanized mice by hydrodynamic tail-vein injection resulted in significantly enhanced reconstitution of erythrocytes. With this improved humanized mouse, here we show that P. falciparum infects de novo generated human RBCs, develops into schizonts and causes successive reinvasion. We also show that different parasite strains exhibit variation in their ability to infect these humanized mice. Parasites could be detected by nested PCR in the blood samples of humanized mice infected with P. falciparum K1 and HB3 strains for 3 cycles, whereas in other strains such as 3D7, DD2, 7G8, FCR3 and W2mef parasites could only be detected for 1 cycle. In vivo adaptation of K1 strain further improves the infection efficiency and parasites can be detected by microscopy for 3 cycles. The parasitemia ranges between 0.13 and 0.25% at the first cycle of infection, falls between 0.08 and 0.15% at the second cycle, and drops to barely detectable levels at the third cycle of infection. Compared to existing mouse models, our model generates human RBCs de novo and does not require the treatment of mice with immunomodulators.Singapore. National Research Foundation (Singapore-MIT Alliance for Research and Technology

Biosorption of Cadmium by Mangrove-Derived Cyanobacteria (Gloeocapsa sp ARKK3)

Dried microbial biomass of Gloeocapsa sp. Trichoderma, and Thrustochytrids used as bioadsorbent for the removal of cadmium in the artificial sewage. Among the three species the maximum adsorption recorded in Gloeocapsa sp. biomass. For the augmentation of cadmium removal in sewage, adsorption process conditions was statistically optimized by the method of response surface methodology (RSM) and adsorption kinetics also studied. The important factors of temperature, pH, adsorbent dosage and processing time were selected for optimization, and it was done with 30 experimental cycles derived from centre composite design (CCD). The statistical optimization reveled that optimized condition for cadmium removal was pH 9, temperature 40ºC, adsorbent dosage 0.6 mg.l-1 and 60 minutes. Finally in this condition was experimentally proved with yield of cadmium removal of 92.9 % under statistically optimized condition. In the case of the adsorption kinetic Gloeocapsa sp. biomass showed a significant adsorption capacity of qmax-56.96 (mg.g-1). The present study concluded that the microbial dried biomass derived from marine Gloeocapsa sp. was a potent source for the removal of the cadmium in the sewage waste water

Snakebite and its socio-economic impact on the rural population of Tamil Nadu, India

BACKGROUND: Snakebite represents a significant health issue worldwide, affecting several million people each year with as many as 95,000 deaths. India is considered to be the country most affected, but much remains unknown about snakebite incidence in this country, its socio-economic impact and how snakebite management could be improved. METHODS/PRINCIPAL FINDINGS: We conducted a study within rural villages in Tamil Nadu, India, which combines a household survey (28,494 people) of snakebite incidence with a more detailed survey of victims in order to understand the health and socio-economic effects of the bite, the treatments obtained and their views about future improvements. Our survey suggests that snakebite incidence is higher than previously reported. 3.9% of those surveyed had suffered from snakebite and the number of deaths corresponds to 0.45% of the population. The socio-economic impact of this is very considerable in terms of the treatment costs and the long-term effects on the health and ability of survivors to work. To reduce this, the victims recommended improvements to the accessibility and affordability of antivenom treatment. CONCLUSIONS: Snakebite has a considerable and disproportionate impact on rural populations, particularly in South Asia. This study provides an incentive for researchers and the public to work together to reduce the incidence and improve the outcomes for snake bite victims and their families