Comparative Toxicity of Nanomaterials to Air-blood Barrier Permeability Using an In Vitro Model / 生物医学与环境科学（英文）

OBJECTIVE@#To comparatively study the toxicity of four metal-containing nanoparticles (MNPs) and their chemical counterparts to the air-blood barrier (ABB) permeability using an in vitro model.@*METHODS@#ABB model, which was developed via the co-culturing of A549 and pulmonary capillary endothelium, was exposed to spherical CuO-NPs (divided into CuO-40, CuO-80, and CuO-100 based on particle size), nano-Al2O3 (sheet and short-rod-shaped), nano-ZnO, nano-PbS, CuSO4, Al2(SO4)3, Zn(CH3COO)2, and Pb(NO3)2 for 60 min. Every 10 min following exposure, the cumulative cleared volume (ΔTCL) of Lucifer yellow by the model was calculated. A clearance curve was established using linear regression analysis of ΔTCL versus time. Permeability coefficient (P) was calculated based on the slope of the curve to represent the degree of change in the ABB permeability.@*RESULTS@#The results found the increased P values of CuO-40, CuO-80, sheet, and short-rod-shaped nano-Al2O3, Al2(SO4)3, and Pb(NO3)2. Among them, small CuO-40 and CuO-80 were stronger than CuO-100 and CuSO4; no difference was observed between Al2(SO4)3 and sheet and short-rod-shaped nano-Al2O3; and nano-PbS was slightly weaker than Pb(NO3)2. So clearly the MNPs possess diverse toxicity.@*CONCLUSION@#ABB permeability abnormality means pulmonary toxicity potential. More studies are warranted to understand MNPs toxicity and ultimately control the health hazards.

Renal Cell Toxicity Screening of Drugs by High Content Analysis / 中国药学杂志

OBJECTIVE: To discuss the feasibility of renal toxicity screening of drugs using high content analysis technology. METHODS: Rosiglitazone was selected as the negative drug and valinomycin was selected as the positive drug. High intension HK-2 renal cell toxicity screening model was established through testing five indexes including cell number, DNA intensity, cell permeability, mitochondrial membrane potential and cytochrome C, using high content analysis technology. Aristolochic acid A and cisplatine that has obvious renal toxicity was used to validate the model. RESULTS: Valinomycin, cisplatin and aristolochic acid A has obvious renal toxicity;rosiglitazone don't have renal toxicity. CONCLUSION: High content analysis can be used to screen renal toxicity of drugs.

Comparison of bioassays using the anostracan crustaceans Artemia salina and Thamnocephalus platyurus for plant extract toxicity screening / Comparação de bioensaios com os crustáceos Artemia salina e Thamnocephalus platyurus para abordagem de extratos de plantas com toxicidade

Three lethality bioassays, using the salt-water crustacean Artemia salina Leach, Artemiidae, (conventional 96 microwell plate test and the Artoxkit M microbiotest) and the freshwater crustacean Thamnocephalus platyurus Packard, Thamnocephalidae, (Thamnotoxkit F microbiotest), were compared using extracts of ten Guatemalan plant species. It was previously observed that five of them have anti-Artemia activity. These were: Solanum americanum Mill., Solanaceae, Gliricidia sepium (Jacq.) Kunth ex Walp., Fabaceae, Neurolaena lobata (L.) Cass., Asteraceae, Petiveria alliacea L., Phytolaccaceae, and Ocimum campechianum Mill., Lamiaceae. The five others: Curatella americana L., Dilleniaceae, Prunus barbata Koehne, Rosaceae, Quercus crispifolia Trel., Fagaceae, Rhizophora mangle L., Rhizophoraceae, and Smilax domingensis Willd., Smilacaceae, do not. All plants without anti-Artemia activity had no lethal effects in both assays with A. salina. For the plants with anti-Artemia activity the Artoxkit M was not sensitive to G. sepium and the conventional Artemia test was not sensitive to S. americanum, G. sepium and N. lobata. All the plant extracts, except for that of C. americana, had lethal effects on T. platyurus and the lethal median concentration (LC50) levels for this organism were in all cases substantially lower than those of the salt-water test species. This study revealed that T. platyurus is a promising test species worth further in depth investigation for toxicity screening of plant extracts with potential medicinal properties.

Três bioensaios de letalidade com o crustáceo de água salgada Artemia salina Leach, Artemiidae, (teste convencional em microplaca de 96 poós Artoxkit microbiotest M) e o crustáceo de água doce Thamnocephalus platyurus Packard, Thamnocephalidae (Thamnotoxkit microbiotest F), foram comparados utilizando extratos de dez espécies de plantas da Guatemala. Foi previamente observado que cinco delas possuem atividade anti-Artemia: Solanum americanum Mill., Solanaceae, Gliricidia sepium (Jacq.) Kunth ex Walp., Fabaceae, Neurolaena lobata (L.) Cass., Asteraceae, Petiveria alliacea L., Phytolaccaceae e Ocimum campechianum Mill., Lamiaceae. As outras cinco espécies, Curatella americana L., Dilleniaceae, Prunus barbata Koehne, Rosaceae, Quercus crispifolia Trel., Fagaceae, Rhizophora mangle L., Rhizophoraceae e Smilax domingensis Willd., Smilacaceae, não. Todas as plantas sem atividade anti-Artemia não tiveram nenhum efeito letal em ambos os ensaios com A. salina. Para as plantas com atividade anti-Artemia o M Artoxkit não foi sensível a G. sepium e teste convencional de Artemia não foi sensível a S. americanum, G. sepium e N. lobata. Todos os extratos vegetais, exceto o de C. americana, apresentaram um efeito letal sobre T. platyurus e a concentração letal média (CL50) para este organismo em todos os casos foram substancialmente inferiores aos da espécie de teste de água salgada. Este estudo revelou que T. platyurus é teste promissor para uma investigação aprofundada na seleção de extratos de plantas com potenciais propriedades medicinais.