How to evaluate the potential toxicity of therapeutic carbon nanomaterials? A comprehensive study of carbonized nanogels with multiple animal toxicity test models.

Carbon-based nanomaterials have great potential in medical applications, especially in the treatment of infectious diseases and even tumors. However, to safely execute the application of carbon nanomaterials in human treatments, conducting safety assessments and establishing suitable evaluation criteria are necessary. In this study, lysine-carbonized nanogels (Lys-CNGs) that display antibacterial and antiviral abilities were employed in a comprehensive evaluation of their toxicity profiles through assessments in different animal models and growth stages. It was observed that zebrafish at the embryo and eleutheroembryo stages experienced significant toxic effects at a concentration of 15-fold the recommended dosage (0.5 ppm), whereas adult zebrafish following long-term consumption of fodder containing Lys-CNGs presented no adverse effects. Further microbiota analysis indicated that Lys-CNGs did not cause significant changes in the composition of the intestinal bacteria. In contrast, in the toxicity assessments with mammalian animal models, the Lys-CNGs showed no adverse effects, such as weight loss, dermal irritation, and skin sensitization responses in rabbits and guinea pigs, even at a high dose of 2000 mg/kg body weight. Our study revealed that Lys-CNGs have different toxic effects on different growth stages of zebrafish. Researchers in this field should carefully consider the implications of these toxicity profiles during the development of therapeutic carbon-based nanomaterials and for comparison of studies.

Somatic embryogenesis from leaf explants of Tagetes erecta L.

Tagetes erecta is an asteraceous plant of industrial, ornamental and medicinal importance; its inflorescences have been used as a pigment source for food coloring, mainly for poultry skin and eggs. Nevertheless, there are few reports on plant regeneration or micropropagation, because unsuccesfull results in the plant's reaction to the growth regulators, developing embryogenesis on Tagetes erecta. In this study, somatic embryogenesis was induced and plantlets of Tagetes erecta were regenerated. For induction of globular structures MS medium supplemented with 2,4-D (4.5 µM) and BAP (8.8 µM) was used; globular structures were transferred to MS medium with 45 g l-1 sucrose until the embryos maturation. Transmission electron microscopy showed characteristic subcellular structures of embryogenic callus. Somatic embryos were transferred to MS medium without plant growth regulators and whole plantlets were obtained. In vitro plants were successfully transplanted into a mixture of peat moss and vermiculite (1 : 1 v/v) under greenhouse conditions. In this study, somatic embryogenesis and plant regeneration system from foliar explants were established, an important requirement for performing genetic transformation events on Tagetes erecta.