Application of encapsulated nano materials as feed additive in livestock and poultry: a review.

Livestock plays a significant role in the socio-economic development of developing countries by providing livelihood and nutritional security, transport, contingency during crop failure and day-to-day earning to the farm family. The human population is projected to reach 9.9 billion by 2050, which along with increasing urbanization and growing income is expected to increase the demand for livestock products. Global livestock feed demand will be almost doubled, and 1.3 billion tons of grain will be required for feeding farm animals alone. To increase the livestock production efficiency, feed additives have been used to improve the production and growth of high-quality livestock products. Even though feed additives have a pertinent role in animal growth performance, disadvantages like endo toxin production and reduced absorption of nutrients by interaction of additives with naturally occurring nutrients limits the use of feed additives. A majority of the macronutrients in the rumen are metabolized or transformed by microbes, hence nutrients should be preserved and made available in the small intestine. Encapsulation technology, which has been employed in a broad range of applications in various fields of science, can address this challenge and rejuvenate livestock nutrition research. The present review explores the importance of encapsulated nano material in livestock and poultry production.

Anticancer potential of ZnO nanoparticle-ferulic acid conjugate on Huh-7 and HepG2 cells and diethyl nitrosamine induced hepatocellular cancer on Wistar albino rat.

Drawbacks and limitations of recently available therapies to hepatocellular cancer (HCC) devoted the scientist to focus on emerging new strategies. ZnO nanoparticles (ZnONPs) based chemotherapeutics has been emanating as a promising approach to maximize therapeutic synergy facilitating the discovery of novel multitargeted combinations. In the present study we conjugated ZnONPs with ferulic acid (ZnONPs-FAC) characterized by computational, spectroscopic and microscopic techniques. In vitro anticancer potential has been evaluated by assessing cell viability, morphology, ROS generation, mitochondrial membrane permeability, comet assay, immunofluorescent staining of 8-OHdG, Ki67 and γ-H2AX, cell cycle analysis and western blot analysis and in vivo anticancer potential against DEN induced HCC was analyzed by histopathological and immunohistochemical methods. The results revealed that ZnONPs-FAC induces cell death through apoptosis and can suppress the DEN-induced HCC. Our study documents therapeutic potential of nanoparticle conjugated with phytochemicals, suggesting a new platform for combinatorial chemotherapy.

Selenium nanoparticles synthesized in aqueous extract of Allium sativum perturbs the structural integrity of Calf thymus DNA through intercalation and groove binding.

Biomedical application of selenium nanoparticles (SeNPs) demands the eco-friendly composite for synthesis of SeNPs. The present study reports an aqueous extract of Allium sativum (AqEAS) plug-up the current need. Modern spectroscopic, microscopic and gravimetric techniques were employed to characterize the synthesized nanoparticles. Characterization studies revealed the formation of crystalline spherical shaped SeNPs. FTIR spectrum brings out the presence of different functional groups in AqEAS, which influence the SeNPs formation and stabilization. Furthermore the different aspects of the interaction between SeNPs and CT-DNA were scrutinized by various spectroscopic and cyclic voltametric studies. The results reveals the intercalation and groove binding mode of interaction of SeNPs with stacked base pair of CT-DNA. The Stern-Volmer quenching constant (KSV) were found to be 7.02×106M-1 (ethidium bromide), 4.22×106 M-1 (acridine orange) and 7.6×106M-1 (Hoechst) indicating strong binding of SeNPs with CT-DNA. The SeNPs - CT-DNA interactions were directly visualized by atomic force microscopy. The present study unveils the cost effective, innocuous, highly stable SeNPs intricate mechanism of DNA interaction, which will be a milestone in DNA targeted chemotherapy.