ABSTRACT
As an essential trace element, selenium plays a very important role in antioxidation and maintaining redox homeostasis in various metabolic processes. With the development of nano-technology, selenium nanoparticles ( SeNPs) have become potential biomedical drugs because of their low toxicity, degrad-ability and high bioavailability. With the ability to activate apop-tosis or autophagy by regulating the production of reactive oxygen species ( ROS) , SeNPs are widely used in anticancer therapy and pathogens killing/clearance. In addition, with excellent stability and drug encapsulation capacity, SeNPs are serving as a kind of effective nano-carriers for anti-cancer and anti-infection treatments. Interestingly, the important role of SeNPs in immune regulation ( such as the activation of macrophages and T effector cells) provides a new possibilities to achieve nano-immune syn-ergetic treatment strategy for anti-cancer and anti-infection thera¬pies. In this paper, we review the latest progress of the prepara¬tion methods and safety for SeNPs, followed by the advances of anti-infection, anti-cancer effects and its mechanisms, which would be helpful for promoting the pace of clinical research and application. In addition, we also summarize the functions of SeNPs in other aspects, so as to provide beneficial assistance for facilitating its scientific and clinical research.
ABSTRACT
The primary and secondary tuberculosis features two completely different pathogenesis.At present,the pathogenesis of primary tuberculosis has been clear,whereas that of secondary tuberculosis remains unclear.In order to decipher the mechanism of secondary infection of
Subject(s)
Humans , Coinfection , Cord Factors , Mycobacterium tuberculosis , Tuberculosis , Tuberculosis, PulmonaryABSTRACT
Bacterial communities usually develop biofilms abound in nature niche. The development of biofilm is a highly dynamic and complex process coordinated by multiple mechanisms, of which two-component system and quorum sensing are two well-defined systems. Biofilm is involved in the virulence of many pathogens. Therefore, targeting the key factors involved in the biofilm formation represents a novel and promising avenue for developing better antibiotics.