ABSTRACT
Background: Nanoparticles have been applied to medicine, hygiene, pharmacy and dentistry, and will bring significant advances in the prevention, diagnosis, drug delivery and treatment of disease. Green synthesis of metal nanoparticles has a very important role in nanobiotechnology, allowing production of non-toxic and eco-friendly particles
Objectives: Green synthesis of silver nanoparticles [AgNPs] was studied using pine pollen as a novel, cost-effective, simple and non-hazardous bioresource. The antifungal activity of the synthesized AgNPs was investigated in vitro
Materials and Methods: Biosynthesis of AgNPs was conducted using pollen of pine [as a novel bioresource] acting as both reducing and capping agents. AgNPs were characterized using UV-visible spectroscopy, X-ray diffraction and transmission electron microscopy. In evaluation for antifungal properties, the synthesized AgNPs represented significant in vitro inhibitory effects on Neofusicoccum parvum cultures
Results: Pine pollen can mediate biosynthesis of colloidal AgNPs with an average size of 12 nm. AgNPs were formed at 22[degree]C and observed to be highly stable up to three months without precipitation or decreased antifungal property. AgNPs showed significant inhibitory effects against Neofusicoccum parvum
Conclusion: The first report for a low-cost, simple, well feasible and eco-friendly procedure for biosynthesis of AgNPs was presented. The synthesized AgNPs by pine pollen were nontoxic and eco-friendly, and can be employed for large-scale production. The nanoparticles showed strong effect on quantitative inhibition and disruption of antifungal growth
Subject(s)
Antifungal Agents , Pollen , Nanoparticles , PinusABSTRACT
Background: Protein aggregation is one of the important, common and troublingproblems in biotechnology, pharmaceutical industries and amyloid-re-lated disorders
Methods: In the present study, the inhibitory effects of some carbohydrates [alginate,beta -cyclodextrin and trehalose] on the formation of nano-globular aggregates fromnormal [HSA] and glycated [GHSA] human serum albumin were studied; when theformation of aggregates was induced by the simultaneous heating and addition ofdithiotheritol. For the investigations, the biophysical methods of UV-vis spectrophotometry,circular dichroism spectroscopy, transmission electron microscopy andtensiometry were employed
Results: The effect of inhibitory mechanism of these inhibitors on the aggregation ofHSA and GHSA was expressed and compared together
Conclusion: The results showed that the nucleus formation step of the aggregationprocess of HSA and GHSA was different in the presence of alginate [compared tobeta -cyclodextrin and trehalose]. The inhibition efficiencies of the carbohydrates on the aggregateformation of HSA and GHSA were different, arising from the differences inthe hydrophobicities of HSA and GHSA, and also, the differences between HSA-andGHSA-carbohydrate interactions
ABSTRACT
Nanostructured materials are being increasingly applied to improve the performance and efficiency of electrochemical genosensors. The unique properties of nanostructured materials offer excellent prospects for biological sensing systems and for designing a new generation of biosensing devices with exhibiting novel functions. Application of nanostructured materials in the fabrication of electrochemical genosensors offers several important advantages over conventional biological procedures, and can have a significant impact on clinical diagnosis. In this context, nanomaterials such as polymeric nanoparticles, metallic nanoparticles and metal oxide nanoparticles were actively investigated for their applications in the fabrication of electrochemical genosensors. In this article, an overview of various nanostructured materials in the fabrication of electrochemical genosensors that utilize different biological recognition elements for biomedical applications is presented
ABSTRACT
Investigation of the redox properties of drugs and their determination are performed by electrochemical techniques. Data obtained from electrochemical techniques are often correlated with molecular structure and pharmacological activity of drugs. In this regard, different modified electrodes were applied as sensors for quantification of different drugs. A nanocomposite of reduced graphene oxide-cobalt hexacyanoferrate was synthesized by a simple precipitation route. Scanning electron microscopy revealed that the nanocomposite comprised nanoparticles of cobalt hexacyanoferrate attached to the reduced graphene oxide nanosheets. A nanocomposite-modified carbon paste electrode was then fabricated. It represented prominent activity toward the electrocatalytic oxidation of ascorbic acid, and the kinetics of the electrooxidation process was evaluated. Finally, an amperometric method was developed for the quantification of ascorbic acid in different pharmaceutical formulations
Subject(s)
Pharmaceutical Preparations , Graphite , Ferrocyanides , NanocompositesABSTRACT
Extensive researches exist in the recent years about attractive properties of nanoparticles and their applicability in design of the biosensors. In this area, development of simple and reliable biosensors for the determination of sulfhydryl compound is pertinent. In this trial, an enzyme-less amperometric biosensor was designed for the detection of cysteine and N-acetyl-L-cysteine. Nanoparticles of iron [III] oxide core-cobalt hexacyanoferrate shell were synthesized and employed as a signal transducer in the amperometric biosensor. The nanoparticles represented a good redox behavior and represented an efficient catalytic activity toward the oxidation of the substrates. Amperometric signals of the biosensor were successfully recorded for quantification of the substrates and the biosensor was successfully employed for the analysis of real samples or determination in blood serum and urine