The effects of biological and chemical silver nanoparticles along with aerobic and anaerobic training protocols on tissues: Morphological and histopathological evaluation.

Nanotechnology and its byproducts are used increasingly considering its global nanotechnology market size and many applications in the health field. The aim of the present study was to investigate the effect of aerobic and anaerobic exercises on cellular uptake of nanoparticles in body tissues. Fusarium oxysporum was used to synthesize biological AgNPs in silver nitrate solution and UV-vis spectrophotometer; XRD and TEM were used to confirm production of nanoparticles. Moreover, 45 male Wistar rats were purchased and randomly divided into 9 equal groups including healthy control groups, aerobic preparation, anaerobic preparation, biological AgNPs, chemical AgNPs, biological AgNPs+aerobic preparation, biological AgNPs+anaerobic preparation, chemical AgNPs+ aerobic preparation, chemical AgNPs+anaerobic preparation. In order to induce aerobic and anaerobic preparation and to create tissue adaptations, male rats completed two types of aerobic and anaerobic protocols three sessions per week for 10 weeks. At the end of the study, sampling was done for histopathology study. The size and shape of AgNPs was 20-30 nm and spherical to polygonal, respectively. The results showed that anaerobic exercise was significantly effective in weight loss. The chemical nanoparticle group led to more intensive tissue degradation in all variables and there were no significant tissue changes in the aerobic, anaerobic, the biological nanoparticles + aerobic and anaerobic groups. It seems that biological AgNPs are more effective than chemical AgNPs on body tissues and chemical AgNPs lead to more tissue damage in most variables. RESEARCH HIGHLIGHTS: There were severe degradative histological effects in the chemical AgNPs groups compare biological AgNPs groups, in terms of most variables.

Liver tissue changes induced by biological and chemical silver nanoparticles in trained male Wistar rats.

INTRODUCTION: Despite the widespread use of chemical and biological nano-silver are in industry, their side effects on hepatocytes have been less studied. On the other hand, different types of physical activities may increase liver resistance to toxins. Therefore, the aim of this study was to evaluate the resistance of hepatocytes to receiving chemical versus biological silver nanoparticles in aerobic and anaerobic pre-conditioned rats. MATERIALS AND METHODS: 45 male Wistar rats with similar average range of age (8-12 weeks) and weight (180-220 g), were randomly divided normally into 9 groups, including Control (C), Aerobic (A), Anaerobic (AN), Biological nano-silver (BNS), Chemical nano-silver (CNS), Biological nano-silver + Aerobic (BNS+A), Biological nano-silver + Anaerobic (BNS+AN), Chemical nano-silver + Aerobic (CNS+A) and Chemical nano-silver + Anaerobes (CNS+AN). Prior to injection, rats trained on a rodent treadmill, 10 weeks, 3 sessions per week, according to aerobic and anaerobic protocols.Then, 48 h after the last training session, the rats received 10 % of their body weight, chemical and biological nanosilver intraperitoneally. Liver enzymes (ALT, AST, and ALP) and liver tissue were sent to the relevant laboratories for further evaluation. RESULTS: Results showed that the weight of rats in all groups of physical pre-conditioning, decreased comparison to the control and non-exercise groups, and this decrease was much greater in the anaerobic group (p-value=0.045). Also, the distance traveled in the progressive endurance running a test on a rodent treadmill, increased significantly in the training groups compared to the nano-exercise and control groups (p-value=0.001). Also, the results showed that the level of ALT in chemical nano-silver (p-value=0.004) and biological nano-silver (p-value=0.044), increased significantly compared to other groups. Also, histopathological results showed that nano-silver injection affects the structure of the liver of male Wistar rats and causes inflammation, hyperemia and destruction of liver cells, especially in chemical nano-silver. CONCLUSION: The results of the present study showed that chemical silver nanoparticles cause liver damage more than comparison biological ones. Also, physical pre-conditioning increases hepatocyte resistance to toxic nanoparticle doses and aerobic preparation appears to be more effective than anaerobic.