Activity

Smoke is generated by energy-based surgical instruments. The airborne by-products may have potential health implications.

We developed a simple way to use de conventional surgical evacuator coupled with de electrosurgical pen attached to a 14G bladder catheter for open surgery. It was used in ten prospective patients with breast cancer.

We notice a high reduction in surgical smoke during all breast surgery. A questionnaire was used for all participants of the surgery to answer the impression that they had about the device. The subjective impression was that the surgical smoke in contact whit the surgical team was reduced by more than 95%.

Surgical smoke is the gaseous by-product produced by heat-generating devices in various surgical procedures. Surgical smoke may contain chemicals particles, bacteria, and viruses that are harmful and increase the risk of infection for surgeons and all the team in the operation room due to long term exposure of smoke mainly in coronavirus disease 2019 age. The adapted device described is a very simple and cheaper way to use smoke evacuators attached with the monopolar electrosurgical pen to reduce smoke exposure to the surgical team worldwide.

Surgical smoke is the gaseous by-product produced by heat-generating devices in various surgical procedures. Surgical smoke may contain chemicals particles, bacteria, and viruses that are harmful and increase the risk of infection for surgeons and all the team in the operation room due to long term exposure of smoke mainly in coronavirus disease 2019 age. The adapted device described is a very simple and cheaper way to use smoke evacuators attached with the monopolar electrosurgical pen to reduce smoke exposure to the surgical team worldwide.

Students can have some issues in the comprehension and execution of coronal preparations in fixed partial prosthesis (FPP). Some issues pertain to the amount of reduction, the inclination, and the positioning, all of which are important for the execution of an ideal preparation while respecting the required biomechanical principles.

The present study’s aim was to evaluate the main problems experienced by graduation students regarding coronal preparation in FPP and to suggest teaching skills to help students and professors.

A total of 87 students, who were enrolled in the 3rd year of Dentistry at the FPP course – in the Institute of Science and Technology, São Paulo State University, between 2017 and 2018, participated in the study. Two methodologies were developed, applied, and validated first, a mannequin with a scheme of colors to help students visualize the coronal preparation; second, a comparison of different didactic methods.

Only 54.02% of the students answered the questionnaire, and the main pand the live projection were approved as auxiliary didactic resources for teaching FPP.The Octapeptide ELHQEEPL, which was identified from the rapeseed protein napin showed prominent Dipeptidyl peptidase-IV (DPP-IV) inhibitory activity. The objective of this study was to investigate the DPP-IV inhibitory activity and transepithelial transport of ELHQEEPL in an approaching intestinal condition using Caco-2 cell monolayers. ELHQEEPL and its degraded fragments EL, HQEEP, and methylated ELHQEEPL were transported across Caco-2 cell monolayers through different pathways. Compared with the nonbiological enzyme inhibition test, the in vitro experiment on Caco-2 cell monolayers showed that the IC50 value of DPP-IV inhibition increased by 43.11% for ELHQEEPL. There was no significant change in DPP-IV gene expression in the Caco-2 cell monolayers upon treatment with ELHQEEPL. Furthermore, molecular docking predicted that the weaker binding between inhibitory peptide and enzyme for the degradation products from ELHQEEPL during transepithelial transport greatly limited its role in inhibiting DPP-IV. PRACTICAL APPLICATIONS The DPP-IV inhibitory activity of ELHQEEPL was confirmed using Caco-2 cell monolayers as a novel assessment tool, although its potency was reduced by metabolic degradation. In general, this study reported the use of Caco-2 cell monolayers as a tool for comprehensively studying peptides as sources of DPP-IV inhibitors. check details A Caco-2 cell-based approach with molecular docking can be adapted for the investigation of intestinal absorption and activity attenuation of food peptides being considered for enzymatic action. Moreover, since the Caco-2 cells express a wide range of enzymes, this method can be used for screening for other active food peptides such as for the inhibitors of ACE and a-glucosidase.Increasingly, microbeams and microcrystals are being used for macromolecular crystallography (MX) experiments at synchrotrons. However, radiation damage remains a major concern since it is a fundamental limiting factor affecting the success of macromolecular structure determination. The rate of radiation damage at cryotemperatures is known to be proportional to the absorbed dose, so to optimize experimental outcomes, accurate dose calculations are required which take into account the physics of the interactions of the crystal constituents. The program RADDOSE-3D estimates the dose absorbed by samples during MX data collection at synchrotron sources, allowing direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has aided the study of MX radiation damage and enabled prediction of approximately when it will manifest in diffraction patterns so it can potentially be avoided. However, the probability of photoelectron escape from the sample and entry from the surrounding material has not previously been included in RADDOSE-3D, leading to potentially inaccurate does estimates for experiments using microbeams or microcrystals. We present an extension to RADDOSE-3D which performs Monte Carlo simulations of a rotating crystal during MX data collection, taking into account the redistribution of photoelectrons produced both in the sample and the material surrounding the crystal. As well as providing more accurate dose estimates, the Monte Carlo simulations highlight the importance of the size and composition of the surrounding material on the dose and thus the rate of radiation damage to the sample. Minimizing irradiation of the surrounding material or removing it almost completely will be key to extending the lifetime of microcrystals and enhancing the potential benefits of using higher incident X-ray energies.