Effectiveness of chitosan phonophoresis on ulnar nerve conduction velocity, pain relief, and functional outcomes for mild to moderate cubital tunnel syndrome: A double-blind randomized controlled trial.

BACKGROUND: Cubital tunnel syndrome (CBTS) impairs hand function, with limited conservative options often leading to surgery. Chitosan neuroregenerative effects delivered via phonophoresis provide a rationale for testing this emerging treatment approach. PURPOSE: The primary goal of this research was to assess the impact of chitosan phonophoresis on the conductivity of the ulnar nerve, as well as its effects on pain levels and functional outcomes in individuals diagnosed with mild to moderate CBTS. STUDY DESIGN: Double-blind randomized controlled trial. METHODS: This was a prospective, double-blinded, randomized controlled study. The participants consisted of 54 individuals aged between 20-35 years who were randomly assigned using block randomization. The control group (n = 27) received standard hand therapy alone, while the experimental group (n = 27) received both standard hand therapy and chitosan phonophoresis. Both groups underwent three treatment sessions per week, each lasting for 60-72 minutes, over a period of five weeks. Pre- and post-intervention evaluations included assessments of ulnar nerve conduction velocity (NCV), pain assessment using the numerical pain rating scale (NPRS), as well as hand function evaluated using the Quick Disabilities of Arm Shoulder Hand (QuickDASH) questionnaire. RESULTS: After the intervention, the experimental group significantly improved in all outcome measures compared to the control group. Accordingly, ulnar NCV (MD = 2.233 m/sec; CI = 1.63:2.83; p < 0.001; η2p = 0.516), NPRS (MD = -1.11; CI = -1.71: -0.50; p < 0.001; η2p = 0.208) and QuickDASH (MD = -2.72; CI = -4.54:0.87; p < 0.007; η2p = 0.133). CONCLUSIONS: The study findings suggest that chitosan phonophoresis may have the potential as a supplementary treatment to hand therapy for individuals with mild to moderate CBTS. This approach demonstrated significant improvements in nerve conduction, pain reduction, and enhancement of hand function.

Unraveling the influence of solvent composition on Drop-on-Demand binder jet 3D printed tablets containing calcium sulfate hemihydrate.

Recently, binder jet printed modular tablets were loaded with three anti-viral drugs via Drop on Demand (DoD) technology where drug solutions prepared in ethanol showed faster release than those prepared in water. During printing, water is used as a binding agent, whereas ethanol is added to maintain the porous structure of the tablets. Thus, the hypothesis is that the porosity would be controlled by manipulating the percentage of water and ethanol. In this study, Rhodamine 6G (R6G) was selected as a model drug due to its high solubility in water and ethanol, visualization function as a fluorescent dye, and potential therapeutic effects for cancer treatment. Approximately, 10 mg/ml R6G solutions were prepared with five different water-ethanol ratios (0-100, 75-25, 50-50, 75-25, 100-0). The ink solutions were printed onto blank binder jet 3D-printed tablets containing calcium sulphate hemihydrate using DoD technology. The tablets were dried at room temperature and then characterized using SEM-EDX, fluorescent microscope, TGA, XRD, FTIR, and DSC as well as in vitro release studies to investigate the impact of water-ethanol ratio on the release profile of R6G. Results indicated that the solution with higher ethanol ratio penetrated the tablets faster than the lower ethanol ratio, while the solution prepared with pure water was first accumulated onto the tablets' surface and then absorbed by the tablets. Moreover, tablets with more water content gained more weight and thickness. The EDX analysis and fluorescent microscope showed the uniform surface distribution of the drug. The SEM images revealed the difference in the tablet surface among the five formulations. Furthermore, the TGA data presents a notable increase in water loss, with XRD analysis suggesting the formation of gypsum in tablets containing elevated water content. The release study exhibited that the fastest release was from WE0-100, whereas the release rate decreases as the content of water increases. The WE0-100 releases more than 40 % drug within the first hour which is almost twice as high of the WE100-0 formulation. This DoD technology could distribute drugs onto the tablet's surface uniformly. The calcium sulfate would transform from hemihydrate to dihydrate form in the presence of water and therefore, those tablets treated with higher water content led to slower release. In conclusion, this study underscores the substantial impact of the water-ethanol ratio on drug release from binder jet printed tablets and highlights the potential of DoD technology for uniform drug distribution and controlled release.

Novel long-acting brimonidine tartrate loaded-PCL/PVP nanofibers for versatile biomedical applications: fabrication, characterization and antimicrobial evaluation.

The global state of antibiotic resistance highlights the necessity for new drugs that can treat a wide range of microbial infections. Drug repurposing has several advantages, including lower costs and improved safety compared to developing a new compound. The aim of the current study is to evaluate the repurposed antimicrobial activity of Brimonidine tartrate (BT), a well-known antiglaucoma drug, and to potentiate its antimicrobial effect by using electrospun nanofibrous scaffolds. BT-loaded nanofibers were fabricated in different drug concentrations (1.5, 3, 6, and 9%) via the electrospinning technique using two biopolymers (PCL and PVP). Then, the prepared nanofibers were characterized by SEM, XRD, FTIR, swelling ratio, and in vitro drug release. Afterward, the antimicrobial activities of the prepared nanofibers were investigated in vitro using different methods against several human pathogens and compared to the free BT. The results showed that all nanofibers were prepared successfully with a smooth surface. The diameters of nanofibers were reduced after loading of BT compared to the unloaded ones. In addition, scaffolds showed controlled-drug release profiles that were maintained for more than 7 days. The in vitro antimicrobial assessments revealed good activities for all scaffolds against most of the investigated human pathogens, particularly the one prepared with 9% BT which showed superiority in the antimicrobial effect over other scaffolds. To conclude, our findings proved the capability of nanofibers in loading BT and improving its repurposed antimicrobial efficacy. Therefore, it could be a promising carrier for BT to be used in combating numerous human pathogens.

Dissolution enhancement of olmesartan medoxomil through polymer-based surface solid dispersion and solidified surfactant techniques.

This study aims to formulate Olmesartan medoxomil (OM) into oral fast-dissolving tablets (FDTs) to improve its solubility and bioavailability via two different techniques; The polymer-based surface solid dispersion (SSD) technique and the solidified surfactant (SS) technique. In the first technique, two polymers were used; polyvinylpyrrolidone (PVP K90) and Poloxamer 407 (Pluronic®F127), while in the second technique the liquid Tween 80 was solidified by adsorption onto Aeroperl®300. The pre-compression and post-compression parameters of the obtained formulations were assessed. The best formulations were subjected to a taste masking evaluation and a short-term stability study. The results demonstrated that, in comparison to the pure drug, the proportion of drug released from each of the prepared FDTs considerably increased. Results of the stability studies showed that the chosen drug formulations remained stable throughout the storage period.