Effectiveness of static, dynamic and combined dry needling techniques in the management of myofascial pain syndrome: A three-group study.

Objectives: This study aims to evaluate and compare the therapeutic effectiveness of static dry needling (S-DN), dynamic dry needling (D-DN), and a combined technique (CT) for managing myofascial pain syndrome (MPS).

Patients And Methods: Between January 1, 2023 and April 15, 2023, a total of 38 patients (9 males, 29 females; mean age: 40.5±12.

Tripolyphosphate-functionalized cellulose: A green solution for cadmium contamination.

This study introduces a highly efficient tripolyphosphate -tethered cellulose sorbent for cadmium (Cd⁺) removal from aqueous solutions. Characterization through FTIR and SEM revealed the material's structural properties. The sorbent achieved 99% Cd⁺ removal even at a minimal dosage of 0.

Removal of manganese (Mn) from water samples using a biocomposite sorbent.

Herein, tannic acid-tethered cellulose was developed as an efficient and selective sorbent for Mn⁺ removal from aqueous solutions. The modified cellulose was characterized through scanning electron microscopy, infrared spectroscopy, and elemental analyses. Sorption performance was evaluated using various parameters, including pH, initial Mn⁺ concentration, contact time, and the presence of interfering ions.

Separation of Boron and Arsenic from Geothermal Water with Novel Gel-Type Chelating Ion Exchange Resins: Batch and Column Sorption-Elution Studies.

In this research, the removal of boron and arsenic from geothermal water was examined by using novel -methyl-d-glucamine functionalized gel-like resins (abbreviated as 1JW and 2JW) synthesized by the membrane emulsification method. The outcomes were compared with those of commercially available boron selective chelating ion exchange resin (Diaion CRB 05). According to the results obtained with the novel resins, it was possible to reduce both boron and arsenic concentrations in geothermal water by using these novel gel-like chelating resins below their permissible levels for agricultural irrigation (<1 mg B/L) and drinking water (<0.

Removal of bromate ions from aqueous solutions via electrodeionization.

Bromate (BrO) is a disinfection byproduct formed during the chemical oxidation of water containing bromide. Due to the carcinogenic effect of bromate, its maximum permissible concentration in drinking water has been set to 10 μg/L by the World Health Organization. In this study, the removal of BrO ions from aqueous solutions via electrodeionization (EDI) was investigated.