Interaction between fasudil hydrochloride and bovine serum albumin: spectroscopic study

Fabrication of fasudil hydrochloride modified graphene oxide biocomposites and its defensive effect acute renal injury in septicopyemia rats

This investigation aspired to the impacts of intraperitoneal injection of suspended graphene oxide-bovine serum albumin (GO-BSA) biocomposite blended in fasudil (FSD)-against intense renal damage in septicopyemia rodent's models. It was picked a model of acute renal injury by an intraperitoneal organization of fasudil. Our outcomes demonstrated that few markers of renal capacity, for example, blood urea nitrogen (BUN), creatinine (SC), and intratubular waste levels were altogether diminished essentially in fasudil blended GO-BSA intraperitoneally infusion groups during the first week, showing that GO-BSA has an uncommon ability to ensure FSD discharges. Additionally, surprisingly, while rats got GO-BSA intraperitoneally, biomedical examination demonstrated the fruitful decrease of blood urea nitrogen and creatinine blood factors showing that GO-BSA has an uncommon ability alone to repair the acute renal injury. It appears that GO-BSA can adsorb ECM proteins and encourages their exchange to the intense renal damage tissue and expands its repair speed, in addition, GO-BSA ensures the FSD and along these lines the helpful adequacy of the FSD in intense renal damage enhanced by the grip of living cells to GO-BSA biocomposites. It could be inferred that GO-BSA material improves the rate of achievement of FSD conveys in intense renal damage in septicopyemia animals.

A comparative study on intrinsic fluorescence of BSA and lysozyme proteins in presence of different divalent ions from their solution and thin film conformations

Optical emission behaviours of lysozyme and bovine serum albumin, from bulk and thin film geometry, were studied in the presence of three different divalent ions (Mg²⁺ , Ca²⁺ or Ba²⁺ ) using different spectroscopic [steady-state fluorescence, UV-Vis and Fourier transform infra-red (FTIR)] techniques. Additionally, protein thin films on silicon surfaces were prepared and morphological studies were carried out using atomic force microscopy. Dynamic quenching was mainly identified for both proteins in the presence of Mg²⁺ , Ca²⁺ and Ba²⁺ ions. The molecular conformation of the proteins was modified in thin films compared with that in solution, consequently quenching efficiencies also varied. ATR-FTIR studies confirmed the conformational changes of proteins in the presence of all divalent ions. All metal ions used were divalent in nature and belonged to the same group of the periodic table but, depending on their individual characteristics such as electron affinity, ionic radius, etc., the magnitude of the protein and hydrated ion interaction varied and accordingly the quenching efficiency was modified. Quenching was maximum for Ca²⁺ ions, followed by the other two ions. Our study clearly illustrates the geometry-dependent physical and biological functions of proteins.