Mafenide derivatives inhibit neuroinflammation in Alzheimer's disease by regulating pyroptosis.

The main mechanism of pyroptosis is Caspase-1-mediated GSDMD cleavage, and GSDMD is also the executive protein of pyroptosis. Our previous study has shown that mafenide can inhibit pyroptosis by inhibiting the GSDMD-Asp275 site to suppress cleavage. In this study, sulfonamide was used as the parent nucleus structure to synthesize sulfa-4 and sulfa-20. Screening of drug activity in the pyroptosis model of BV2 and iBMDM cell lines revealed the efficacy of five compounds were superior to mafenide, which exerted a better inhibitory effect on the occurrence of pyroptosis. For in vivo assay, Sulfa-4 and Sulfa-22 were intervened in the neuroinflammation APP/PS1 mice. As a result, the administration of Sulfa-4 and Sulfa-22 could significantly inhibit the activation of microglia, decrease the expression of inflammatory factors in the central nervous system and simultaneously suppress the production of p30-GSDMD as well as the expression of upstream NLRP3 inflammasome and Caspase-1 protein. Immunoprecipitation and Biotin-labelled assay confirmed the targeted binding relationship of Sulfa-4 and Sulfa-22 with GSDMD protein in the iBMDM model in vitro. In this study, we investigated a new type inhibitor of GSDMD cleavage, which exerted a good inhibitory effect on pyroptosis and provided new references for the development of inflammatory drugs in the future.

Thermal stability of mafenide and amphotericin B topical solution.

OBJECTIVE: Fungal infections remain a major cause of mortality in the burned population. Mafenide acetate/amphotericin B solution (SMAT) has been used topically for prophylaxis and treatment of these infections. Current manufacturer guidelines only guarantee the stability of mafenide solution and amphotericin B at room temperature. Additionally, the recommended maximum storage time for mafenide solution is 48h, leading to significant financial and material loss when unused solutions are discarded. The purpose of this study was to characterize the chemical stability, structure and bioactivity of SMAT stored at 2°C, 25°C, and 40°C for up to 90 days. METHODS: Stability analyses of SMAT solutions containing 2.5% or 5% mafenide plus 2µg/mL amphotericin B were performed using high performance liquid chromatography. Chemical structure was assessed using Fourier-transform infrared spectroscopy. Bioactivity against clinically relevant species was examined. RESULTS: The chemical structure and stability of mafenide did not change over 90days at all temperatures. Amphotericin B was undetectable in SMAT solutions after two days at high temperatures, which was slowed by refrigerated storage. Against Staphylococcus aureus, SMAT activity began to decrease generally between two and seven days. Against Pseudomonas aeruginosa, activity slowly tapered and was gone by day 90. SMAT retained high bioactivity against Candida albicans for over 40days and was not affected by temperature. CONCLUSIONS: The amphotericin B component of SMAT is degraded within 2days under warm storage. While mafenide was stable over 90 days, the bioactivity of SMAT solution may be lost within 2days as well.

Vibrational analyses of sulfamoyl halides NH2SO2X (X is F, Cl and Br).

The structural stability of sulfamoyl halides NH(2)-SO(2)X (X is F, Cl and Br) were investigated by DFT-B3LYP/6-311+G** and ab initio MP2/6-311+G** calculations. From the calculations the molecules were predicted to exist only in the anti (XS bond is anti with respect to nitrogen lone pair) conformation with the possibility of very low abundance of the syn (SO(2) and NH(2) groups eclipse each other) form of only the fluoride. The equilibrium constant for the syn<-->anti conformational conversion of sulfamoyl fluoride was calculated to be 0.0172 that corresponds to an equilibrium mixture of about 2% syn and 98% anti at 298.15K. The vibrational frequencies were computed at DFT-B3LYP level for the stable anti conformer of the d(0) and d(2) (ND(2)-SO(2)X) deuterated species of the three molecules. Normal coordinate calculations were then carried out and the potential energy distributions were calculated for the molecules.

Risk of aluminum accumulation in patients with burns and ways to reduce it.

Severely burned patients experience a bone lesion consisting of markedly reduced bone formation and evidence of decreased resportion. The cause of the lesion may be multifactorial, but aluminum loading, which also occurs in patients with burns, has been documented to produce this type of injury in both humans and animals. To assess the risk of aluminum loading with patients with burns, we analyzed fluids, creams, and medication used in the management of acute burn injury for aluminum content. These substances were classified according to route of administration: cutaneous, enteral, or parenteral, to assess the risk of aluminum loading. Cutaneous exposure to aluminum is greatest from baths, which may provide up to 8 mg aluminum. However, the dynamics of aluminum entry into the blood via a damaged skin barrier are unclear. Enteral exposure to aluminum is no greater than daily dietary exposure. Parenteral sources of aluminum, especially 25% human serum albumin and calcium gluconate, provide the most significant risk of loading because of direct introduction of aluminum into the circulation. Substitution with a different brand of albumin and calcium chloride can reduce the parenteral aluminum load by as much as 95% and minimize any role aluminum may play in the pathogenesis of this bone lesion.