Optimization of photo-biomodulation therapy for wound healing of diabetic foot ulcers in vitro and in vivo.

Unclear optical parameters make photo-biomodulation (PBM) difficult to implement in diabetic foot ulcer (DFU) clinically. Here, 12 wavelengths (400-900 nm) were used to conduct PBM to heal DFU wounds in vitro and in vivo. PBM at 10 mW/cm2 and 0.5-4 J/cm2 with all 12 wavelengths promoted proliferation of diabetic wound cells. In a mimic DFU (mDFU) rat model, PBM (425, 630, 730, and 850 nm, and a combination light strategy) promoted mDFU healing. The positive cell proliferation, re-epithelialization, angiogenesis, collagen synthesis, and inflammation were possible mechanisms. The combination strategy had the best effect, which can be applied clinically.

Effects of the Tibetan medicine Byur dMar Nyer lNga Ril Bu on Alzheimer's disease in mice models.

ETHNOPHARMACOLOGICAL RELEVANCE: Byur dMar Nyer lNga Ril Bu (BdNlRB) is a classic Tibetan medicine prescription for treating " white vein disease". Alzheimer's disease (AD) is a chronic degenerative disease of the central nervous system, characterized by distinct "white vein disease". In the absence of effective drugs for AD, BdNlRB may be a possible treatment for AD. AIM OF THE STUDY: To verify the therapeutic effect and possible mechanism of the proved Tibetan medicine BdNlRB on Alzheimer's disease. MATERIALS AND METHODS: 60 APP/PS1 double transgenic AD mice (Mt) and 60 Aß1-40 protein-induced AD mice (Mi) were divided into 3 groups according to the dose of BdNlRB: BdNlRB-100, BdNlRB-200 and BdNlRB-400, with 100, 200 and 400 mg/kg*weight, respectively. The mice were administrated by gavage for 8 weeks. The cognitive ability of mice was detected by Morris Water Maze, the expression of Aß protein, p-tau and microglia was detected by immunofluorescent staining, the protein expression in the hippocampus was detected by proteomics, and the abundance of fecal intestinal flora was detected by 16S RNA. RESULTS: The learning ability and memory ability of Mi mice were significantly improved after BdNlRB administration. The learning ability of Mt mice was significantly improved, while the memory ability was not improved after BdNlRB administration. After the treatment with low and medium doses of BdNlRB, the expression of p-tau decreased significantly (the rate of decrease in BdNlRB-100 and BdNlRB-200 groups was 8.05% and 12.7%, respectively), and the number of microglia increased (39.3% and 31.6%, respectively). BdNlRB significantly affected the protein expression in the hippocampus of Mt mice. 382 proteins in different expression in all three groups mainly involved in amino acid synthesis, fatty acid degradation, glutamine metabolism, synaptic vesicular cycle and oxidative phosphorylation, PPAR signaling pathway and Fc gamma-mediated phagocytosis were activated. Meanwhile, the administration of BdNlRB can regulate the intestinal flora of Mt mice, which reduces the abundance of Muribaculum and uncultured bacteroidales bacterium, and improves the abundance of Ruminococcus-1 and Ruminiclostridium-9. CONCLUSION: The oral administration of BdNlRB significantly improved the cognitive ability of AD mice, and neuroinflammation and intestinal flora regulation were the possible mechanisms.

Gut flora-targeted photobiomodulation therapy improves senile dementia in an Aß-induced Alzheimer's disease animal model.

BACKGROUND: Emerging evidence suggests that the gut microbiota plays an important role in the pathological progression of Alzheimer's disease (AD). Photobiomodulation (PBM) therapy is believed to have a positive regulatory effect on the imbalance of certain body functions, including inflammation, immunity, wound healing, nerve repair, and pain. Previous studies have found that the intestinal flora of patients with AD is in an unbalanced state. Therefore, we have proposed the use of gut flora-targeted PBM (gf-targeted PBM) as a method to improve AD in an Aß-induced AD mouse model. METHODS: PBM was performed on the abdomen of the mice at the wavelengths of 630 nm, 730 nm, and 850 nm at 100 J/cm2 for 8 weeks. Morris water maze test, immunofluorescence and proteomic of hippocampus, and intestinal flora detection of fecal were used to evaluate the treatment effects of gf-targeted PBM on AD rats. RESULTS: PBM at all three wavelengths (especially 630 nm and 730 nm) significantly improved learning retention as measured by the Morris water maze. In addition, we found reduced amyloidosis and tau phosphorylation in the hippocampus by immunofluorescence in AD mice. By using a quantitative proteomic analysis of the hippocampus, we found that gf-targeted PBM significantly altered the expression levels of 509 proteins (the same differentially expressed proteins in all three wavelengths of PBM), which involved the pathways of hormone synthesis, phagocytosis, and metabolism. The 16 s rRNA gene sequencing of fecal contents showed that PBM significantly altered the diversity and abundance of intestinal flora. Specifically, PBM treatment reversed the typical increase of Helicobacter and uncultured Bacteroidales and the decrease of Rikenella seen in AD mice. CONCLUSIONS: Our data indicate that gf-targeted PBM regulates the diversity of intestinal flora, which may improve damage caused by AD. Gf-targeted PBM has the potential to be a noninvasive microflora regulation method for AD patients.

Deep proteome profiling of SW837 cells treated by photodynamic therapy (PDT) reveals the underlying mechanisms of metronomic and acute PDTs.

AIM: Metronomic photodynamic therapy (mPDT) with a longer irradiation time and lower energy compared with acute (or classic) photodynamic therapy (aPDT) is a more effective treatment than aPDT for tumor cells, especially colorectal cancer. However, the underlying mechanisms of the superior effects of mPDT are unknown. METHODS: we used SWATH-MS (sequential window acquisition of all theoretical mass spectra) to identify differentially expressed proteins (DEPs) specific to aPDT (conventional fluence rate, 20 mW/cm2, 4 min 10 s), mPDT (metronomic fluence rate, 0.4 mW/cm2, 3.5 h), and control groups of SW837 cells. The photosensitizer used in both PDT methods was aminolevulinic acid which were incubated with the cells before irradiation. RESULTS: A total of 6805 proteins were identified in the three groups of SW837 cells. aPDT induced 333 DEPs and mPDT induced 1716 DEPs compared with the control. We identified 185 common DEPs in the two PDT groups, 148 different DEPs in the aPDT group, and 1531 different DEPs in the mPDT group. Most of the 185 common DEPs were involved in the extracellular component, participated in the processes of vesicle transport and secretion, binding, and hydrolase/catalytic activity. They were also involved in PI3K-Akt, cGMP-PKG, RAS, and aAMP signaling pathways. In addition, the 1531 different DEPs in the mPDT group participated in similar processes and molecular functions, but in a more complex manner than those in the aPDT group. CONCLUSION: our proteome data suggest that mPDT has a complex tumor destruction mechanism with more involved proteins compared with aPDT, which may explain the better tumor killing effect of mPDT.