0.05).Conclusion In-vitro-cultured CB has good effects in the treatment of apoplexy.Neither in-vitro-cultrued CB nor natural CB for apoplexy has obvious adverse reaction.

Objective To observe the clinical efficacy of dynamic joint mobilization combined with core stability training in the treatment of nonspecific low back pain.Methods 60 patients with nonspecific low back pain were randomly assigned into either the treatment group or control group.Each group had 30 patients.The treatment group received a therapeutic regimen combining dynamic joint mobilization and core stability training,while the control group only received core stability training.Both groups were evaluated for therapeutic effectiveness using the Visual Analogue Scale(VAS)for pain,the Oswestry Disability Index(ODI),and the range of motion(ROM)of the lumbar spine before treatment,and at the 1st,3rd,and 6th weeks after treatment.At the conclusion of the treatment,a thorough assessment of the overall therapeutic efficacy was performed.Results At the 1st,3rd,and 6th weeks post-treatment,both groups showed statistically significant differences in VAS scores,ODI scores,and ROM scores over time(P＜0.05).The improvements in these indices were significantly greater in the treatment group compared to the control group(P＜0.05).The treatment group had considerably higher therapeutic effective-ness compared to the control group(P＜0.05).Conclusions Dynamic joint mobilization combined with core stabil-ity training is effective in treating nonspecific low back pain.It can help with pain relief,lumbar and back function restoration,and lumbar and back mobility improvement.This approach is worthy of clinical application and promotion.

In maintaining normal function and activation processes, glycolysis, lipid metabolism, and amino acid metabolism play key roles in the energy demand of platelets. In the resting state, platelets primarily rely on glycolysis and aerobic oxidation to generate energy. Upon activation, platelets preferentially utilize glycolysis, as it can more rapidly provide the required ATP. In addition to glycolysis, platelets can also utilize glycogen and fatty acids as additional energy sources. The ATP provided by fatty acid oxidation is crucial for platelet activation. Additionally, during platelet storage, distinctive changes in energy metabolism occur. In the early stages of storage, platelets primarily rely on glycolysis and the pentose phosphate pathway (PPP) to generate energy. In the mid-storage phase, there is an increase in tricarboxylic acid cycle (TCA) metabolism. In the later stages of storage, cellular metabolism gradually declines. The regulation and flexibility of these metabolic pathways play a critical role in the survival and function of platelets in different states.