Lipocalin-2 (LCN2), a member of the human lipocalin family, has been demonstrated to be closely associated with diabetes, cardiovascular diseases, and renal disorders. Recent studies have indicated that LCN2 plays a significant regulatory role in the pathogenesis and progression of various neurological diseases by mediating pathways such as inflammation, oxidative stress, and ferroptosis. This article reviews the research advancements on the mechanism of LCN2 in neurological disorders, including cerebrovascular diseases, cognitive impairment disorders, Parkinson's disease, depression, and anxiety disorders, aiming to enhance clinical understanding.

Clinical management of atopic dermatitis (AD) is challenged by its susceptibility to recurrence, side effects, and high costs. We found that Portulaca oleracea L.-derived nanovesicles (PDNV) exert anti-inflammatory effects by modulating macrophage M1/M2 polarization. These effects were achieved through pathways including inhibition of nuclear factor-κB (NF-κB) and stimulator of interferon genes (STING) protein expression in diseased tissues, demonstrating their potential to ameliorate AD symptoms. To increase the transdermal permeation of PDNV, dissolvable microneedles composed primarily of hyaluronic acid (HA) were developed as an adjunctive means of delivery. Meanwhile, polysaccharides of Portulaca oleracea L., which were synergistic with PDNV, were used as microneedle constituent materials to enhance the mechanical properties and physical stability of HA. This new means of delivery significantly improves the treatment of AD and also provides new options for the efficient utilization of plant extracellular vesicles and the treatment of AD. In addition, transcriptomic analysis of PDNV showed that the mRNAs of Portulaca oleracea L. are closest to those of ferns, which may shed light on related evolutionary and plant species identification studies.

Objective Virtual reality(VR)technology is closely related to eye vision.With the development and progress of hardware and software equipment,VR has been applied widely in the field of ophthalmology.This article describes the application of VR technology in the clinical research and ophthalmology education,reviews the current research results and advantages of this new technology,including the new curative effect in amblyopia/strabismus,myopia and glaucoma,as well as research on the technology's application in cataract surgery training and ophthalmology education.The article also discusses the dangers and difficulties of VR application and predicts its future application trend.In view of the shortcomings of VR in current research applications,the paper discusses and looks forward to provide powerful strategies for amblyopia,myopia and other ophthalmic diseases and clinical research.

Objective To propose a method for optimizing the design of diabetic foot insoles by combining the elastic modulus and thickness of footwear to reduce plantar pressure and internal stress in soft tissues.Methods A finite element model of The foot was established using reverse engineering techniques.Orthotic pressure regions were identified based on the characteristics of plantar pressure distributions.Contact mechanics were studied using the finite element method to lay the foundation for adjusting the elastic modulus of the materials and the thickness of the forefoot and rearfoot insoles in different regions during the optimization process.The optimal parameter combination was obtained using an optimal Latin hypercube design.Results The plantar contact area of the designed insole increased by approximately 37.55％,and the peak pressures in the metatarsal and heel regions were reduced by 15.07％and 36.96％,respectively.The internal stress in the soft tissues of the heel decreased by 20.83％.Tension in the plantar fascia decreased by 60％.Conclusions The proposed method can be used for designing customized insoles,and such designed personalized insoles have a greater contact area,with great potential in reducing diabetic foot ulcers.