Trauma-informed care is a model of care in which healthcare professionals implement targeted interventions based on fully understanding of patients' trauma experiences, aiming to reduce psychological trauma symptoms, prevent re-traumatization, and improve health outcomes. Since the introduction of this concept, it has been applied in various fields, including medical education, mental health, obstetrics, and emergency care. The implementation of trauma-informed care requires targeted education and training for healthcare professionals; however, there is currently insufficient understanding of trauma-informed care among these professionals. Additionally, there are significant variations in the scope, content, model, and effectiveness of trauma-informed care education. This study aims to review the existing state of trauma-informed care education internationally, identify current research hotspots and shortcomings, and provide references for the future design and implementation of trauma-informed care education in China.

OBJECTIVE: To review the research progress of three-dimensional (3D) bioprinting technology for wound dressing design and preparation. METHODS: The literature on 3D bioprinted wound dressings in recent years, both domestically and internationally, was retrieved. The core principles of 3D bioprinting technology, mainstream methods, and their applications in wound dressings design and preparation were summarized. RESULTS: By leveraging precise spatial manipulation capabilities and multi-material integration, 3D bioprinting technology constructs the functionalized wound dressings with complex structures and bioactivity. These dressings primarily function across several dimensions: wound hemostasis, infection control, controlled drug release, and monitoring wound healing. CONCLUSION Although 3D bioprinted wound dressings can promote wound healing through multiple dimensions, large-scale clinical validation is still lacking. Future efforts should further clarify their clinical value and scope of application to provide more efficient, precise, and patient-comfortable treatment options for refractory wounds .
Humans ; Wound Healing ; Printing, Three-Dimensional ; Bioprinting/methods* ; Bandages ; Tissue Engineering/methods* ; Tissue Scaffolds ; Biocompatible Materials

BACKGROUND:In previous studies,the equivalent structure of three-dimensional cell reconstruction of tissue engineering oral mucosa is similar to normal oral mucosa,including epithelial-like structure,lamina propria-like structure,and vascular lumen-like structure,and has initially achieved the establishment of vascular equivalent,but its vascularization characteristics are not very clear.OBJECTIVE:Vascular-like structures of vascularized oral mucosa equivalent were obtained by targeting vascular endothelial cells specific marker expression profiles correlated with laser capture microdissection system,and their vascularization ability was evaluated to reveal their vascularization characteristics.METHODS:Human gingival epithelial cells were cultured from human gingival epithelium and human gingival fibroblasts,human gingival mesenchymal stem cells were cultured from human gingival lamina propria.Human gingival mesenchymal stem cells were induced to differentiate into vascular endothelial-like cells after monoclonal expansion culture.Human gingival epithelial cells,human gingival fibroblasts,and vascular endothelial-like cells were loaded with acellular vascular matrix-0.25%human-like collagen type Ⅰ scaffold to construct the vascularized oral mucosa equivalent.The layered structure of oral mucosa equivalent(experimental group)and the acellular vascular matrix-0.25%human-like collagen type Ⅰ scaffold(control group)were implanted subcutaneously into the back of nude mice,respectively.14 days later,the incision surface of the two groups was coated with biogel.The biogel surface of the experimental group was inoculated with human gingival epithelial cells,while the control group was not inoculated with cells.The samples were collected after 14 days of feeding.The layered structure of oral mucosa equivalent was observed by morphology.The neovascular-like structures in oral mucosa equivalents were labeled by immunohistochemistry and immunofluorescence with a more comprehensive expression profile of vascular endothelial cells,and the vascularization characteristics were analyzed.A laser capture microdissection system was used to capture the neovascularization structures in the oral mucosa equivalents specifically labeled by immunohistochemistry and analyze their vascularization characteristics.RESULTS AND CONCLUSION:(1)The morphology showed that the cell level of oral mucosa equivalent was clear,and the structure was similar to that of normal oral mucosa,that is,there were epithelioid structures,lamina-like structures,and vascular cavelike structures,and there were scattered erythrocytes in the vascular cavelike structures.(2)The results of EdU Apollo tracer seed cells in the oral mucosa equivalent group showed that human gingival epithelial cells labeled with EdU Apollo 488 showed green fluorescence expression.DAPI labeled human gingival fibroblasts showed blue fluorescence expression and formed lamina-like structures in vivo.EdU Apollo 567 labeled vascular endothelial-like cells showed red fluorescence expression and formed a vascular-like structure in vivo.(3)Vascular endothelial cell specific marker expression profile immunofluorescence labeling of vascular structure showed that compared with normal oral mucosa,the expressions of CD31,CD51,CD54,CD105,Tie-2,VWF,vascular endothelial growth factor receptor 1,and vascular endothelial growth factor receptor 2 in oral mucosa equivalents were increased(P<0.000 1).There were no significant changes in CD34 expression(P>0.05).(4)Compared with the specifically labeled oral mucosal vascular structures,the expression levels of CD51,CD54,CD105,Tie-2,VWF,vascular endothelial growth factor receptor 1,and vascular endothelial growth factor receptor 2 of the oral mucosa equivalents targeted by the laser capture microdissection system were increased(P<0.000 1).There were no significant changes in expression of CD31 and CD34(P>0.05).(5)The results showed that the oral mucosa equivalent reconstructed by three-dimensional cell stratification could achieve good vascularization,and its vascularization characteristics were consistent with the immunological function and characteristics of neovascularization.Vascularization helps three-dimensional cell layer reconstruction of oral mucosa equivalent regeneration.

Trauma-informed care is a model of care in which healthcare professionals implement targeted interventions based on fully understanding of patients' trauma experiences, aiming to reduce psychological trauma symptoms, prevent re-traumatization, and improve health outcomes. Since the introduction of this concept, it has been applied in various fields, including medical education, mental health, obstetrics, and emergency care. The implementation of trauma-informed care requires targeted education and training for healthcare professionals; however, there is currently insufficient understanding of trauma-informed care among these professionals. Additionally, there are significant variations in the scope, content, model, and effectiveness of trauma-informed care education. This study aims to review the existing state of trauma-informed care education internationally, identify current research hotspots and shortcomings, and provide references for the future design and implementation of trauma-informed care education in China.

BACKGROUND:In previous studies,the equivalent structure of three-dimensional cell reconstruction of tissue engineering oral mucosa is similar to normal oral mucosa,including epithelial-like structure,lamina propria-like structure,and vascular lumen-like structure,and has initially achieved the establishment of vascular equivalent,but its vascularization characteristics are not very clear.OBJECTIVE:Vascular-like structures of vascularized oral mucosa equivalent were obtained by targeting vascular endothelial cells specific marker expression profiles correlated with laser capture microdissection system,and their vascularization ability was evaluated to reveal their vascularization characteristics.METHODS:Human gingival epithelial cells were cultured from human gingival epithelium and human gingival fibroblasts,human gingival mesenchymal stem cells were cultured from human gingival lamina propria.Human gingival mesenchymal stem cells were induced to differentiate into vascular endothelial-like cells after monoclonal expansion culture.Human gingival epithelial cells,human gingival fibroblasts,and vascular endothelial-like cells were loaded with acellular vascular matrix-0.25%human-like collagen type Ⅰ scaffold to construct the vascularized oral mucosa equivalent.The layered structure of oral mucosa equivalent(experimental group)and the acellular vascular matrix-0.25%human-like collagen type Ⅰ scaffold(control group)were implanted subcutaneously into the back of nude mice,respectively.14 days later,the incision surface of the two groups was coated with biogel.The biogel surface of the experimental group was inoculated with human gingival epithelial cells,while the control group was not inoculated with cells.The samples were collected after 14 days of feeding.The layered structure of oral mucosa equivalent was observed by morphology.The neovascular-like structures in oral mucosa equivalents were labeled by immunohistochemistry and immunofluorescence with a more comprehensive expression profile of vascular endothelial cells,and the vascularization characteristics were analyzed.A laser capture microdissection system was used to capture the neovascularization structures in the oral mucosa equivalents specifically labeled by immunohistochemistry and analyze their vascularization characteristics.RESULTS AND CONCLUSION:(1)The morphology showed that the cell level of oral mucosa equivalent was clear,and the structure was similar to that of normal oral mucosa,that is,there were epithelioid structures,lamina-like structures,and vascular cavelike structures,and there were scattered erythrocytes in the vascular cavelike structures.(2)The results of EdU Apollo tracer seed cells in the oral mucosa equivalent group showed that human gingival epithelial cells labeled with EdU Apollo 488 showed green fluorescence expression.DAPI labeled human gingival fibroblasts showed blue fluorescence expression and formed lamina-like structures in vivo.EdU Apollo 567 labeled vascular endothelial-like cells showed red fluorescence expression and formed a vascular-like structure in vivo.(3)Vascular endothelial cell specific marker expression profile immunofluorescence labeling of vascular structure showed that compared with normal oral mucosa,the expressions of CD31,CD51,CD54,CD105,Tie-2,VWF,vascular endothelial growth factor receptor 1,and vascular endothelial growth factor receptor 2 in oral mucosa equivalents were increased(P<0.000 1).There were no significant changes in CD34 expression(P>0.05).(4)Compared with the specifically labeled oral mucosal vascular structures,the expression levels of CD51,CD54,CD105,Tie-2,VWF,vascular endothelial growth factor receptor 1,and vascular endothelial growth factor receptor 2 of the oral mucosa equivalents targeted by the laser capture microdissection system were increased(P<0.000 1).There were no significant changes in expression of CD31 and CD34(P>0.05).(5)The results showed that the oral mucosa equivalent reconstructed by three-dimensional cell stratification could achieve good vascularization,and its vascularization characteristics were consistent with the immunological function and characteristics of neovascularization.Vascularization helps three-dimensional cell layer reconstruction of oral mucosa equivalent regeneration.

Currently, the management of domestic laboratory developed test (LDT) is still in the exploration stage, and new plans and ideas need to be investigated that are suitable for our national development. By analyzing encountered issues, combining the actual needs of the government, healthcare reform, and patients, this article proposes that "promoting healthy development of LDT projects and focusing on the organic combination of patients′ interest protection and innovation support" is an important direction for LDT management, around which the new idea for LDT project management is proposed, that is, LDT management model targeting product registration. The core of this management model is to target product registration and to ensure low service fees for patients and continuous real-time data monitoring. Benefit and risk analysis demonstrate that this management model can to a larger extent balance the realistic demands of patients, medical institutions, in vitro diagnostics companies, and government management departments, which benefits promoting the perfection and development of LDT projects in our country.

Blood glucose fluctuation leads to poor bone defect repair in patients with type 2 diabetes(T2DM).Strategies to safely and efficiently improve the bone regeneration disorder caused by blood glucose fluctuation are still a challenge.Neutral sphingophospholipase 2(Smpd3)is downregulated in jawbone-derived bone marrow mesenchymal stem cells(BMSCs)from T2DM patients.Here,we investigated the effect of Smpd3 on the osteogenic differentiation of BMSCs and utilized exosomes from stem cells overexpressing Smpd3 as the main treatment based on the glucose responsiveness of phenylboronic acid-based polyvinyl alcohol crosslinkers and the protease degradability of gelatin nanoparticles.The combined loading of Smpd3-overexpressing stem cell-derived exosomes(Exos-Smpd3)and nanosilver ions(Ns)to construct a hydrogel delivery system(Exos-Smpd3@Ns)promoted osteogenesis and differentiation of BMSCs in a glucose-fluctuating environment,ectopic osteogenesis of BMSCs in a glucose-fluctuating environment and jawbone regeneration of diabetic dogs in vitro.Mechanistically,Smpd3 promoted the osteogenesis and differentiation of jawbone-derived BMSCs by activating autophagy in the jawbone and inhibiting macrophage polarization and oxidative stress caused by blood glucose fluctuations.These results reveal the role and mechanism of Smpd3 and the Smpd3 overexpression exosome delivery system in promoting BMSC function and bone regeneration under blood glucose fluctuations,providing a theoretical basis and candidate methods for the treatment of bone defects in T2DM patients.

Aluminum adjuvants (Alum), approved by the US Food and Drug Administration, have been extensively used in vaccines containing recombinant antigens, subunits of pathogens, or toxins for almost a century. While Alums typically elicit strong humoral immune responses, their ability to induce cellular and mucosal immunity is limited. As an alternative, layered double hydroxide (LDH), a widely used antacid, has emerged as a novel class of potent nano-aluminum adjuvants (NanoAlum), demonstrating advantageous physicochemical properties, biocompatibility and adjuvanticity in both humoral and cellular immune responses. In this review, we summarize and compare the advantages and disadvantages of Alum and NanoAlum in these properties and their performance as adjuvants. Moreover, we propose the key features for ideal adjuvants and demonstrate that LDH NanoAlum is a promising candidate by summarizing its current progress in immunotherapeutic cancer treatments. Finally, we conclude the review by offering our integrated perspectives about the remaining challenges and future directions for NanoAlum's application in preclinical/clinical settings.

Blood glucose fluctuation leads to poor bone defect repair in patients with type 2 diabetes (T2DM). Strategies to safely and efficiently improve the bone regeneration disorder caused by blood glucose fluctuation are still a challenge. Neutral sphingophospholipase 2 (Smpd3) is downregulated in jawbone-derived bone marrow mesenchymal stem cells (BMSCs) from T2DM patients. Here, we investigated the effect of Smpd3 on the osteogenic differentiation of BMSCs and utilized exosomes from stem cells overexpressing Smpd3 as the main treatment based on the glucose responsiveness of phenylboronic acid-based polyvinyl alcohol crosslinkers and the protease degradability of gelatin nanoparticles. The combined loading of Smpd3-overexpressing stem cell-derived exosomes (Exos-Smpd3) and nanosilver ions (Ns) to construct a hydrogel delivery system (Exos-Smpd3@Ns) promoted osteogenesis and differentiation of BMSCs in a glucose-fluctuating environment, ectopic osteogenesis of BMSCs in a glucose-fluctuating environment and jawbone regeneration of diabetic dogs in vitro. Mechanistically, Smpd3 promoted the osteogenesis and differentiation of jawbone-derived BMSCs by activating autophagy in the jawbone and inhibiting macrophage polarization and oxidative stress caused by blood glucose fluctuations. These results reveal the role and mechanism of Smpd3 and the Smpd3 overexpression exosome delivery system in promoting BMSC function and bone regeneration under blood glucose fluctuations, providing a theoretical basis and candidate methods for the treatment of bone defects in T2DM patients.
Exosomes ; Animals ; Bone Regeneration/drug effects* ; Dogs ; Mesenchymal Stem Cells ; Humans ; Blood Glucose ; Cell Differentiation ; Osteogenesis/drug effects* ; Diabetes Mellitus, Type 2/therapy* ; Diabetes Mellitus, Experimental ; Cells, Cultured ; Hydrogels ; Male

Objective:To explore the effect of high-frequency repetitive transcranial magnetic stimulation(rTMS)on brain functional remodeling and function of core muscle group in patients with stroke.Methods:A total of 104 patients with stroke who admitted to Ruijin Hospital Affiliated to Shanghai Jiaotong University School of Medicine from January 2022 to June 2023 were prospectively selected,and they were randomly divided into a control group(52 cases,received conventional rehabilitation treatment)and a study group(52 cases,received conventional rehabilitation+high-frequency rTMS treatment).The differences in clinical efficacy,brain functional remodeling(LI value),and postural assessment scale for stroke(PASS)of the function of core muscle group and manual muscle test(MMT)scores of core muscle group between two groups were analyzed.Results:The total effective rate of clinical treatment in study group was 92.31％,which was significantly higher than that in the control group(73.08％),and the difference was significant(x2=6.718,P＜0.05).There were no significant difference in the scores of PASS and MMT between the two groups before treatment(P＞0.05).The scores of PASS and MMT of two groups after treatment were significantly higher than those before treatment(t=21.017,13.359,P＜0.05),respectively.After treatment,the PASS and MMT scores of study group were respectively(31.15±1.78)points and(11.88±2.03)points,which were significantly higher than those[(28.33±1.82)points and(9.41±2.27)points]of control group(t=7.988,5.849,P＜0.05),respectively.After treatment,the brain activation areas of study group mainly distributed in the precentral gyrus,precuneus,somatosensory area,cerebellum and ipsilateral supplementary motor area,which appeared a trend of centralization.The distribution of brain activation areas of control group after treatment still showed the characteristics of bilateral extensive activation,which did not appear significant changes than those before treatment.There was no significant difference in LI value between the two groups before treatment(P＞0.05).After treatment,the LI values of two groups were significantly improved,and the LI value of study group was significantly higher than that of control group(t=17.199,P＜0.05).Pearson correlation analysis was performed on the LI values and the scores of PASS and MMT when the hemiplegic side of the patients of two groups conducted chunking motion.The results showed that the LI values appeared significantly positive correlation with PASS score and MMT score(r=0.863,0.847,P＜0.05),respectively.Both two groups did not occur serious abnormal reactions during the treatment.Two patients of study group reported they occurred mild dizziness and headache,which were relieved by themselves after rest.Conclusion:High-frequency rTMS can effectively improve the treatment effect for patients with stroke,and promote the recovery of the motor function area of brain and the function of core muscle group of patients.