This paper reviews the published articles of recent years on the application of deep learning methods in automatic localization of acupoint, and summarizes it from 3 key links, i.e. the dataset construction, the neural network model design, and the accuracy evaluation of acupoint localization. The significant progress has been obtained in the field of deep learning for acupoint localization, but the scale of acupoint detection needs to be expanded and the precision, the generalization ability, and the real-time performance of the model be advanced. The future research should focus on the support of standardized datasets, and the integration of 3D modeling and multimodal data fusion, so as to increase the accuracy and strengthen the personalization of acupoint localization.
Deep Learning ; Acupuncture Points ; Humans ; Neural Networks, Computer

OBJECTIVE: To review and evaluate the advantages and disadvantages of minimally invasive treatment techniques for tibial plateau fractures (TPFs), as well as the research progress and limitations. METHODS: The relevant domestic and international research literature on the minimally invasive treatment of TPFs in recent years was reviewed. The advantages, disadvantages, and clinical efficacy of various technologies were summarized and analyzed, and an outlook on future development trends was provided. RESULTS: Surgery remains the primary method for treating displaced TPFs. Although traditional open reduction and internal fixation has advantages such as direct reduction and simplicity of procedure, it has gradually fallen out of favor with clinical orthopedic doctors due to extensive soft tissue removal, excessive bleeding, tissue adhesion, and postoperative complications such as skin infection, fracture nonunion, and joint dysfunction. As medical technology continues to develop, minimally invasive surgery and precise diagnosis and treatment are gradually being introduced to orthopedic trauma. Guided by concepts such as "minimally invasive treatment", "homeopathic repositioning of fractures", and "internal compression fixation", many traction reduction devices, internal fixation devices, minimally invasive reduction techniques, and computer-aided navigation technologies have been widely used in the clinical treatment of TPFs. This has greatly helped to overcome the challenges of intraoperative reduction, secondary reduction loss, and postoperative functional impairment and effectively promoting the adoption of minimally invasive treatment techniques in the clinical treatment of TPFs. CONCLUSION Minimally invasive treatment techniques have made significant progress in the clinical treatment of TPFs, particularly with regard to the reduction, and have demonstrated unique advantages. While relevant research results have received international recognition, there is still a need for orthopedic scholars to conduct real-world research to further explore the underlying principles and mechanisms of action.
Humans ; Minimally Invasive Surgical Procedures/instrumentation* ; Tibial Fractures/surgery* ; Fracture Fixation, Internal/instrumentation* ; Tibial Plateau Fractures

OBJECTIVE: To evaluate the effectiveness and safety of minimally invasive treatment for bilateral tibial plateau fractures using the double reverse traction reducer. METHODS: The clinical data of 4 patients with bilateral tibial plateau fractures who met the selection criteria and treated between January 2016 and April 2024 were retrospectively analyzed. The cohort included 3 males and 1 female, aged 30-65 years (mean, 52.5 years). Injury mechanisms comprised traffic accidents (2 cases) and falls (2 cases). According to the Schatzker classification, 2 limbs were type Ⅱ and 6 were type Ⅵ. The time from injury to surgery ranged from 5 to 9 days (mean, 7 days). All patients underwent minimally invasive reduction using the double reverse traction reducer. Surgical duration, intraoperative blood loss, and hospitalization time were recorded. Functional outcomes were assessed at last follow-up using the Hospital for Special Surgery (HSS) knee score and range of motion (ROM), while fracture reduction quality was evaluated using the Rasmussen radiological score. RESULTS: All 4 patients successfully completed the procedure without conversion to open reduction. The total mean operation time was 80.25 minutes (range, 73-86 minutes), with a mean total intraoperative blood loss of 132.5 mL (range, 100-150 mL). The mean hospitalization time was 13.5 days (range, 11-16 days). All incisions healed primarily without neurovascular complications. X-ray film at 1 day after operation confirmed satisfactory reduction and articular surface alignment. Follow-up time ranged from 12 to 26 months (mean, 17.0 months). Fractures achieved clinical union at an average of 13 weeks (range, 12-16 weeks). No complication, such as deep vein thrombosis, joint stiffness, post-traumatic arthritis, or implant failure, was observed. At last follow-up, the mean HSS score was 92.9 (range, 90-97), mean knee ROM was 128.1° (range, 115°-135°), and mean Rasmussen radiological score was 16.4 (range, 15-19), with 2 limbs rated as excellent and 6 as good. CONCLUSION The double reverse traction reducer facilitates minimally invasive treatment of bilateral tibial plateau fractures with advantages including minimal trauma, shorter surgical duration, precise reduction, and fewer complications, effectively promoting fracture healing and functional recovery of the knee joint.
Humans ; Tibial Fractures/diagnostic imaging* ; Middle Aged ; Male ; Minimally Invasive Surgical Procedures/instrumentation* ; Female ; Adult ; Retrospective Studies ; Aged ; Traction/methods* ; Treatment Outcome ; Fracture Fixation, Internal/instrumentation* ; Range of Motion, Articular ; Operative Time ; Tibial Plateau Fractures

OBJECTIVE: To investigate the biomechanical characteristics of Schatzker type Ⅱ tibial plateau fracture fixed by different bone grafting methods and internal fixations. METHODS: Twenty-four embalmed specimens of adult knee joint were selected to make Schatzker type Ⅱ tibial plateau fracture models, which were randomly divided into 8 groups (groups A1-D1 and groups A2-D2, n=3). After all the fracture models were restored, non-structural iliac crest bone grafts were implanted in group A1-D1, and structural iliac crest bone grafts in groups A2-D2. Following bone grafting, group A was fixed with a lateral golf locking plate, group B was fixed with lateral golf locking plate combined compression bolt, group C was fixed with lateral tibial "L"-shaped locking plate, and group D was fixed with lateral tibial "L"-shaped locking plate combined compression bolt. Compression and cyclic loading tests were performed on a biomechanical testing machine. A distal femur specimen or a 4-cm-diameter homemade bone cement ball were used as a pressure application mould for each group of models. The specimens were loaded with local compression at a rate of 10 N/s and the mechanical loads were recorded when the vertical displacement of the split bone block reached 2 mm. Then, compressive and cyclic loading tests were conducted on the fixed models of each group. The specimens were compression loaded to 100, 400, 700, and 1 000 N at a speed of 10 N/s to record the vertical displacement of the split bone block. The specimens were also subjected to cyclic loading at 5 Hz and 10 N/s within the ranges 100-300, 100-500, 100-700, and 100-1 000 N to record the vertical displacement of the split bone block at the end of the entire cyclic loading test. The specimens were subjected to cyclic loading tests and the vertical displacement of the split bone block was recorded at the end of the test. RESULTS: When the vertical displacement of the collapsed bone block reached 2 mm, the mechanical load of groups A2-D2 was significantly greater than that of groups A1-D1 ( P<0.05). The mechanical load of groups B and D was significantly greater than that of group A under the two bone grafting methods ( P<0.05); the local mechanical load of group D was significantly greater than that of groups B and C under the structural iliac crest bone grafts ( P<0.05). There was no significant difference ( P>0.05) in the vertical displacement of the split bone blocks between the two bone graft methods when the compressive load was 100, 400, 700 N and the cyclic load was 100-300, 100-500, 100-700 N in groups A-D. However, the vertical displacement of bone block in groups A1-D1 was significantly greater than that in groups A2-D2 ( P<0.05) when the compressive loading was 1 000 N and the cyclic load was 100-1 000 N. The vertical displacement of bone block in group B was significantly smaller than that in group A, and that in group D was significantly smaller than that in group C under the same way of bone graft ( P<0.05). CONCLUSION Compared with non-structural iliac crest bone grafts implantation, structural iliac crest bone grafts is more effective in preventing secondary collapse of Schatzker type Ⅱ tibial plateau fracture, and locking plate combined with compression bolt fixation can provide better articular surface support and resistance to axial compression, and the lateral tibial "L"-shaped locking plate can better highlight its advantages of "raft" fixation and show better mechanical stability.
Humans ; Bone Transplantation/methods* ; Tibial Fractures/physiopathology* ; Fracture Fixation, Internal/instrumentation* ; Biomechanical Phenomena ; Bone Plates ; Ilium/transplantation* ; Adult ; Tibia/surgery* ; Bone Cements ; Knee Joint/surgery* ; Male ; Tibial Plateau Fractures

Objective:To investigate the effects of dual vascularized tissue-engineered bone constructed by vascular bundles and endothelial progenitor cells (EPCs) on repair of large bone defects and vascular regeneration.Methods:EPCs were seeded on the demineralized bone matrix (DBM) scaffolds and cultured for 6 days. The attachment and morphology of EPCs on DBM scaffolds were observed by electron microscopy. Next, the radial artery was implanted into a vascular groove opened inside the DBM-EPCs composite scaffolds. Finally, models of a large segmental bone defect were constructed using the radii from 18 New Zealand white rabbits. The rabbits were randomly divided into 4 groups using a simple random sampling method: DBM group, DBM+EPCs group, DBM+vascular bundle group, and DBM+EPCs+vascular bundle group. The DBM group and DBM+EPCs group shared the same rabbits so that transplantations were conducted into the left and right forearms respectively; the DBM+vascular bundle group and DBM+EPCs+vascular bundle group also shared the same rabbits so that transplantations were conducted into the left and right forearms respectively. Consequently, there were 9 experimental sites in each group. X-ray examination and gross morphological observation were performed to evaluate the bone regeneration in the experimental rabbits in each group at 4, 8, and 12 weeks after surgery, and CD31 immunofluorescence staining was used to evaluate the vascular regeneration. Micro-CT was used to analyze bone tissue parameters and reconstruct the three-dimensional structures of the defects site at 12 weeks after surgery.Results:Compared with the DBM, DBM+EPCs and DBM+vascular bundle groups, the DBM+EPCs+vascular bundle group showed new bone tissue crawling on the scaffold surface at 4 weeks after surgery, almost complete healing of the bone defect area at 8 weeks, and forming of a complete and dense bone bridge and appearance of a bone marrow cavity at 12 weeks. Micro-CT data at 12 weeks after surgery showed regular arrangement of the trabeculae, significantly improved mineralization, and increased thickness of the bone cortex in the DBM+EPCs+vascular bundle group. Additionally, in the DBM+EPCs+vascular bundle group, the number of microvessels was significantly higher than that in the other groups at 4, 8, 12 weeks after surgery ( P<0.05), and the angiogenesis and bone tissue regeneration were particularly prominent at 12 weeks after surgery. The number of CD31 cells in the DBM+EPCs+vascular bundle group increased significantly more than that in the DBM, DBM+EPCs and DBM+vascular bundle groups ( P<0.05). Conclusion:As the dual vascularized tissue-engineered bone constructed by vascular bundles and EPCs can significantly promote bone tissue regeneration and angiogenesis, it may be a potential therapeutic strategy for repair of large bone defects.

Objective:To explore the clinical effects of free bilateral turbocharged anterolateral thigh flaps in tandem in repairing extensive wounds in the foot and ankle.Methods:The study was a retrospective observational study. From April 2020 to June 2023, 12 patients with extensive wounds in the foot and ankle who met the inclusion criteria were admitted to the Department of Wound Repair Surgery of Suzhou Ruihua Orthopedic Hospital, including 8 males and 4 females, aged 21 to 65 years. The wound area after debridement ranged from 27 cm×14 cm to 37 cm×20 cm. The bilateral perforator flaps pedicled with either oblique or descending branches of the lateral circumflex femoral artery were designed and harvested based on the size and shape of the wounds. The individual flap incision area ranged from 16 cm×9 cm to 34 cm×12 cm. The non-homologous perforator of the flap on the one side was turbocharged by anastomosing it with the gross muscular branch or main vessel of the oblique or descending branch of the lateral circumflex femoral artery from the flap. Subsequently, the proximal end of the oblique or descending branch of the lateral circumflex femoral artery and its accompanying vein from the flap on the one side were connected end-to-end with either the anterior tibial artery and vein, posterior tibial artery and vein, or dorsal foot artery and vein in the recipient area, the distal end of the oblique or descending branch of the lateral circumflex femoral artery and its accompanying vein from the flap on the one side were anastomosed end-to-end with a source vessel originating from flap on the other side. The wounds in the flap donor areas were sutured directly. The number and source of perforators carried by the flaps and the duration of the flap repair surgery were recorded. The survival of the flap, the occurrence of vascular crisis, and the wound healing at both donor and recipient areas were observed after surgery. The flap condition, appearance and function of the affected limb were observed during follow-up. At the last follow-up, the sensory function of the flap was assessed using the British Medical Research Council's sensory rating standard, the foot and ankle function of the affected limb was evaluated according to the American Orthopedic Foot and Ankle Society scoring standard.Results:A total 24 flaps were successfully harvested, carrying 60 perforators, including 34 perforators from the oblique branch of the lateral circumflex femoral artery, 24 perforators from the descending branch of the lateral circumflex femoral artery, one perforator from the transverse branch of the lateral circumflex femoral artery, and one perforator from the direct branch of the femoral artery. The duration of the flap repair surgery ranged from 4.2 to 9.0 hours. The flaps of 12 patients exhibited complete survival after surgery. A total of two flaps of two patients experienced venous crisis after surgery but survived through emergency exploration. One patient encountered undesirable wound healing at the donor area of flap on the one side after surgery, which healed after dressing change, debridement, and suturing. The remaining patients' donor area wounds healed. Two patients displayed impaired wound healing in the recipient area, which improved after dressing change and resection of residual sequestrum, and the wounds in the recipient area of other patients healed successfully. During the follow-up of 4-26 months, the flaps demonstrated favorable color and texture, slight edematous appearance, and partial sensory recovery, as well as good aesthetic and functional restoration of the affected limbs. At the last follow-up, the sensory function of the flap was assessed as grade S2 in 9 cases and grade S3 in 3 cases; the foot and ankle function of the affected limb was evaluated as excellent in two cases, good in 9 cases, and fair in one case.Conclusions:The bilateral turbocharged anterolateral thigh flaps have numerous sources of perforators. By implementing supercharging of non-homologous perforators within the flap, the vascular supply to the flap is turbocharged, thereby mitigating the risk of extensive flap necrosis. The flap is an effective approach for repairing extensive wounds in the foot and ankle, resulting in improved function of the affected limb after repair.

Objective:To investigate the effects of dual vascularized tissue-engineered bone constructed by vascular bundles and endothelial progenitor cells (EPCs) on repair of large bone defects and vascular regeneration.Methods:EPCs were seeded on the demineralized bone matrix (DBM) scaffolds and cultured for 6 days. The attachment and morphology of EPCs on DBM scaffolds were observed by electron microscopy. Next, the radial artery was implanted into a vascular groove opened inside the DBM-EPCs composite scaffolds. Finally, models of a large segmental bone defect were constructed using the radii from 18 New Zealand white rabbits. The rabbits were randomly divided into 4 groups using a simple random sampling method: DBM group, DBM+EPCs group, DBM+vascular bundle group, and DBM+EPCs+vascular bundle group. The DBM group and DBM+EPCs group shared the same rabbits so that transplantations were conducted into the left and right forearms respectively; the DBM+vascular bundle group and DBM+EPCs+vascular bundle group also shared the same rabbits so that transplantations were conducted into the left and right forearms respectively. Consequently, there were 9 experimental sites in each group. X-ray examination and gross morphological observation were performed to evaluate the bone regeneration in the experimental rabbits in each group at 4, 8, and 12 weeks after surgery, and CD31 immunofluorescence staining was used to evaluate the vascular regeneration. Micro-CT was used to analyze bone tissue parameters and reconstruct the three-dimensional structures of the defects site at 12 weeks after surgery.Results:Compared with the DBM, DBM+EPCs and DBM+vascular bundle groups, the DBM+EPCs+vascular bundle group showed new bone tissue crawling on the scaffold surface at 4 weeks after surgery, almost complete healing of the bone defect area at 8 weeks, and forming of a complete and dense bone bridge and appearance of a bone marrow cavity at 12 weeks. Micro-CT data at 12 weeks after surgery showed regular arrangement of the trabeculae, significantly improved mineralization, and increased thickness of the bone cortex in the DBM+EPCs+vascular bundle group. Additionally, in the DBM+EPCs+vascular bundle group, the number of microvessels was significantly higher than that in the other groups at 4, 8, 12 weeks after surgery ( P<0.05), and the angiogenesis and bone tissue regeneration were particularly prominent at 12 weeks after surgery. The number of CD31 cells in the DBM+EPCs+vascular bundle group increased significantly more than that in the DBM, DBM+EPCs and DBM+vascular bundle groups ( P<0.05). Conclusion:As the dual vascularized tissue-engineered bone constructed by vascular bundles and EPCs can significantly promote bone tissue regeneration and angiogenesis, it may be a potential therapeutic strategy for repair of large bone defects.

Objective:To explore the clinical effects of free bilateral turbocharged anterolateral thigh flaps in tandem in repairing extensive wounds in the foot and ankle.Methods:The study was a retrospective observational study. From April 2020 to June 2023, 12 patients with extensive wounds in the foot and ankle who met the inclusion criteria were admitted to the Department of Wound Repair Surgery of Suzhou Ruihua Orthopedic Hospital, including 8 males and 4 females, aged 21 to 65 years. The wound area after debridement ranged from 27 cm×14 cm to 37 cm×20 cm. The bilateral perforator flaps pedicled with either oblique or descending branches of the lateral circumflex femoral artery were designed and harvested based on the size and shape of the wounds. The individual flap incision area ranged from 16 cm×9 cm to 34 cm×12 cm. The non-homologous perforator of the flap on the one side was turbocharged by anastomosing it with the gross muscular branch or main vessel of the oblique or descending branch of the lateral circumflex femoral artery from the flap. Subsequently, the proximal end of the oblique or descending branch of the lateral circumflex femoral artery and its accompanying vein from the flap on the one side were connected end-to-end with either the anterior tibial artery and vein, posterior tibial artery and vein, or dorsal foot artery and vein in the recipient area, the distal end of the oblique or descending branch of the lateral circumflex femoral artery and its accompanying vein from the flap on the one side were anastomosed end-to-end with a source vessel originating from flap on the other side. The wounds in the flap donor areas were sutured directly. The number and source of perforators carried by the flaps and the duration of the flap repair surgery were recorded. The survival of the flap, the occurrence of vascular crisis, and the wound healing at both donor and recipient areas were observed after surgery. The flap condition, appearance and function of the affected limb were observed during follow-up. At the last follow-up, the sensory function of the flap was assessed using the British Medical Research Council's sensory rating standard, the foot and ankle function of the affected limb was evaluated according to the American Orthopedic Foot and Ankle Society scoring standard.Results:A total 24 flaps were successfully harvested, carrying 60 perforators, including 34 perforators from the oblique branch of the lateral circumflex femoral artery, 24 perforators from the descending branch of the lateral circumflex femoral artery, one perforator from the transverse branch of the lateral circumflex femoral artery, and one perforator from the direct branch of the femoral artery. The duration of the flap repair surgery ranged from 4.2 to 9.0 hours. The flaps of 12 patients exhibited complete survival after surgery. A total of two flaps of two patients experienced venous crisis after surgery but survived through emergency exploration. One patient encountered undesirable wound healing at the donor area of flap on the one side after surgery, which healed after dressing change, debridement, and suturing. The remaining patients' donor area wounds healed. Two patients displayed impaired wound healing in the recipient area, which improved after dressing change and resection of residual sequestrum, and the wounds in the recipient area of other patients healed successfully. During the follow-up of 4-26 months, the flaps demonstrated favorable color and texture, slight edematous appearance, and partial sensory recovery, as well as good aesthetic and functional restoration of the affected limbs. At the last follow-up, the sensory function of the flap was assessed as grade S2 in 9 cases and grade S3 in 3 cases; the foot and ankle function of the affected limb was evaluated as excellent in two cases, good in 9 cases, and fair in one case.Conclusions:The bilateral turbocharged anterolateral thigh flaps have numerous sources of perforators. By implementing supercharging of non-homologous perforators within the flap, the vascular supply to the flap is turbocharged, thereby mitigating the risk of extensive flap necrosis. The flap is an effective approach for repairing extensive wounds in the foot and ankle, resulting in improved function of the affected limb after repair.

Tissue engineering bone technology, grounded in seed cells, cytokines, and scaffold supports, provides an effective solution for addressing extensive bone defects, demonstrating significant potentials in the field of bone repair. However, this technology still faces numerous challenges. Focusing on vascularization in engineered bones, this article reviews various methods to enhance vascularization within tissue-engineered bones, including multicellular co-culture, application of angiogenic factors, advanced 3D printing, and aid of surgical interventions. This article also analyses the latest research developments and the limitations of the methods, and speculates future research directions for tissue engineered bone.

Sheep pox is widespread worldwide and is the most severe animal pox virus infection. This study aimed to identify the key microRNAs (miRNAs) differentially expressed in the exosomes of sheep poxvirus-infected cells and their target genes and related pathways and provide a theoretical basis for an in-depth understanding of the molecular mechanisms of sheep poxvirus-infected cells. In this study, the differentially expressed miRNAs were verified by quantitative polymerase chain reaction (qPCR), and the target genes of miRNAs were predicted and analyzed by bioinformatics. The qPCR results showed that the expression trends of oar-miR-21, oar-miR-10b, oar-let-7f, oar-let-7b, and oar-miR-221 were consistent with the sequencing results. The Gene Ontology and Kyoto Encyclopedia of Genes and Genomes results showed that differentially expressed miRNAs were mainly involved in the immune system processes of the Arf6 downstream pathway. The target genes Reactome pathways were mainly enriched in the RAC1 GTPase cycle, CDC42 GTPase cycle, RHO GTPase cycle, RHOV GTPase cycle, and post-transcriptional silencing of small RNAs. The transcription factors SP4, NKX6-1, MEF2A, SP1, EGR1, and POU2F1 that may be connected to sheep pox virus (SPPV)-infected cells were discovered by transcription factor annotation screening. In conclusion, this study screened for differentially expressed miRNAs in SPPV-infected cells and performed a series of bioinformatic analyses of their target genes to provide a theoretical basis for the molecular mechanism of sheep pox virus infections of cells. The data can be used as basic information in future studies on the defense mechanisms against poxvirus infections.