Acute symptomatic osteoporotic thoracolumbar compression fracture (ASOTLF) can lead to chronic low back pain, kyphosis deformity, pulmonary dysfunction, loss of mobility, and even life-threatening complications. Vertebral augmentation is currently the mainstream treatment method for this condition. In 2019, the Editorial Board of Chinese Journal of Trauma and the Spinal Trauma Group of Orthopedic Surgeons Branch of Chinese Medical Doctor Association collaboratively led the development of Clinical guideline for vertebral augmentation for acute symptomatic osteoporotic thoracolumbar compression fractures. Six years later, with advances in clinical diagnosis and treatment techniques as well as accumulating evidence in related fields, the 2019 guideline requires updating. To this end, the Spinal Trauma Group of Orthopedic Surgeons Branch of Chinese Medical Doctor Association, the Spinal Health Professional Committee of China Human Health Science and Technology Promotion Association, and the Minimally Invasive Orthopedics Professional Committee of Shaanxi Medical Doctor Association have organized experts in the field to develop the Clinical guideline for vertebral augmentation of acute symptomatic osteoporotic thoracolumbar compression fractures ( version 2025) , based on the latest evidence-based medical researches. This guideline incorporates 3 recommendations retained from the 2019 version with updated strength of evidence, along with 12 new recommendations. It provides recommendations from six aspects of diagnosis, pain management, treatment option selection, prevention of postoperative complications, anti-osteoporosis therapy, and postoperative rehabilitation, aiming to provide a reference for standard treatment of vertebral augmentation for ASOTLF in hospitals at all levels.

Acute symptomatic osteoporotic thoracolumbar compression fracture (ASOTLF) can lead to chronic low back pain, kyphosis deformity, pulmonary dysfunction, loss of mobility, and even life-threatening complications. Vertebral augmentation is currently the mainstream treatment method for this condition. In 2019, the Editorial Board of Chinese Journal of Trauma and the Spinal Trauma Group of Orthopedic Surgeons Branch of Chinese Medical Doctor Association collaboratively led the development of Clinical guideline for vertebral augmentation for acute symptomatic osteoporotic thoracolumbar compression fractures. Six years later, with advances in clinical diagnosis and treatment techniques as well as accumulating evidence in related fields, the 2019 guideline requires updating. To this end, the Spinal Trauma Group of Orthopedic Surgeons Branch of Chinese Medical Doctor Association, the Spinal Health Professional Committee of China Human Health Science and Technology Promotion Association, and the Minimally Invasive Orthopedics Professional Committee of Shaanxi Medical Doctor Association have organized experts in the field to develop the Clinical guideline for vertebral augmentation of acute symptomatic osteoporotic thoracolumbar compression fractures ( version 2025) , based on the latest evidence-based medical researches. This guideline incorporates 3 recommendations retained from the 2019 version with updated strength of evidence, along with 12 new recommendations. It provides recommendations from six aspects of diagnosis, pain management, treatment option selection, prevention of postoperative complications, anti-osteoporosis therapy, and postoperative rehabilitation, aiming to provide a reference for standard treatment of vertebral augmentation for ASOTLF in hospitals at all levels.

Objective:To provide clues for in-depth research on radiation protection in deep space exploration missions by reviewing the biological effects of space radiation and biological protection technologies. Literature resource and selection 　Domestic and abroad relevant literatures were searched and reviewed. Literature quotation 　Thirty-nine papers published in China and abroad were cited. Literature synthesis 　Space radiation is the most important environmental harmful factor that affects the health and mission completion of astronauts in deep space exploration missions. It can cause multiple organ cancers throughout the body, degenerative diseases of cardiovascular, central nervous systems, and ocular lens, and acute radiation syndrome of the bone marrow, brain, and gastrointestinal tracts. The effect mechanisms include free radical production, oxidative stress, DNA and other biomolecular breaks, inflammation, cell apoptosis, and bystander effects. Biological protection can be carried out according to the characteristics of the mechanism at different stages of the development of space radiation effects. Conclusions:Deep space radiation can cause health risks such as cancer, degeneration, and acute radiation syndrome, which can be mainly protected and alleviated by reducing free radicals, promoting DNA repair, and inhibiting cell apoptosis.

Objective To explore the effect of bone marrow injury by simulating the radiation from solar particle events in order to address the radiation limit and assess risks during manned deep space exploration.Methods In line with solar particle events(the main component was protons),BALB/c mice(48 mice per group)were irradiated with 90 MeV protons at the doses of 0,0.1,0.3,0.5,1 and 2 Gy.At 3 and 7 days after irradiation.Routine blood counters were employed to detect peripheral blood changes,Giemsa staining was used to detect the ratio of granulocytes to erythrocytes in bone marrow,and flow cytometry was adopted to detect the proportion of bone marrow stem cells,cell subsets and apoptosis before the dose-response relationship and threshold were analyzed.Results In the dose range of 0.1 to 2 Gy,the number of peripheral blood white blood cells and lymphocytes decreased at 3 and 7 days after irradiation and the ratio of granulocytes to erythrocytes in bone marrow and bone marrow cell subsets were abnormal as the dose increased.Seven days after irradiation,the platelet count decreased.The minimum dose that caused significant changes was 0.5 Gy,13 models with dose-response relationships were obtained,and the minimum values of ED25,ED50 and ED63 were 0.25,0.58 and 0.76 Gy,respectively.Conclusion A total of 13 dose-response relationship models of proton-induced bone marrow injury in mice have been obtained,and the dose threshold of proton-induced bone marrow injury ranges from 0.25 to 0.76 Gy.

Objective:To explore the produced-radiation brain damage in simulated solar particle events and to provide evidence for health risk assessment of radiation from manned deep space exploration.Methods:According to the main characteristics of solar particle events, mice were treated with total body irradiation (TBI) with 90 MeV protons in a dose range from 0.1 to 2 Gy, with irradiation dose of 0, 0.1, 0.3, 0.5, 1, 2 Gy, respectively. At 3 and 7 d after irradiation, the behavior of mice was examined using balance beam tests, rotarod tests, and new object recognition tests. Then, the density of dendritic spines and the number of Nissl bodies in the hippocampus were measured using Golgi and Nissl staining. The superoxide dismutase (SOD) activity, malondialdehyde (MDA) content, and neurotransmitter content in brain tissue were detected using the WST-8 method, TBA method, and high pressure liquid chromatography (HPLC), respectively. Besides, cell apoptosis was determined using the TUNEL method, and the dose-response relationship, a function of dose change with damage index, was analyzed using linear and linear square fitting method. Finally, the minimum radiation dose causing a significant change in all indicators of brain damage was determined as the brain damage threshold.Results:Compared to the control group, 1 Gy proton irradiation result ed in a significant decrease in the density of filopod dendritic spines ( t = 1.82, 2.30, P < 0.05) and a significant increase in abnormal Nissl bodies in the CA1 region ( t = 2.44, 3.77, P < 0.05). At 3 and 7 d after irradiation, as well as a significant increase in the DA ( t = 2.52, P<0.05) and Glu contents ( t = 4.04, P < 0.05) on day 7. In contrast, 2 Gy proton irradiation result ed in a decrease in SOD activity on day 3 ( t = 3.44, P < 0.05), and an increase in the MDA content ( t = 1.90, 2.14, P < 0.05), hippocampal cell apoptosis (t = 3.91, 3.54, P < 0.05), and 5-HT levels ( t = 2.81, 2.69, P < 0.05), together with a decrease in climbing time in the rotarod tests ( t = 2.85, 2.64, P<0.05) and propensity to recognize new objects ( t = 2.87, 2.84, P < 0.05) on days 3 and 7. Furthermore, a dose-response relationship was observed in the dose range from 0.1 to 2 Gy ( R2=0.74-0.99). Conclusions:The dose threshold of 90 MeV protons inducing brain damage in mice is inferred to be 1 Gy, and 14 dose-response models are developed, providing a biological basis for organ dose capping and risk assessment of crew experiencing short-term deep space flights.

Objective:To provide clues for in-depth research on radiation protection in deep space exploration missions by reviewing the biological effects of space radiation and biological protection technologies. Literature resource and selection 　Domestic and abroad relevant literatures were searched and reviewed. Literature quotation 　Thirty-nine papers published in China and abroad were cited. Literature synthesis 　Space radiation is the most important environmental harmful factor that affects the health and mission completion of astronauts in deep space exploration missions. It can cause multiple organ cancers throughout the body, degenerative diseases of cardiovascular, central nervous systems, and ocular lens, and acute radiation syndrome of the bone marrow, brain, and gastrointestinal tracts. The effect mechanisms include free radical production, oxidative stress, DNA and other biomolecular breaks, inflammation, cell apoptosis, and bystander effects. Biological protection can be carried out according to the characteristics of the mechanism at different stages of the development of space radiation effects. Conclusions:Deep space radiation can cause health risks such as cancer, degeneration, and acute radiation syndrome, which can be mainly protected and alleviated by reducing free radicals, promoting DNA repair, and inhibiting cell apoptosis.

Objective To analyze the plantar pressure distribution of knee osteoarthritis ( KOA) patients after medial opening wedge high tibial osteotomy ( MOWHTO), so as to provide biomechanical references for the surgical treatment and rehabilitation of patients. Methods A total of 31 patients with medial single compartmental KOA after unilateral MOWHTO treatment were selected as the experimental group, and 35 healthy subjects at same age were selected as the control group. The Pedomedic 40 􀅺 pressure measuring system was used to test dynamic plantar pressure. By comparing the maximum pressure ( pmax ), force-time integral ( FTI) and contact area (CA) of different plantar zones between the experimental group (operative side and unoperated side) and the control group during walking, the changes of plantar pressure in patients with medial single compartmental KOA after MOWHTO were evaluated. Results Compared with the unoperated side and the control group, the CA and FTI of the 1st metatarsal head (MH1) were higher (P<0. 05), the CA of the 4th metatarsal head (MH4)was smaller (P<0. 001), the pmax and FTI of the 5th metatarsal head (MH5) were smaller (P<0. 05), the CA of the lateral middle foot (MF-L) was smaller (P<0. 001), and the CA of the medial rear foot (RF-M) was larger (P<0. 05). Compared with the control group, the pmax of MH1 and MH2 was smaller (P<0. 05), the CA and FTI of MH5 were larger (P<0. 05), the pmax of MF-L was larger (P<0. 001), and the FTI of lateral rear foot (RF-L) was larger (P<0. 05). Conclusions Compared with healthy people, patients with medial single compartmental KOA have abnormal plantar pressure residual after MOWHTO. In clinical practice, targeted intensive rehabilitation therapy is necessary to restore the normal plantar distributions of patients.

OBJECTIVE: To explore prevalence, risk factors and treatment of ankle sprain of young college student , in order to obtain accurate epidemiological data. METHODS: From March 2019 to May 2019, 552 college students(1 104 sides of anke joints) from Xi'an Physical Education university were enrolled in study according to inclusion and excludion standard, including 309 males and 243 females aged from 16 to 24 years old with an average of (20.9±3.7) years old. Age, gender, and body mass indes(BMI) etc were recorded. Morbidity of acute and chronic ankle sprains of physical students, treatment after the first sprain (cold compress, cast or plaster bracing and medicine), visual analogue scale (VAS) during walking were assessed through ankle sprain questionnaire;Cumberland ankle instability tool (CAIT), Maryland foot score were applied to assess ankle function. Lateral ankle ligament injury was objectively assessed by musculoskeletal ultrasonography. RESULTS: The prevalence of acute ankle sprain(AAS) was 96.20% (531/552), and the incidence of AAS was 59.96% (622/1 104). The prevalence of chronic ankle joint instability(CAI) was 16.85% (93/552), and the incidence of CAI was 8.97% (99/1 104). In the four categories of sports, college student suffered from multiple sprains in performance majors group was 22.20% (14/63), including of aerobicsand dance performance. The incidence of AAS of ball sports was 8.60%(14/163). After the first sprain, most college students(94.4%) were received cold compression, about 60% of them went to hospital;however, only 44.7% students were received standard treatmens(cast or plaster), only 35.3% of them were received hard ankle orthosis. In 552 college students, 44 students were suffered from more than 4 times of ankle sprain, and the total incidence was 7.97% (44/552). Cumberland score was 26.6±2.4, Cumberland score of students sprained ankle joint more than 4 times was (29.2±1.1), suggested it was a risk factor for ankle joint instability. VAS of students sprained ankle joint more than 4 times was higher than that of less than 4 times(P<0.05), Maryland foot score was significantly lower than that of that of <4 times(P<0.05). Musculoskeletal ultrasonography measured the thickness of anterior tibiofibular ligament(ATFL) was (2.41±0.41) mm, and the thickness of calcaneofibular ligament(CFL) was (1.92±0.21) mm, and had no statistical difference(P>0.05). CONCLUSION Ninty-four percent college students had at least once ankle sprain, ankle sprains were more common in erobics and ball sports. After the first sprain, the proportion of cast or plaster treatment was less than 50%. Sprained ankle joint more than 4 times is a risk factor, and musculoskeletal ultrasonography showed thickening of both ATFL and CFL, while no statstical difference.
Female ; Male ; Humans ; Adolescent ; Young Adult ; Adult ; Cross-Sectional Studies ; Joint Instability/epidemiology* ; Physical Education and Training ; Universities ; Ankle Injuries/therapy*

Osteoporotic vertebral compression fracture (OVCF) can lead to lower back pain and may be even accompanied by scoliosis, neurological dysfunction and other complications, which will affect the daily activities and life quality of patients. Vertebral augmentation is an effective treatment method for OVCF, but it cannot correct unbalance of bone metabolism or improve the osteoporotic status, causing complications like lower back pain, limited spinal activities and vertebral refracture. The post-operative systematic and standardized rehabilitation treatments can improve curative effect and therapeutic efficacy of anti-osteoporosis, reduce risk of vertebral refracture, increase patient compliance and improve quality of life. Since there still lack relevant clinical treatment guidelines for postoperative rehabilitation treatments following vertebral augmentation for OVCF, the current treatments are varied with uneven therapeutic effect. In order to standardize the postoperative rehabilitation treatment, the Spine Trauma Group of the Orthopedic Branch of Chinese Medical Doctor Association organized relevant experts to refer to relevant literature and develop the "Guideline for postoperative rehabilitation treatment following vertebral augmentation for osteoporotic vertebral compression fracture (2022 version)" based on the clinical guidelines published by the American Academy of Orthopedic Surgeons (AAOS) as well as on the principles of scientificity, practicality and advancement. The guideline provided evidence-based recommendations on 10 important issues related to postoperative rehabilitation treatments of OVCF.