BACKGROUND:The AO12-C type middle-proximal humeral fractures are usually caused by high-energy injuries,accompanied by comminuted fractures and a large number of butterfly-shaped bone fragments.These fractures are difficult to achieve good reduction and effective fixation.With the increasing understanding of the biological characteristics of bone and soft tissue,surgical treatment is gradually shifting towards minimally invasive steel plates and intramedullary nail fixation.However,there has been no consensus on which is the best surgical technique for treating humeral fractures in minimal invasive plate osteosynthesis and intramedullary nail.OBJECTIVE:To compare the clinical effect of minimal invasive plate osteosynthesis and intramedullary nail for treating AO12-C type middle-proximal humeral fractures.METHODS:A retrospective analysis was performed in 36 patients with AO12-C type middle-proximal humeral fracture who met the inclusion criteria admitted to the Guizhou Hospital of Beijing Jishuitan Hospital from January 2020 to December 2022.All patients were assigned to minimal invasive plate osteosynthesis group(18 cases)and intramedullary nail group(18 cases)according to the surgical treatment plan.The minimal invasive plate osteosynthesis group received minimally invasive plate osteosynthesis based on preoperative planning assisted by 3D printing,while the intramedullary nail group received intramedullary nail internal fixation.Operation time,intraoperative blood loss,hospital stay,and fracture healing time were compared between the two groups.Visual analog scale score at 1,3,and 6 months after surgery,shoulder joint function,Constant-Murley score,Quick Disabilities of the Arm,Shoulder and Hand(QuickDASH)score,and complications of the shoulder joint at the last follow-up were compared between the two groups.RESULTS AND CONCLUSION:(1)All patients were followed-up for average(15.56±4.05)months,and no difference was observed in hospital stay and fracture healing time between the two groups(P＞0.05).The minimal invasive plate osteosynthesis group had shorter operation time compared to the intramedullary nail group(P＜0.05).The intramedullary nail group had less intraoperative blood loss between the two groups of patients(P＜0.05).(2)In the intramedullary nail group,at 1 and 3 months after operation,the visual analog scale score was significantly lower than the minimal invasive plate osteosynthesis group(P＜0.05).No difference was observed in the visual analog scale in long-term follow-up,shoulder joint function,Constant-Murley score,Quick Disabilities of the Arm,Shoulder and Hand(QuickDASH)score at the last follow-up between the two groups(P＞0.05).(3)No complications such as nonunion or wound infection occurred in either group.Two cases of radial nerve palsy occurred in minimal invasive plate osteosynthesis group,both of which recovered within 3 months.The intramedullary nail group had 1 case of rotator cuff injury.There was no significant difference in the rate of complications between the two groups(P＞0.05).(4)To conclude,minimal invasive plate osteosynthesis and intramedullary nail can achieve good clinical efficacy in the treatment of AO12-C type middle-proximal humeral fractures,effectively improving shoulder joint function in patients.However,minimal invasive plate osteosynthesis exhibits obvious advantages in shorter surgical time with the assistance of 3D printing,which is a valuable,effective,and safe method for treating AO12-C type middle-proximal humeral fractures.

BACKGROUND:Previous studies have mostly performed biomechanical analysis of early fracture healing by ignoring muscle loading and using simplified femoral loading. Nevertheless,the biomechanical effects of muscle loading on early fracture healing are still uncertain.OBJECTIVE:To construct various femoral loading models allows for the study of the biomechanical effects of muscle loading on fracture healing,enabling clinicians to gain a deeper understanding of the biomechanical process of fracture healing and to optimize treatment protocols.METHODS:The AnyBody Modeling System software was employed to construct a personalized human musculoskeletal system,which was then analyzed by simulation in order to obtain the musculoskeletal loading model in vivo. This model,along with the femur loading model constructed using the improved simplified loading method and the simplified loading method,was utilized as boundary conditions for the finite element inputs,which were used to analyze the locking compression plate stress-strain and interfragmentary strain in the standing condition,respectively.RESULTS AND CONCLUSION:(1) The locking compression plate stresses and strains and interfragmentary strains obtained from the musculoskeletal method were,respectively,31.9％,38.9％,and 19.5％ smaller than those obtained from the simplified loading method. (2) A comparison of the musculoskeletal method with the modified simplified loading method revealed that the neglect of muscle loading resulted in an overestimation of locking compression plate stress and strain,as well as interfragmentary strain,by 16.8％,14.3％,and 19.5％,respectively. Muscle loading did not have a significant effect on the magnitude of the shear motion of the fracture block,whereas it did have a significant effect on the direction of motion. (3) The results indicated that the simplified femoral loading and the method of ignoring muscle loading exhibited some deviation from the musculoskeletal loading situation. Consequently,it is necessary to consider the biomechanical effects of muscle loading in the study of fracture healing.

BACKGROUND:Previous studies have mostly performed biomechanical analysis of early fracture healing by ignoring muscle loading and using simplified femoral loading. Nevertheless,the biomechanical effects of muscle loading on early fracture healing are still uncertain.OBJECTIVE:To construct various femoral loading models allows for the study of the biomechanical effects of muscle loading on fracture healing,enabling clinicians to gain a deeper understanding of the biomechanical process of fracture healing and to optimize treatment protocols.METHODS:The AnyBody Modeling System software was employed to construct a personalized human musculoskeletal system,which was then analyzed by simulation in order to obtain the musculoskeletal loading model in vivo. This model,along with the femur loading model constructed using the improved simplified loading method and the simplified loading method,was utilized as boundary conditions for the finite element inputs,which were used to analyze the locking compression plate stress-strain and interfragmentary strain in the standing condition,respectively.RESULTS AND CONCLUSION:(1) The locking compression plate stresses and strains and interfragmentary strains obtained from the musculoskeletal method were,respectively,31.9％,38.9％,and 19.5％ smaller than those obtained from the simplified loading method. (2) A comparison of the musculoskeletal method with the modified simplified loading method revealed that the neglect of muscle loading resulted in an overestimation of locking compression plate stress and strain,as well as interfragmentary strain,by 16.8％,14.3％,and 19.5％,respectively. Muscle loading did not have a significant effect on the magnitude of the shear motion of the fracture block,whereas it did have a significant effect on the direction of motion. (3) The results indicated that the simplified femoral loading and the method of ignoring muscle loading exhibited some deviation from the musculoskeletal loading situation. Consequently,it is necessary to consider the biomechanical effects of muscle loading in the study of fracture healing.

BACKGROUND:The AO12-C type middle-proximal humeral fractures are usually caused by high-energy injuries,accompanied by comminuted fractures and a large number of butterfly-shaped bone fragments.These fractures are difficult to achieve good reduction and effective fixation.With the increasing understanding of the biological characteristics of bone and soft tissue,surgical treatment is gradually shifting towards minimally invasive steel plates and intramedullary nail fixation.However,there has been no consensus on which is the best surgical technique for treating humeral fractures in minimal invasive plate osteosynthesis and intramedullary nail.OBJECTIVE:To compare the clinical effect of minimal invasive plate osteosynthesis and intramedullary nail for treating AO12-C type middle-proximal humeral fractures.METHODS:A retrospective analysis was performed in 36 patients with AO12-C type middle-proximal humeral fracture who met the inclusion criteria admitted to the Guizhou Hospital of Beijing Jishuitan Hospital from January 2020 to December 2022.All patients were assigned to minimal invasive plate osteosynthesis group(18 cases)and intramedullary nail group(18 cases)according to the surgical treatment plan.The minimal invasive plate osteosynthesis group received minimally invasive plate osteosynthesis based on preoperative planning assisted by 3D printing,while the intramedullary nail group received intramedullary nail internal fixation.Operation time,intraoperative blood loss,hospital stay,and fracture healing time were compared between the two groups.Visual analog scale score at 1,3,and 6 months after surgery,shoulder joint function,Constant-Murley score,Quick Disabilities of the Arm,Shoulder and Hand(QuickDASH)score,and complications of the shoulder joint at the last follow-up were compared between the two groups.RESULTS AND CONCLUSION:(1)All patients were followed-up for average(15.56±4.05)months,and no difference was observed in hospital stay and fracture healing time between the two groups(P＞0.05).The minimal invasive plate osteosynthesis group had shorter operation time compared to the intramedullary nail group(P＜0.05).The intramedullary nail group had less intraoperative blood loss between the two groups of patients(P＜0.05).(2)In the intramedullary nail group,at 1 and 3 months after operation,the visual analog scale score was significantly lower than the minimal invasive plate osteosynthesis group(P＜0.05).No difference was observed in the visual analog scale in long-term follow-up,shoulder joint function,Constant-Murley score,Quick Disabilities of the Arm,Shoulder and Hand(QuickDASH)score at the last follow-up between the two groups(P＞0.05).(3)No complications such as nonunion or wound infection occurred in either group.Two cases of radial nerve palsy occurred in minimal invasive plate osteosynthesis group,both of which recovered within 3 months.The intramedullary nail group had 1 case of rotator cuff injury.There was no significant difference in the rate of complications between the two groups(P＞0.05).(4)To conclude,minimal invasive plate osteosynthesis and intramedullary nail can achieve good clinical efficacy in the treatment of AO12-C type middle-proximal humeral fractures,effectively improving shoulder joint function in patients.However,minimal invasive plate osteosynthesis exhibits obvious advantages in shorter surgical time with the assistance of 3D printing,which is a valuable,effective,and safe method for treating AO12-C type middle-proximal humeral fractures.

Hepatocellular carcinoma (HCC) is one of the most common malignant tumors in the world, with the features of insidious onset, low surgical resection rate, and frequent early metastasis and recurrence. With the development of new molecular biology technology in recent years, a liquid biopsy technology, circulating tumor DNA (ctDNA) detection, has achieved encouraging results. This article reviews the current research status and future prospects of ctDNA as a key component of liquid biopsy in patients with HCC, in order to provide new ideas for the clinical treatment of HCC.

0bjective To explore the effects of narrative nursing on posttraumatic growth for patients with amputation. Methods From December 2016 to March 2018,a total of 62 hospitalized patients with amputation were randomly assigned into the control group and the intervention group by random number table.The control group received routine nursing,the intervention group received narrative nursing on the basis of control group.Two groups were evaluated by Posttraumatic Growth Inventory(PTGI) before and after intervention. Results Before intervention,the scores of reflections on life, personal strengths, new possibilities, relating to others, self-transformation and posttraumatic growth in the the control group were (19.87 ± 5.22), (7.90 ± 2.53), (8.83 ± 3.62), (9.73 ± 3.13), (10.63 ± 3.01), (56.97 ± 17.21) points, respectively. After intervention,the scores were (20.80±5.89), (8.80±2.17), (8.90±3.39), (10.27± 2.75), (11.07 ± 3.12), (59.83 ± 16.91) points, respectively, except new possibilities, the scores of each dimension and total scores of posttraumatic growth in the the control group were higher than before,the differences were statistically significant(t=3.00- 5.34, P＜0.05).Before intervention,the scores of reflections on life, personal strengths, new possibilities, relating to others, self-transformation and posttraumatic growth in the the intervention group were (20.28±4.94), (8.17±2.58), (8.59±3.48), (9.55± 2.90), (11.07±2.83), (57.66±16.42) points, respectively. After intervention, the scores were (23.79±4.70), (10.10±2.17), (10.72±3.34), (11.69±2.22), (12.79±3.28),(69.10±14.92) points, respectively, the scores of each dimension and total scores of posttraumatic growth in the intervention group were statistically higher than those in the control group and before intervention,the differences were statistically significant (t=10.61-16.75, P＜0.05). Conclusion Narrative nursing can effectively improve the level of posttraumatic growth and psychological state for patients with amputation.

One major strategy to generate genetically modified mouse models is gene targeting in mouse embryonic stem (ES) cells, which is used to produce gene-targeted mice for wide applications in biomedicine. However, a major bottleneck in this approach is that the robustness of germline transmission of gene-targeted ES cells can be significantly reduced by their genetic and epigenetic instability after long-term culturing, which impairs the efficiency and robustness of mouse model generation. Recently, we have established a new type of pluripotent cells termed extended pluripotent stem (EPS) cells, which have superior developmental potency and robust germline competence compared to conventional mouse ES cells. In this study, we demonstrate that mouse EPS cells well maintain developmental potency and genetic stability after long-term passage. Based on gene targeting in mouse EPS cells, we established a new approach to directly and rapidly generate gene-targeted mouse models through tetraploid complementation, which could be accomplished in approximately 2 months. Importantly, using this approach, we successfully constructed mouse models in which the human interleukin 3 (IL3) or interleukin 6 (IL6) gene was knocked into its corresponding locus in the mouse genome. Our study demonstrates the feasibility of using mouse EPS cells to rapidly generate mouse models by gene targeting, which have great application potential in biomedical research.