Periosteum is a thin fibrous layer that covers most bones. It resides in a dynamic mechanically loaded environment and provides a niche for pluripotent cells and a source for molecular factors that modulate cell behav...Periosteum is a thin fibrous layer that covers most bones. It resides in a dynamic mechanically loaded environment and provides a niche for pluripotent cells and a source for molecular factors that modulate cell behaviour. Elucidating periosteum regenerative poten-tial has become a hot topic in orthopaedics. This review discusses the state of the art of osteochondral tissue engineering rested on periosteum derived progenitor cells(PDPCs) and suggests upcoming research direc-tions. Periosteal cells isolation, characterization and migration in the site of injury, as well as their differen-tiation, are analysed. Moreover, the role of cell mecha-nosensing and its contribution to matrix organization, bone microarchitecture and bone stenght is examined. In this regard the role of periostin and its upregulation under mechanical stress in order to preserve PDPC sur-vival and bone tissue integrity is contemplated. The re-view also summarized the role of the periosteum in the field of dentistry and maxillofacial reconstruction. The involvement of microRNAs in osteoblast differentiation and in endogenous tissue repair is explored as well. Fi-nally the novel concept of a guided bone regenerationbased on the use of periosteum itself as a smart mate-rial and the realization of constructs able to mimic the extracellular matrix features is talked out. Additionally, since periosteum can differentiate into insulin produc-ing cells it could be a suitable source in allogenic trans-plantations. That innovative applications would takeadvantage from investigations aimed to assess PDPCimmune privilege.展开更多
Objective: To study the efficacy of combined use of a new grafting material, new reconstituted bone xenograft (NRBX) and free periosteal graft in repair of segmental bony defects. Methods: NRBX was made by combining r...Objective: To study the efficacy of combined use of a new grafting material, new reconstituted bone xenograft (NRBX) and free periosteal graft in repair of segmental bony defects. Methods: NRBX was made by combining recombi- nant human BMP2(rhBMP2) and an antigen-free bovine cancellous bone (BCB) as a carrier. NRBX was used alone, in combination with free periosteal graft to repair a 1. 5 cm defect in the radius of rabbit. The defect-repairing capability for each of the treatment modalities was assessed with radiographical, biomechanical, densitometrical and histological methods. Results: NRBX used alone was capable of healing the defect in large by 16 weeks, with a similar repair process and mecha- nism seen with econstituted bone xenograft (RBX). Combined use of NRBX and free periosteal graft was superior in terms of increased and quality of the new bone formed at the early stage of the repair pass (within 12 weeks) to NRBX used alone, with the defect basically healed by 12 weeks. Conclusion: Both methods are effective in repairing segmental bone defects, but NRBX used in combination with free periosteal graft is preferred, because of the satisfactory osteogenesis, osteoconduction and osteoinduction.展开更多
Periosteum,a membrane covering the surface of the bone,plays an essential role in maintaining the function of bone tissue—and especially in providing nourishment and vascularization during the bone regeneration proce...Periosteum,a membrane covering the surface of the bone,plays an essential role in maintaining the function of bone tissue—and especially in providing nourishment and vascularization during the bone regeneration process.Currently,most artificial periostea have relatively weak mechanical strength and a rapid degradation rate,and they lack integrated angiogenesis and osteogenesis functions.In this study,a bi-layer,biomimetic,artificial periosteum composed of a methacrylated gelatin–nano-hydroxyapatite(GelMA-nHA)cambium layer and a poly(N-acryloyl 2-lycine)(PACG)-GelMA-Mg^(2+)fibrous layer was fabricated via 3D printing.The GelMA-nHA layer is shown to undertake the function of improving osteogenic differentiation of rat bone marrow mesenchymal stem cells with the sustainable release of Ca^(2+) from nHA nanoparticles.The hydrogen-bonding-strengthened P(ACG-GelMA-L)-Mg^(2+)hydrogel layer serves to protect the inner defect site and prolong degradation time(60 days)to match new bone regeneration.Furthermore,the released magnesium ion exhibits a prominent effect in regulating the polarization phenotype of macrophage cells into theM2 phenotype and thus promotes the angiogenesis of the human umbilical vein endothelial cells in vitro.This bi-layer artificial periosteum was implanted into a critical-sized cranial bone defect in rats,and the 12-week post-operative outcomes demonstrate optimal new bone regeneration.展开更多
BACKGROUND Nodular fasciitis(NF)is a self-limiting tumor that mostly occurs in the subcutaneous superficial fascia.NF originating from the appendicular periosteum is extremely rare.A large NF lesion of periosteal orig...BACKGROUND Nodular fasciitis(NF)is a self-limiting tumor that mostly occurs in the subcutaneous superficial fascia.NF originating from the appendicular periosteum is extremely rare.A large NF lesion of periosteal origin can be misdiagnosed as a malignant bone tumor and may cause overtreatment.CASE SUMMARY A right axillary mass was found in a 46-year-old man and was initially diagnosed intraoperatively as low-grade sarcoma,but later diagnosed as NF after postresection histopathological evaluation.Furthermore,fluorescence in situ hybridization analysis revealed a USP6 gene rearrangement that confirmed the diagnosis.To the best of our knowledge,this is the first case of NF in the humeral periosteum.CONCLUSION NF poses a diagnostic challenge as it is often mistaken for sarcoma.Postoperative histopathological examination of whole sections can be combined with immunohistochemical staining and,if necessary,the diagnosis can be confirmed by molecular detection,and thus help avoid overtreatment.展开更多
Backgrounds: Reconstruction after hemipelvectomy is very important for rehabilitation into society. The pelvis plays an important role for support of the intra-abdominal organs. Methods: We operated 3 cases using fill...Backgrounds: Reconstruction after hemipelvectomy is very important for rehabilitation into society. The pelvis plays an important role for support of the intra-abdominal organs. Methods: We operated 3 cases using fillet flaps with the femoral periosteum for reconstruction of hemipelvectomy defect. Results: It is useful to elevate the flap all around with the femoral periosteum, because the periosteum can be sutured to supporting pelvic structures with the aim to support intra-abdominal organs. Conclusion: Without alternative supports for the bony pelvis, pelvic reconstructions are at risk for hernia and it may be difficult for outpatients to fit their habiliments after radical cure. The rigid support for the intra-abdominal organs occurs in association with the suture pelvic and femoral periosteum.展开更多
To reconstruct tracheal defect after tumor excision,we used the contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum.Methods The contralateral musculo-periosteum flap of the s...To reconstruct tracheal defect after tumor excision,we used the contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum.Methods The contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum was used to reconstruct the tracheal defect when the blood supply to the ipsilateral sternocleidomastoideus was destroyed because of lymphonode clearing or radiotherapy.The pedicle of the musculo-periosteum flap was dissected adequately and the blood supply was protected carefully.Results All flaps survived with epithelization and osteogenesis.The endotracheal tubes were pulled out safely without trachea stenosis in all the patients.Conclusion The contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum could reconstruct the tracheal defect when the ipsilateral blood supply was damaged.This method extends the application of the musculo-periosteum flap.3 refs,4 figs.展开更多
The use of periosteum-derived progenitor cells (PCs) combined with bioresorbable materials is an attractive approach for tissue engineering. The aim of this study was to characterize the osteogenic differentiation of ...The use of periosteum-derived progenitor cells (PCs) combined with bioresorbable materials is an attractive approach for tissue engineering. The aim of this study was to characterize the osteogenic differentiation of PC in 3-dimensional (3D) poly-lactic-co-glycolic acid (PLGA) fleeces cultured in medium containing allogeneic human serum. PCs were isolated and expanded in monolayer culture. Expanded cells of passage 3 were seeded into PLGA constructs and cultured in osteogenic me- dium for a maximum period of 28 d. Morphological, histological and cell viability analyses of three-dimensionally cultured PCs were performed to elucidate osseous synthesis and deposition of a calcified matrix. Furthermore, the mRNA expression of type I collagen, osteocalcin and osteonectin was semi-quantitively evaluated by real-time reverse transcriptase-polymerase chain reac- tion (RT-PCR). The fibrin gel immobilization technique provided homogeneous PCs distribution in 3D PLGA constructs. Live-dead staining indicated a high viability rate of PCs inside the PLGA scaffolds. Secreted nodules of neo-bone tissue formation and the presence of matrix mineralization were confirmed by positive von Kossa staining. The osteogenic differentiation of PCs was further demonstrated by the detection of type I collagen, osteocalcin and osteonectin gene expression. The results of this study support the concept that this tissue engineering method presents a promising method for creation of new bone in vivo.展开更多
目的分析并对比自体带骨膜髂骨移植与同种异体骨骨粉联合富血小板凝胶(platelet rich gel,PRP)治疗HeppleⅤ型距骨骨软骨损伤(osteochondral injury,OLT)。方法选取浙江中医药大学附属金华中医院2018年10月至2022年10月收入的HeppleⅤ型...目的分析并对比自体带骨膜髂骨移植与同种异体骨骨粉联合富血小板凝胶(platelet rich gel,PRP)治疗HeppleⅤ型距骨骨软骨损伤(osteochondral injury,OLT)。方法选取浙江中医药大学附属金华中医院2018年10月至2022年10月收入的HeppleⅤ型OLT患者62例为研究对象,根据其治疗方式将其分为移植组(接受自体带骨膜髂骨移植治疗,31例)、联合组(接受同种异体骨骨粉联合PRP治疗,31例)。对患者进行术后12个月门诊随访研究,评估并比较两组患者术后12个月治疗效果、踝关节活动度(range of motion,ROM)、美国骨科足踝外科学会(American Society of Orthopedic Foot andAnkle Surgeons,AOFAS)踝-后足评分、疼痛评分、满意度、并发症发生率差异。结果移植组治疗总有效率(96.77%)与联合组(93.55%)相比,差异无统计学意义(P>0.05)。术后12个月两组ROM、AOFAS评分均改善(P<0.05),组间差异无统计学意义(P>0.05)。两组患者术后1个月、3个月、6个月、12个月,两组疼痛评分均较术前有所降低(P<0.05)。移植组患者主观总满意度(77.42%),低于联合组(96.77%,P<0.05)。移植组并发症总发生率(19.35%)与联合组(3.23%)相比,明显更高(P<0.05)。结论同种异体骨骨粉联合PRP可避免额外手术切口,患者主观满意度更高,术后并发症发生率低。展开更多
Treatment of bone defects still poses a great challenge in orthopedic clinics, and the vital role of periosteum in such processes has attracted widespread attention. However, studies focusing on the oxidative stress m...Treatment of bone defects still poses a great challenge in orthopedic clinics, and the vital role of periosteum in such processes has attracted widespread attention. However, studies focusing on the oxidative stress micro-environment with an artificial periosteum at the site of defect have been scarce. The intrinsic anti-oxidative properties and therapeutic potential for bone defects of metal-phenolic networks(MPNs)have provided a potential solution to this. Herein, we have developed a protocatechualdehyde + zinc ion(PCA+Zn^(Ⅱ)) MPN coating on a thermoplastic polyurethane membrane with a one-pot method to fabricate a new-type of periosteum with meritorious biocompatibility and abilities of modulating oxidative stress condition and promoting osteogenesis and mineralization for better bone regeneration, which has shown to be a promising strategy for constructing artificial periosteum with various MPNs.展开更多
Periosteum is a thin membrane that encases the surfaces of most bones.It is composed of an outer fibrous layer contains longitudinally oriented cells and collagen fibers and an inner cambial layer that consists of mul...Periosteum is a thin membrane that encases the surfaces of most bones.It is composed of an outer fibrous layer contains longitudinally oriented cells and collagen fibers and an inner cambial layer that consists of multipotent mesenchymal stem cells(MSCs)and osteogenic progenitor cells.Periosteum has a function of regulating cell and collagen arrangement,which is important to the integrity,modelling and remodelling of bone,particularly during bone defect repair.Apart from autograft and allograft,artificial periosteum,or tissue-engineered periosteum mimicking native periosteum in structure or function,made up of small intestinal submucosa,acellular dermis,induced membrane,cell sheets,and polymeric scaffolds,and so on,has been developed to be used in bone defect repair.In this review,we classify the artificial periosteum into three approaches based on the material source,that is,native tissues,scaffoldfree cell sheets and scaffold-cell composites.Mechanisms,methods and efficacy of each approach are provided.Existing obstacles and enabling technologies for future directions are also discussed.展开更多
The experimental research, presented in this study, focuses on athletic tests with the purpose to highlight the elastic deformations of the bones of the lower limbs, intending to verify whether the manually treated an...The experimental research, presented in this study, focuses on athletic tests with the purpose to highlight the elastic deformations of the bones of the lower limbs, intending to verify whether the manually treated anatomical structure increases in elasticity, becoming able to accumulate more energy in the loading phase, to then release it in the final phase of the thrust. Introduction: Too often neglected, the bone tissue is capable of deforming. The deformation has a key role in the cushioning and dissipation of stress, a function that is hindered in the event of fascial tension, which will consequently fall on other structures used for the same purpose (Discs, menisci, cartilage, …). Structures that, in the event of increased mechanical stress, could undergo degeneration, inflammation, and injury. Materials and Method: Randomized double-blind selection of 38 people, 18 in the treatment group and 20 in the control group, men and women, aged between 16 and 35, who have been part, for at least one year, of a sports club, with a large space dedicated to jumping in its training program, have been divided into two groups: the treatment group, which was treated to increase the performance of the jump and the control group subjected to mild manual pressures, without any intention. Results: The treatment group had an increase in Standing Long Jump (SLJ) for 3.67% (p Conclusions: This study has shown that an osteopathic manipulative treatment, aimed at increasing jumping performance, can increase the performance of the SLJ.展开更多
基金Supported by Italian FIRB and PRIN project grants,No.2010J8RYS7 and No.RBAP10MLK7
文摘Periosteum is a thin fibrous layer that covers most bones. It resides in a dynamic mechanically loaded environment and provides a niche for pluripotent cells and a source for molecular factors that modulate cell behaviour. Elucidating periosteum regenerative poten-tial has become a hot topic in orthopaedics. This review discusses the state of the art of osteochondral tissue engineering rested on periosteum derived progenitor cells(PDPCs) and suggests upcoming research direc-tions. Periosteal cells isolation, characterization and migration in the site of injury, as well as their differen-tiation, are analysed. Moreover, the role of cell mecha-nosensing and its contribution to matrix organization, bone microarchitecture and bone stenght is examined. In this regard the role of periostin and its upregulation under mechanical stress in order to preserve PDPC sur-vival and bone tissue integrity is contemplated. The re-view also summarized the role of the periosteum in the field of dentistry and maxillofacial reconstruction. The involvement of microRNAs in osteoblast differentiation and in endogenous tissue repair is explored as well. Fi-nally the novel concept of a guided bone regenerationbased on the use of periosteum itself as a smart mate-rial and the realization of constructs able to mimic the extracellular matrix features is talked out. Additionally, since periosteum can differentiate into insulin produc-ing cells it could be a suitable source in allogenic trans-plantations. That innovative applications would takeadvantage from investigations aimed to assess PDPCimmune privilege.
文摘Objective: To study the efficacy of combined use of a new grafting material, new reconstituted bone xenograft (NRBX) and free periosteal graft in repair of segmental bony defects. Methods: NRBX was made by combining recombi- nant human BMP2(rhBMP2) and an antigen-free bovine cancellous bone (BCB) as a carrier. NRBX was used alone, in combination with free periosteal graft to repair a 1. 5 cm defect in the radius of rabbit. The defect-repairing capability for each of the treatment modalities was assessed with radiographical, biomechanical, densitometrical and histological methods. Results: NRBX used alone was capable of healing the defect in large by 16 weeks, with a similar repair process and mecha- nism seen with econstituted bone xenograft (RBX). Combined use of NRBX and free periosteal graft was superior in terms of increased and quality of the new bone formed at the early stage of the repair pass (within 12 weeks) to NRBX used alone, with the defect basically healed by 12 weeks. Conclusion: Both methods are effective in repairing segmental bone defects, but NRBX used in combination with free periosteal graft is preferred, because of the satisfactory osteogenesis, osteoconduction and osteoinduction.
基金the National Key Research and Development Program(No.2018YFA0703100)the National Natural Science Foundation of China(No.51733006).
文摘Periosteum,a membrane covering the surface of the bone,plays an essential role in maintaining the function of bone tissue—and especially in providing nourishment and vascularization during the bone regeneration process.Currently,most artificial periostea have relatively weak mechanical strength and a rapid degradation rate,and they lack integrated angiogenesis and osteogenesis functions.In this study,a bi-layer,biomimetic,artificial periosteum composed of a methacrylated gelatin–nano-hydroxyapatite(GelMA-nHA)cambium layer and a poly(N-acryloyl 2-lycine)(PACG)-GelMA-Mg^(2+)fibrous layer was fabricated via 3D printing.The GelMA-nHA layer is shown to undertake the function of improving osteogenic differentiation of rat bone marrow mesenchymal stem cells with the sustainable release of Ca^(2+) from nHA nanoparticles.The hydrogen-bonding-strengthened P(ACG-GelMA-L)-Mg^(2+)hydrogel layer serves to protect the inner defect site and prolong degradation time(60 days)to match new bone regeneration.Furthermore,the released magnesium ion exhibits a prominent effect in regulating the polarization phenotype of macrophage cells into theM2 phenotype and thus promotes the angiogenesis of the human umbilical vein endothelial cells in vitro.This bi-layer artificial periosteum was implanted into a critical-sized cranial bone defect in rats,and the 12-week post-operative outcomes demonstrate optimal new bone regeneration.
基金Supported by Jilin Province Department of Finance Project,No.2019SCZT005,No.2019SRCJ007 and No.2020SCZT007National Natural Science Foundation of China,No.81902342and Health Commission of Jilin Province,No.2019Q002.
文摘BACKGROUND Nodular fasciitis(NF)is a self-limiting tumor that mostly occurs in the subcutaneous superficial fascia.NF originating from the appendicular periosteum is extremely rare.A large NF lesion of periosteal origin can be misdiagnosed as a malignant bone tumor and may cause overtreatment.CASE SUMMARY A right axillary mass was found in a 46-year-old man and was initially diagnosed intraoperatively as low-grade sarcoma,but later diagnosed as NF after postresection histopathological evaluation.Furthermore,fluorescence in situ hybridization analysis revealed a USP6 gene rearrangement that confirmed the diagnosis.To the best of our knowledge,this is the first case of NF in the humeral periosteum.CONCLUSION NF poses a diagnostic challenge as it is often mistaken for sarcoma.Postoperative histopathological examination of whole sections can be combined with immunohistochemical staining and,if necessary,the diagnosis can be confirmed by molecular detection,and thus help avoid overtreatment.
文摘Backgrounds: Reconstruction after hemipelvectomy is very important for rehabilitation into society. The pelvis plays an important role for support of the intra-abdominal organs. Methods: We operated 3 cases using fillet flaps with the femoral periosteum for reconstruction of hemipelvectomy defect. Results: It is useful to elevate the flap all around with the femoral periosteum, because the periosteum can be sutured to supporting pelvic structures with the aim to support intra-abdominal organs. Conclusion: Without alternative supports for the bony pelvis, pelvic reconstructions are at risk for hernia and it may be difficult for outpatients to fit their habiliments after radical cure. The rigid support for the intra-abdominal organs occurs in association with the suture pelvic and femoral periosteum.
文摘To reconstruct tracheal defect after tumor excision,we used the contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum.Methods The contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum was used to reconstruct the tracheal defect when the blood supply to the ipsilateral sternocleidomastoideus was destroyed because of lymphonode clearing or radiotherapy.The pedicle of the musculo-periosteum flap was dissected adequately and the blood supply was protected carefully.Results All flaps survived with epithelization and osteogenesis.The endotracheal tubes were pulled out safely without trachea stenosis in all the patients.Conclusion The contralateral musculo-periosteum flap of the sternocleidomastoideus with clavicular periosteum could reconstruct the tracheal defect when the ipsilateral blood supply was damaged.This method extends the application of the musculo-periosteum flap.3 refs,4 figs.
基金Project supported by the Investitionsbank Berlin (IBB), Germany (No. 10020666) and the Science and Technology Bureau of ZhejiangProvince, China (No. 991110052)
文摘The use of periosteum-derived progenitor cells (PCs) combined with bioresorbable materials is an attractive approach for tissue engineering. The aim of this study was to characterize the osteogenic differentiation of PC in 3-dimensional (3D) poly-lactic-co-glycolic acid (PLGA) fleeces cultured in medium containing allogeneic human serum. PCs were isolated and expanded in monolayer culture. Expanded cells of passage 3 were seeded into PLGA constructs and cultured in osteogenic me- dium for a maximum period of 28 d. Morphological, histological and cell viability analyses of three-dimensionally cultured PCs were performed to elucidate osseous synthesis and deposition of a calcified matrix. Furthermore, the mRNA expression of type I collagen, osteocalcin and osteonectin was semi-quantitively evaluated by real-time reverse transcriptase-polymerase chain reac- tion (RT-PCR). The fibrin gel immobilization technique provided homogeneous PCs distribution in 3D PLGA constructs. Live-dead staining indicated a high viability rate of PCs inside the PLGA scaffolds. Secreted nodules of neo-bone tissue formation and the presence of matrix mineralization were confirmed by positive von Kossa staining. The osteogenic differentiation of PCs was further demonstrated by the detection of type I collagen, osteocalcin and osteonectin gene expression. The results of this study support the concept that this tissue engineering method presents a promising method for creation of new bone in vivo.
文摘目的分析并对比自体带骨膜髂骨移植与同种异体骨骨粉联合富血小板凝胶(platelet rich gel,PRP)治疗HeppleⅤ型距骨骨软骨损伤(osteochondral injury,OLT)。方法选取浙江中医药大学附属金华中医院2018年10月至2022年10月收入的HeppleⅤ型OLT患者62例为研究对象,根据其治疗方式将其分为移植组(接受自体带骨膜髂骨移植治疗,31例)、联合组(接受同种异体骨骨粉联合PRP治疗,31例)。对患者进行术后12个月门诊随访研究,评估并比较两组患者术后12个月治疗效果、踝关节活动度(range of motion,ROM)、美国骨科足踝外科学会(American Society of Orthopedic Foot andAnkle Surgeons,AOFAS)踝-后足评分、疼痛评分、满意度、并发症发生率差异。结果移植组治疗总有效率(96.77%)与联合组(93.55%)相比,差异无统计学意义(P>0.05)。术后12个月两组ROM、AOFAS评分均改善(P<0.05),组间差异无统计学意义(P>0.05)。两组患者术后1个月、3个月、6个月、12个月,两组疼痛评分均较术前有所降低(P<0.05)。移植组患者主观总满意度(77.42%),低于联合组(96.77%,P<0.05)。移植组并发症总发生率(19.35%)与联合组(3.23%)相比,明显更高(P<0.05)。结论同种异体骨骨粉联合PRP可避免额外手术切口,患者主观满意度更高,术后并发症发生率低。
基金supported by the 1.3.5 Project for Disciplines of Excellence,West China Hospital,Sichuan University (No.ZYJC18002)。
文摘Treatment of bone defects still poses a great challenge in orthopedic clinics, and the vital role of periosteum in such processes has attracted widespread attention. However, studies focusing on the oxidative stress micro-environment with an artificial periosteum at the site of defect have been scarce. The intrinsic anti-oxidative properties and therapeutic potential for bone defects of metal-phenolic networks(MPNs)have provided a potential solution to this. Herein, we have developed a protocatechualdehyde + zinc ion(PCA+Zn^(Ⅱ)) MPN coating on a thermoplastic polyurethane membrane with a one-pot method to fabricate a new-type of periosteum with meritorious biocompatibility and abilities of modulating oxidative stress condition and promoting osteogenesis and mineralization for better bone regeneration, which has shown to be a promising strategy for constructing artificial periosteum with various MPNs.
基金financially supported by National Natural Science Foundation of China(Nos.31525009 and 31271021)National 863 Project(No.2015AA020316)+2 种基金Sichuan Innovative Research Team Program for Young Scientists(No.2016TD0004)Zhejiang Provincial Science and Technology Grant(No.2017C33100)Zhejiang Provincial Natural Science Foundation of China(No.LY17H060010)
文摘Periosteum is a thin membrane that encases the surfaces of most bones.It is composed of an outer fibrous layer contains longitudinally oriented cells and collagen fibers and an inner cambial layer that consists of multipotent mesenchymal stem cells(MSCs)and osteogenic progenitor cells.Periosteum has a function of regulating cell and collagen arrangement,which is important to the integrity,modelling and remodelling of bone,particularly during bone defect repair.Apart from autograft and allograft,artificial periosteum,or tissue-engineered periosteum mimicking native periosteum in structure or function,made up of small intestinal submucosa,acellular dermis,induced membrane,cell sheets,and polymeric scaffolds,and so on,has been developed to be used in bone defect repair.In this review,we classify the artificial periosteum into three approaches based on the material source,that is,native tissues,scaffoldfree cell sheets and scaffold-cell composites.Mechanisms,methods and efficacy of each approach are provided.Existing obstacles and enabling technologies for future directions are also discussed.
文摘The experimental research, presented in this study, focuses on athletic tests with the purpose to highlight the elastic deformations of the bones of the lower limbs, intending to verify whether the manually treated anatomical structure increases in elasticity, becoming able to accumulate more energy in the loading phase, to then release it in the final phase of the thrust. Introduction: Too often neglected, the bone tissue is capable of deforming. The deformation has a key role in the cushioning and dissipation of stress, a function that is hindered in the event of fascial tension, which will consequently fall on other structures used for the same purpose (Discs, menisci, cartilage, …). Structures that, in the event of increased mechanical stress, could undergo degeneration, inflammation, and injury. Materials and Method: Randomized double-blind selection of 38 people, 18 in the treatment group and 20 in the control group, men and women, aged between 16 and 35, who have been part, for at least one year, of a sports club, with a large space dedicated to jumping in its training program, have been divided into two groups: the treatment group, which was treated to increase the performance of the jump and the control group subjected to mild manual pressures, without any intention. Results: The treatment group had an increase in Standing Long Jump (SLJ) for 3.67% (p Conclusions: This study has shown that an osteopathic manipulative treatment, aimed at increasing jumping performance, can increase the performance of the SLJ.