Osteoporosis is one of the common orthopaedic diseases,characterised by increased bone fragility due to reduced bone mass and microstructural degeneration,posing a great threat to patients’quality of life and safety....Osteoporosis is one of the common orthopaedic diseases,characterised by increased bone fragility due to reduced bone mass and microstructural degeneration,posing a great threat to patients’quality of life and safety.In recent years,Chinese medicine(natural)has had a unique advantage in the treatment of osteoporosis and has shown good efficacy.Autophagy is an inherent cellular survival mechanism for the removal and recycling of damaged proteins and organelles and plays an important role in maintaining the stability of the intracellular environment and organ function.Therefore,this article aims to provide a comprehensive review of these Chinese medicines(natural)for the treatment of osteoporosis through autophagy.They have been intensively studied and reported to have effects such as promoting osteogenesis and anti-bone resorption.The Chinese medicines include plants such as Cistanche deserticola,Epimedium,Curculigo orchioides Gaertn,Achyranthes bidentata Blume,Leonurus japonicus Houtt,Ginseng,Chuanxiong Rhizome,Eucommia ulmoides,Morindae Officinalis Radix,Curcuma longa,Polygoni Cuspidati Rhizoma et Radix,Anemarrhena asphodeloides Bunge,Salvia miltiorrhiza Bge and Pueraria Lobata,thus providing evidence for the use of alternative herbal therapies for the effective treatment of osteoporosis.展开更多
BACKGROUND Hourglass-like constriction neuropathy is a rare neurological disorder.The main clinical manifestation is peripheral nerve injury with no apparent cause,and the pathomorphological change is an unexplained n...BACKGROUND Hourglass-like constriction neuropathy is a rare neurological disorder.The main clinical manifestation is peripheral nerve injury with no apparent cause,and the pathomorphological change is an unexplained narrowing of the diseased nerve.The diagnosis and treatment of the disease are challenging and there is no accepted diagnostic or therapeutic approach.CASE SUMMARY This report describes a rare hourglass constriction of the anterior interosseous nerve in the left forearm in a 47-year-old healthy male who was treated surgically and gradually recovered function over a 6-mo follow-up period.CONCLUSION Hourglass-like constriction neuropathy is a rare disorder.With the development of medical technology,more examinations are now available for diagnosis.This case aims to highlight the rare manifestations of Hourglass-like constriction neuropathy and provides a reference for enriching the clinical diagnosis and treatment experience.展开更多
The repair of osteochondral defects is one of the major clinical challenges in orthopaedics.Well-established osteochondral tissue engineering methods have shown promising results for the early treatment of small defec...The repair of osteochondral defects is one of the major clinical challenges in orthopaedics.Well-established osteochondral tissue engineering methods have shown promising results for the early treatment of small defects.However,less success has been achieved for the regeneration of large defects,which is mainly due to the mechanical environment of the joint and the heterogeneous nature of the tissue.In this study,we developed a multi-layered osteochondral scaffold to match the heterogeneous nature of osteochondral tissue by harnessing additive manufacturing technologies and combining the established art laser sintering and material extrusion techniques.The developed scaffold is based on a titanium and polylactic acid matrix-reinforced collagen“sandwich”composite system.The microstructure and mechanical properties of the scaffold were examined,and its safety and efficacy in the repair of large osteochondral defects were tested in an ovine condyle model.The 12-week in vivo evaluation period revealed extensive and significantly higher bone in-growth in the multi-layered scaffold compared with the collagen–HAp scaffold,and the achieved stable mechanical fixation provided strong support to the healing of the overlying cartilage,as demonstrated by hyaline-like cartilage formation.The histological examination showed that the regenerated cartilage in the multi-layer scaffold group was superior to that formed in the control group.Chondrogenic genes such as aggrecan and collagen-II were upregulated in the scaffold and were higher than those in the control group.The findings showed the safety and efficacy of the cell-free“translation-ready”osteochondral scaffold,which has the potential to be used in a one-step surgical procedure for the treatment of large osteochondral defects.展开更多
Tissue-engineered cartilage(TEC)remains a potential alternative for the repair of articular cartilage defects.However,there has been a significant different between the properties of TEC and those of natural cartilage...Tissue-engineered cartilage(TEC)remains a potential alternative for the repair of articular cartilage defects.However,there has been a significant different between the properties of TEC and those of natural cartilage.Studies have shown that mechanical stimulation such as compressive load can help regulate matrix remodelling in TEC,thus affecting its biomechanical properties.However,the influences of shear induced from the tissue fluid phase have not been well studied and may play an important role in tissue regeneration especially when integrated with the compressive load.Therefore,the aim of this study was to quantitatively investigate the effects of combined loading mechanisms on TEC in vitro.A bespoke biosimulator was built to incorporate the coupled motion of compression,friction and shear.The specimens,encapsulating freshly isolated rabbit chondrocytes in a hydrogel,were cultured within the biosimulator under various mechanical stimulations for 4 weeks,and the tissue activity,matrix contents and the mechanical properties were examined.Study groups were categorized according to different mechanical stimulation combinations,including strain(5-20%at 5%intervals)and frequency(0.25 Hz,0.5 Hz,1 Hz),and the effects on tissue behaviour were investigated.During the dynamic culture process,a combined load was applied to simulate the combined effects of compression,friction and shear on articular cartilage during human movement.The results indicated that a larger strain and higher frequency were more favourable for the specimen in terms of the cell proliferation and extracellular matrix synthesis.Moreover,the combined mechanical stimulation was more beneficial to matrix remodelling than the single loading motion.However,the contribution of the combined mechanical stimulation to the engineered cartilaginous tissue matrix was not sufficient to impede biodegradation of the tissue with culture time.展开更多
Polycaprolactone-carboxymethyl cellulose composites have been obtained and used to print porous structures by material extrusion.The materials used contained 0,2 and 5% w/w of the carboxymethyl cellulose additive.Thes...Polycaprolactone-carboxymethyl cellulose composites have been obtained and used to print porous structures by material extrusion.The materials used contained 0,2 and 5% w/w of the carboxymethyl cellulose additive.These structures have been analyzed in terms of their morphology (including the evaluation of their porosity),mechanical properties under compression load and cell affinity.Cell affinity has been evaluated by culturing sheep mesenchymal stem cells and analyzing their viability by the Alamar Blue(R)assay at days 1,3,6 and 8.The results show that composites samples have similar values of porosity and apparent density than pure polycaprolactone ones.However,samples containing 5%w/w of carboxymethyl cellulose have micropores on the filaments due to a hindered deposition process.This characteristic affects the mechanical properties of the structures,so these ones have a mean compression modulus significantly lower than pure polycaprolactone scaffolds.However, the samples containing 2%w/w of carboxymethyl cellulose show no significant difference with the pure polycaprolactone ones in terms of their mechanical properties.Moreover,the presence of 2%w/w of additive improves cell proliferation on the surface of the porous structures.As complementary information,the flow properties of the composite materials were studied and the power law equations at 210℃ obtained,as this temperature was the 3D printing temperature.These equations can be useful for simulation and designing purposes of other manufacturing processes.展开更多
基金the financial support from the Science and Technology Development Program of Jilin Provincial Science and Technology Department,(No.20210101200JC).
文摘Osteoporosis is one of the common orthopaedic diseases,characterised by increased bone fragility due to reduced bone mass and microstructural degeneration,posing a great threat to patients’quality of life and safety.In recent years,Chinese medicine(natural)has had a unique advantage in the treatment of osteoporosis and has shown good efficacy.Autophagy is an inherent cellular survival mechanism for the removal and recycling of damaged proteins and organelles and plays an important role in maintaining the stability of the intracellular environment and organ function.Therefore,this article aims to provide a comprehensive review of these Chinese medicines(natural)for the treatment of osteoporosis through autophagy.They have been intensively studied and reported to have effects such as promoting osteogenesis and anti-bone resorption.The Chinese medicines include plants such as Cistanche deserticola,Epimedium,Curculigo orchioides Gaertn,Achyranthes bidentata Blume,Leonurus japonicus Houtt,Ginseng,Chuanxiong Rhizome,Eucommia ulmoides,Morindae Officinalis Radix,Curcuma longa,Polygoni Cuspidati Rhizoma et Radix,Anemarrhena asphodeloides Bunge,Salvia miltiorrhiza Bge and Pueraria Lobata,thus providing evidence for the use of alternative herbal therapies for the effective treatment of osteoporosis.
文摘BACKGROUND Hourglass-like constriction neuropathy is a rare neurological disorder.The main clinical manifestation is peripheral nerve injury with no apparent cause,and the pathomorphological change is an unexplained narrowing of the diseased nerve.The diagnosis and treatment of the disease are challenging and there is no accepted diagnostic or therapeutic approach.CASE SUMMARY This report describes a rare hourglass constriction of the anterior interosseous nerve in the left forearm in a 47-year-old healthy male who was treated surgically and gradually recovered function over a 6-mo follow-up period.CONCLUSION Hourglass-like constriction neuropathy is a rare disorder.With the development of medical technology,more examinations are now available for diagnosis.This case aims to highlight the rare manifestations of Hourglass-like constriction neuropathy and provides a reference for enriching the clinical diagnosis and treatment experience.
基金financially supported by the Versus Arthritis (No. 21160)the Rosetree Trust (No. A1184)+2 种基金the European Commission via H2020-MSCA-RISE Program (BAMOS Project (No.734156))Innovate UK via Newton Fund (No. 102872)the Engineering and Physical Science Research Council (EPSRC) via DTP Case Programme (No. EP/T517793/1)
文摘The repair of osteochondral defects is one of the major clinical challenges in orthopaedics.Well-established osteochondral tissue engineering methods have shown promising results for the early treatment of small defects.However,less success has been achieved for the regeneration of large defects,which is mainly due to the mechanical environment of the joint and the heterogeneous nature of the tissue.In this study,we developed a multi-layered osteochondral scaffold to match the heterogeneous nature of osteochondral tissue by harnessing additive manufacturing technologies and combining the established art laser sintering and material extrusion techniques.The developed scaffold is based on a titanium and polylactic acid matrix-reinforced collagen“sandwich”composite system.The microstructure and mechanical properties of the scaffold were examined,and its safety and efficacy in the repair of large osteochondral defects were tested in an ovine condyle model.The 12-week in vivo evaluation period revealed extensive and significantly higher bone in-growth in the multi-layered scaffold compared with the collagen–HAp scaffold,and the achieved stable mechanical fixation provided strong support to the healing of the overlying cartilage,as demonstrated by hyaline-like cartilage formation.The histological examination showed that the regenerated cartilage in the multi-layer scaffold group was superior to that formed in the control group.Chondrogenic genes such as aggrecan and collagen-II were upregulated in the scaffold and were higher than those in the control group.The findings showed the safety and efficacy of the cell-free“translation-ready”osteochondral scaffold,which has the potential to be used in a one-step surgical procedure for the treatment of large osteochondral defects.
基金The work was supported by National Key R&D Program of China[2018YFE0207900]Key R&D Program of Guangdong Province[2018B090906001]the Fundamental Research Funds for the Central Universities and the Youth Innovation Team of Shaanxi Universities and the EU via the H2020-MSCA-RISE-2016 program[734156].
文摘Tissue-engineered cartilage(TEC)remains a potential alternative for the repair of articular cartilage defects.However,there has been a significant different between the properties of TEC and those of natural cartilage.Studies have shown that mechanical stimulation such as compressive load can help regulate matrix remodelling in TEC,thus affecting its biomechanical properties.However,the influences of shear induced from the tissue fluid phase have not been well studied and may play an important role in tissue regeneration especially when integrated with the compressive load.Therefore,the aim of this study was to quantitatively investigate the effects of combined loading mechanisms on TEC in vitro.A bespoke biosimulator was built to incorporate the coupled motion of compression,friction and shear.The specimens,encapsulating freshly isolated rabbit chondrocytes in a hydrogel,were cultured within the biosimulator under various mechanical stimulations for 4 weeks,and the tissue activity,matrix contents and the mechanical properties were examined.Study groups were categorized according to different mechanical stimulation combinations,including strain(5-20%at 5%intervals)and frequency(0.25 Hz,0.5 Hz,1 Hz),and the effects on tissue behaviour were investigated.During the dynamic culture process,a combined load was applied to simulate the combined effects of compression,friction and shear on articular cartilage during human movement.The results indicated that a larger strain and higher frequency were more favourable for the specimen in terms of the cell proliferation and extracellular matrix synthesis.Moreover,the combined mechanical stimulation was more beneficial to matrix remodelling than the single loading motion.However,the contribution of the combined mechanical stimulation to the engineered cartilaginous tissue matrix was not sufficient to impede biodegradation of the tissue with culture time.
文摘Polycaprolactone-carboxymethyl cellulose composites have been obtained and used to print porous structures by material extrusion.The materials used contained 0,2 and 5% w/w of the carboxymethyl cellulose additive.These structures have been analyzed in terms of their morphology (including the evaluation of their porosity),mechanical properties under compression load and cell affinity.Cell affinity has been evaluated by culturing sheep mesenchymal stem cells and analyzing their viability by the Alamar Blue(R)assay at days 1,3,6 and 8.The results show that composites samples have similar values of porosity and apparent density than pure polycaprolactone ones.However,samples containing 5%w/w of carboxymethyl cellulose have micropores on the filaments due to a hindered deposition process.This characteristic affects the mechanical properties of the structures,so these ones have a mean compression modulus significantly lower than pure polycaprolactone scaffolds.However, the samples containing 2%w/w of carboxymethyl cellulose show no significant difference with the pure polycaprolactone ones in terms of their mechanical properties.Moreover,the presence of 2%w/w of additive improves cell proliferation on the surface of the porous structures.As complementary information,the flow properties of the composite materials were studied and the power law equations at 210℃ obtained,as this temperature was the 3D printing temperature.These equations can be useful for simulation and designing purposes of other manufacturing processes.