1.Repair of the septal perforation by tragal cartilage autografting.
Cheol Min YANG ; Jun Yeong BYUN ; Na Kyung WON ; Dong Kyoon KIM ; Kang On LEE
Korean Journal of Otolaryngology - Head and Neck Surgery 1992;35(6):907-911
No abstract available.
Autografts*
;
Cartilage*
;
Transplantation, Autologous*
2.Clinical Experience of Sturdy Elevation of the Reconstructed Auricle.
Jeong Hwan CHOI ; Ju Chan KIM ; Min Su KIM ; Myung Hoon KIM ; Keun Cheol LEE ; Seok Kwun KIM
Archives of Craniofacial Surgery 2014;15(1):1-6
BACKGROUND: The ear is composed of elastic cartilage as its framework, and is covered with a thin layer of skin. Auricular reconstruction using autogenous cartilage in microtia patients requires delicacy. This paper reports clinical experiences related to elevation of reconstructed ear in the last 11 years. METHODS: This study was based on 68 congenital microtia patients who underwent auricular elevation in our hospital. Among these 68 patients, 47 patients were recruited. We compared the differences in the ear size, auriculocephalic angle, and conchal depth with those in the opposite ear, and the patients' satisfaction levels were investigated using a survey. RESULTS: The difference in the sizes of the two ears was less than or equal to 5 mm in 32 patients, 5 to 10 mm in 10 patients, and greater than or equal to 10 mm in 5 patients. The difference in the auriculocephalic angles of the two ears was less than or equal to 10 degrees in 14 patients, 10 to 20 degrees in 26 patients, and greater than or equal to 20 degrees in 7 patients. The difference in the conchal depths of the two ears was less than or equal to 5 mm in 24 patients, 5 to 10 mm in 19 patients, and greater than or equal to 10 mm in 4 patients. The average grade of 3.9 points out of 5 points was obtained by the patients with satisfactory surveys. CONCLUSION: We could make enough protrusion and maintain the three-dimensional shape for a long time to satisfy our patients.
Cartilage
;
Ear
;
Ear Auricle
;
Elastic Cartilage
;
Humans
;
Skin
;
Transplantation
3.Systematic evaluation of the incidence of the knee donor area after autobone cartilage mosaic xentoplasty.
Wen-Jie SONG ; Hao-Ran LIANG ; Wen-Jie NIU ; Yang LIU ; Zhi-Yuan REN ; Xue-Ding WANG ; Wang-Ping DUAN
China Journal of Orthopaedics and Traumatology 2023;36(6):579-585
OBJECTIVE:
To provide an overview of the incidence of knee donor -site morbidity after autologous osteochondral mosaicplasty.
METHODS:
A comprehensive search was conducted in PubMed, EMbase, Wanfang Medical Network, and CNKI databases from January 2010 to April 20, 2021. Relevant literature was selected based on predefined inclusion and exclusion criteria, and data were evaluated and extracted. The correlation between the number and size of transplanted osteochondral columns and donor-site morbidity was analyzed.
RESULTS:
A total of 13 literatures were included, comprising a total of 661 patients. Statistical analysis revealed an incidence of knee donor-site morbidity at 8.6% (57/661), with knee pain being the most common complaint, accounting for 4.2%(28/661). There was no significant correlation between the number of osteochondral columns and postoperative donor-site incidence (P=0.424, N=10), nor between the diameter size of osteochondral columns and postoperative donor-site incidence(P=0.699, N=7).
CONCLUSION
Autologous osteochondral mosaicplasty is associated with a considerable incidence of knee donor-site morbidity, with knee pain being the most frequent complaint. There is no apparent correlation between donor-site incidence and the number and size of transplanted osteochondral columns. Donors should be informed about the potential risks.
Humans
;
Incidence
;
Cartilage/transplantation*
;
Knee
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Knee Joint/surgery*
;
Pain
;
Cartilage, Articular
;
Transplantation, Autologous
;
Bone Transplantation
4.Management of Meniscal Injury: Repair, Meniscectomy, and Transplantation.
The Journal of the Korean Orthopaedic Association 2012;47(3):165-170
Although total meniscectomy had been performed as a treatment of meniscal tear, many published articles reported progression of the degeneration process and development of the osteoarthritis after meniscectomy. Meniscal repair has been performed increasingly, with the increased knowledge of the biomechanical properties of the meniscus. However, resection of the meniscus is still needed for irreparable tear and should be performed as minimally as possible to maintain the important functions of the meniscus. When substantial meniscal tissue is resected, meniscal allograft transplantation is considered to be a therapeutic option for young active patients to prevent the progress of degenerative change of the cartilage. In this review, indications and outcomes after meniscectomy, meniscal repair, and meniscal transplantation for the treatment of the meniscal injury are discussed.
Cartilage
;
Humans
;
Knee
;
Osteoarthritis
;
Transplantation, Homologous
;
Transplants
5.Repair of Osteochondral Defect Using Grafts of Cultured Chondrocytes in Rabbits.
Eun Woo LEE ; Soo Yong KANG ; Eui Chan JANG ; Ki Hwan KIM
The Journal of the Korean Orthopaedic Association 1997;32(2):464-471
Chondrocytes isolated from the articular cartilage of rabbit knee joint were cultured in vitro within fibrin glue carrier for 2 weeks. Histochemical and electromicroscopical approaches were used to study chondrocytes behavior and phenotypic expression. In vitro study, chondrocyte assumed a rounded morphology, accumulated metachromatic matrix and took on the cytological characteristics of in vivo cartilage cells. Allogenic cultured chondrocyte in fibrin glue was transplanted into osteochondral defect in rabbit joint. The contralateral knee joint served as a control in which the defect was left empty. This in vivo study was performed for the investigation of the chondrogenic potential of cultured chondrocytes embedded in fibrin glue. Grafted defects was filled with cartilage in gross finding, repaired tissue consisted of differentiated chondrocytes and matrix resumed that of hyaline cartilage. At sixteen week after transplantation, subchondral region was partially transformed into bone without loss of overlying articular cartilage, but in control group, defect did not heal successfully. Repaired articular cartilage was thicker than host cartilage and tide mark was not shown up to 24 weeks. Some of repaired tissue was degraded partially. These results suggest that fibrin glue provides suitable environment for differentiation of chondrocyte and allograft of cultured chondrocyte in fibrin glue transplanted into large osteochondral defect improves cartilage repair.
Allografts
;
Cartilage
;
Cartilage, Articular
;
Chondrocytes*
;
Fibrin Tissue Adhesive
;
Hyaline Cartilage
;
Joints
;
Knee Joint
;
Rabbits*
;
Transplantation
;
Transplants*
6.Research on repair strategies for articular cartilage defects.
Yu-Song PAN ; Guo-Xin DING ; Jing WANG
China Journal of Orthopaedics and Traumatology 2013;26(2):175-178
Articular cartilage damage is very common in clinical practices. Due to the low self-healing abilities of articular cartilage, the repair strategies for articular cartilage such as arthroscopic lavage and debridement,osteaochondral or chondrocytes transplantation, tissue engineering and hydrogel based artificial cartilage materials are the primary technologies of repairing articular cartilage defect. In this paper,the main repair strategies for the articular cartilage damage and the advantages or disadvantages of each repair technology are summarized. The arthroscopic lavage and debridement is successful in treating the early stage of osteoarthritis. Osteochondral and chondrocytes transplantation are beneficial to treat small full thickness defects. The technology of tissue engineering becomes a new method to heal articular cartilage damage, but the major problem is the absence of bonding strength between the implants and natural defect surfaces. Hydrogel based artificial cartilage possesses similar bio-mechanical and bio-tribological performances to that of natural articular cartilage. However, both bioactivity and interfacial bonding strength between the implant and natural cartilage could be further improved. How to simultaneously optimize the mechanical and bioactive as well as biotribological properties of hydrogel based materials is a focus problem concerned.
Arthroscopy
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Biomechanical Phenomena
;
Cartilage
;
transplantation
;
Cartilage, Articular
;
surgery
;
Chondrocytes
;
transplantation
;
Debridement
;
Humans
;
Tissue Engineering
7.Experimental study on fresh meniscal allografts combined with osteochondral allografts transplantation.
Yu ZHOU ; Yu-Jie LIU ; Shu-Xun HOU
China Journal of Orthopaedics and Traumatology 2012;25(10):852-855
OBJECTIVETo investigate the effect of fresh meniscal allografts combined with osteochondral allografts transplantation for treatment of osteoarthritis.
METHODSThirty-six rabbits were used in the experiment and were randomly divided into 3 groups: in group A, the fresh medial meniscal allografts combined with osteochondral allografts from medial tibial plateau were implanted into medial articular meniscal and medial tibial plateau osteochondral defects; in group B,the fresh medial meniscal allografts were implanted into medial meniscal allografts defects; in group C, the freezing medial meniscal allografts were implanted into medial meniscal allografts defects. General observation, histology examination and glycosaminoglycan (GAG) examination in cartilage of medial tibial plateau were performed at the 4th, 8th and 12th week after operation.
RESULTSThere were no significant differences in cellular counting and amount of GAG between group A and group B, but the cellular amount of group A was significantly more than that of group C at the 12th week.
CONCLUSIONFresh meniscal allografts combined with osteochondral allografts transplantation can repair meniscal and osteochondral defects.
Animals ; Cartilage ; transplantation ; Female ; Male ; Menisci, Tibial ; transplantation ; Rabbits ; Transplantation, Homologous
8.The Correction of Atypical Short Nose Due to Low Caudal Sellion Level: the Combination Method Using L-type Silastic Nasal Implant and Shield-shape Cartilage Graft.
Journal of the Korean Society of Plastic and Reconstructive Surgeons 2004;31(6):825-831
The short nose is characterized by decreased distance from the starting point of nose, sellion to tip defining point and increased nasolabial angle with excessively increased nostril show. In Orientals there are many people who have short nose due to low caudal level sellion and small nasofrontal angle with low dorsum of nose, reduced tip projection and acute nasolabial angle although it is not a typical short nose. In this study we defined this nose as atypical short nose. Lengthening short nose is arguably the most difficult operation in aesthetic rhinoplasty. We have described here a simple and easy technique that correct atypical short nose by using L-type silastic nasal implant and shield-shape cartilage graft. From January 2002 to March 2004, the author attempted to lengthen nasal root by cephalic upward repositioning of sellion with L-type silastic nasal implant with open rhinoplasty approach and improve tip projection and cephalic rotation by using columellar srtut formation with L-type silastic nasal implant, interdomal suture and shield-shape cartilage graft which is harvested from concha in 18 cases. We have got the satisfactory results on aesthetic aspects in all patients without any complications. The change of nasal length was from 44.8mm to 45.7mm and nasal tip projection and cephalic rotation were successfully improved. Especially the patients were very satisfied with one's lateral nasal profile because of smooth curvature of nasal root and natural nasofrontal angle due to cephalic nasal lengthening by upward repositioning of sellion. In conclusion I think this procedure is an effective and simple method in correcting atypical short nose which is characterized by low caudal level sellion, low dorsum of nose and reduced tip projection in Orientals.
Cartilage*
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Ear Cartilage
;
Humans
;
Nose Diseases
;
Nose*
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Rhinoplasty
;
Sutures
;
Transplantation
;
Transplants*
9.Stem Cell Therapy in Articular Cartilage Injury.
Hyung Moon YOON ; Seok Jung KIM ; Tae Gyun KIM
Journal of Rheumatic Diseases 2012;19(3):125-131
The natural history after articular cartilage injury is unclear. However, it is generally accepted that once articular cartilage is injured, its ability to regenerate is limited and that injury progresses to arthritis with time. Over the years various treatments have been developed and are used, such as arthroscopic debridement, microfracture, multiple drilling, osteochondral transfer, and Autologous Chondrocyte Implantation (ACI). These can be divided into treatment methods which apply cells and those which apply tissue. The former include abrasion chondroplasty, microfracture, multiple drilling, and ACI. The latter include osteochondral transfer and allograft. Combination treatments using both cells and tissues are new-generation ACI and microfracture with biomaterials. The clinical applications of stem cell therapy is still at an early stage, but shows much promise, particularly in the management of cartilage defects.
Arthritis
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Biocompatible Materials
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Cartilage
;
Cartilage, Articular
;
Chondrocytes
;
Debridement
;
Knee
;
Mandrillus
;
Natural History
;
Stem Cells
;
Transplantation, Homologous
10.Current therapy status and research progress of cartilage defects of knees.
Xiang-quan LI ; Ke-rong SONG ; Li-ming WANG ; Cheng-zhe JIN
China Journal of Orthopaedics and Traumatology 2015;28(5):482-486
To demonstrate the current strategies for treating cartilage defects of knees and the related research. Published papers about cartilage defects were searched and reviewed. The current strategies for the treatment were summarized. Based on the research of our study and others, the conclusion how to treat cartilage defects was made. The current ways for treating cartilage defects include micro-fractures, chondrocytes transplantation, mosaicplasty and tissue engineering; Research on functional magnetic resonance imaging in the early diagnosis of cartilage defects, cartilage degeneration is gradually increasing. There is still no effective treatment of cartilage defects and tissue engineering has brought new hopes for the treatment of cartilage defects , functional magnetic resonance imaging has some significance in early diagnosis of cartilage defects, cartilage degeneration.
Animals
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Cartilage Diseases
;
surgery
;
therapy
;
Cartilage, Articular
;
surgery
;
Humans
;
Knee
;
surgery
;
Tissue Engineering
;
Transplantation, Autologous