1.Autologous chondrocyte implantation for knee focal cartilage defects: 3 years' follow-up at the University Malaya Medical Centre.
Abbas Aa ; Mohamad Ja ; Lydia Al ; Selvaratnam L ; Razif A ; Ab-Rahim S ; kavitha G ; Shilpa Pn ; Kamarul T
Journal of University of Malaya Medical Centre 2014;17(1):8-13
Autologous chondrocyte implantation (ACI) is a widely accepted procedure for the treatment of large, fullthickness
chondral defects involving various joints, but its use in developing countries is limited because of high
cost and failure rates due to limited resources and support systems. Five patients (age <45 years) with focal
cartilage defects received ACI at University of Malaya from 2006 to 2007 and followed up for 36 months. The
average presubjective Knee Evaluation Forms (IKDC) improved from 38.44±6.29 to 25.6±8.04 postoperatively,
the Oxford Knee Score (OKS) went from 25.6±8.04 to 13.96±1.63 and the American Knee Society Score (AKSS)
improved from 80±14.33 to 92.96±5.82 post-operatively. Thus improvements were seen in the IKDC and
AKSS score but not in the OKS. Magnetic resonance images showed the presence of cartilage tissue filling in
the lateral and medial patellar facet and medial femoral condyle in three patients. Failures were seen in two
patients, both with patellar defects and over the age of 36 years. Treatment with autologous chondrocyte
implantation for focal cartilage defect in lateral and medial patellar facet and medial femoral condyle showed
early improvement which was maintained at 3 yrs follow-up. ACI provided satisfactory outcome in focal cartilage
defects involving the femoral condyle.
Chondrocytes
2.Proteomics of chondrogenesis: a review
Journal of University of Malaya Medical Centre 2015;18(1):1-8
Osteoarthritis (OA) affects millions of people worldwide with its irreversible destruction of articular cartilage.
Recently, the potential of using chondrogenic differentiated multipotent mesenchymal stromal cells (cMSCs)
for OA treatment is being assessed. Preliminary clinical studies have been encouraging. However current
studies have also demonstrated that cMSCs are not biochemically and biomechanically identical to native
articular chondrocytes (ACs). Thus, there is an urgent need for the implementation of proteomic applications
as proteomics involve protein identification, relative quantification of proteins and studies of post-translational
modification which reveal novel regulating processes of complex mechanisms such as in chondrogenesis. A
comprehensive understanding of chondrogenesis is essential for the establishment of an effective cMSC model
to regenerate cartilage. In this article, we will review current proteomic studies on chondrogenesis, focusing
on recent findings and the proteomic approaches utilised.
Chondrocytes
3.Effects of Alginate Culture on Viability, Proliferation, and Phenotype of Canine Articular Chondrocytes.
Hyeong Geun PARK ; Jeong Im WOO ; So Ra PARK ; Han Jo LIM ; Byoung Hyun MIN
Journal of Korean Orthopaedic Research Society 2001;4(1):24-31
No Abstract Available.
Chondrocytes*
;
Phenotype*
4.Histologic Change of the Septal Cartilage with the Respect to Trauma History and Age at the Trauma in Nasal Septal Deviation.
Jong Cheol CHOI ; Jong Yeup KIM ; Byung Kuhn PARK ; Seung Min IN ; Bum Kyeong KIM
Korean Journal of Otolaryngology - Head and Neck Surgery 2006;49(6):629-635
BACKGROUND AND OBJECTIVES: The histologic difference of the traumatic nasal septal cartilage from that of non-traumatic has not been extensively studied. The aim of this study was to identify histologic difference in the nasal septal cartilage between traumatic and non-traumatic nasal septal deviation and to find its implication for surgical intervention. SUBJECTS AND METHOD: Nasal septal cartilage was obtained from 23 patients who had undergone septoplasty or septorhinoplasty for the nasal septal deviation. The septal cartilage without trauma (7 patients, Group I) and with the history of the trauma at the age under 10-15 years old (8 patients, Group II), and over 25 years old (8 patients, Group III) between May 2003 to February 2005 were included in this study. An approximately 1 x 1 cm sized piece of the septal cartilage was harvested from the site deviated the most. The histologic difference of the septal cartilage by hematoxylineosin staining under a light microscope was performed. RESULTS: The chondrocyte densities were significantly higher in the convex side than in the concave side of the septal cartilage in Group I, II, III. Especially, the increased chondrocyte ratio (convex/concave) were more evident in the septal cartilage traumatized at the age of 10 to 15 years, and the cartilage plate was thicker than the other groups (p<0.001). Also, dystrophic changes of the chondrocytes as representing the chondrocyte differentiation and chondroblast ratio (convex/concave) were significantly higher in the group II than in the other groups (p<0.005). CONCLUSION: This study demonstrated that age dependent changes in septal cartilage with nasal trauma showed distinctive histologic characteristics. We suggest that these observations will help determine surgical treatment modality for cases of nasal septal deviations with and without trauma.
Adult
;
Cartilage*
;
Chondrocytes
;
Humans
5.Autologous Chondrocyte Implantation as a Secondary Procedure after Failed Microfracture for Osteochondral Lesion of Talus.
Journal of Korean Foot and Ankle Society 2015;19(1):7-10
Microfracture as a reparative strategy is the treatment of choice for an osteochondral lesion of talus. Although the results of microfracture are generally excellent, at least 30% of patients who received microfracture have acute or chronic ankle pain with several or unknown causes. The most important factor for unsatisfactory outcome after microfracture is the size of the lesion. For failed osteochondral lesion of talus, the second options are autologous osteochondral graft, autologous chondrocyte implantation, or re-microfracture. In this article, we present the autologous chondrocyte implantation as a second procedure for failed microfracture and compare its clinical outcome with other methods based on a literature review.
Ankle
;
Chondrocytes*
;
Humans
;
Talus*
;
Transplants
6.Culture of Chondrocytes on Scaffolds with Different Pore Network of PLGA and PLLA.
Jong Won RHIE ; Tae Joo AHN ; Jae Gu PARK ; Joo Young SOHN ; Hae Suk CHO ; Poong LIM
Journal of the Korean Society of Plastic and Reconstructive Surgeons 2003;30(2):237-244
This study was performed to investigate the in vitro proliferation and migration of rabbit auricular chondrocytes into the various sized pore of PLLA and PLGA scaffolds. The chondrocytes were harvested, expanded, and seeded onto PLGA(50 : 50, 75 : 25, 85 : 15) and PLLA scaffold having either small(50 - 100 micrometer) or large(300 - 350 micrometer) pores. On the 4th and 8th week after culture, histologic observation and quantitative DNA assay were done. We noted that the largest amount of DNA was found in the 85 : 15 PLGA sponges than others, and in the 4th and 8th week, some amount of DNA was detected in the lower portion of 85 : 15 PLGA sponge only, and DNA amounts were increased during the culture period in the 85 : 15 PLGA, significantly. We also found that the numbers of cells were low in middle portion of scaffolds, and in large pore-sized group of 85 : 15 PLGA, there were many cells in the lower portion of the scaffolds more than that of small pore group. In conclusion, the pore size of the scaffold for chondrocyte culture is important for cell migration and proliferation, and PLGA, especially 85 : 15 PLGA with 300- 350 micrometer sized pore is the more suitable biomatrix for proliferation and migration of the chondrocytes.
Cell Movement
;
Chondrocytes*
;
DNA
;
Porifera
7.Study on transport of small molecule rhodamine B within different layers of cartilage.
Zhou QUAN ; Yansong TAN ; Lilan GAO ; Yanping SHI ; Ruixin LI ; Chunqiu ZHANG
Journal of Biomedical Engineering 2022;39(6):1149-1157
The small molecule nutrients and cell growth factors required for the normal metabolism of chondrocyte mainly transport into the cartilage through free diffusion. However, the specific mass transfer law in the cartilage remains to be studied. In this study, using small molecule rhodamine B as tracer, the mass transfer models of cartilage were built under different pathways including surface pathway, lateral pathway and composite pathway. Sections of cartilage at different mass transfer times were observed by using laser confocal microscopy and the transport law of small molecules within different layers of cartilage was studied. The results showed that rhodamine B diffused into the whole cartilage layer through surface pathway within 2 h. The fluorescence intensity in the whole cartilage layer increased with the increase of mass transfer time. Compared to mass transfer of 2 h, the mean fluorescence intensity in the superficial, middle, and deep layers of cartilage increased by 1.83, 1.95, and 3.64 times, respectively, after 24 h of mass transfer. Under lateral path condition, rhodamine B was transported along the cartilage width, and the molecular transport distance increased with increasing mass transfer time. It is noted that rhodamine B could be transported to 2 mm away from cartilage side after 24 h of mass transfer. The effect of mass transfer under the composite path was better than those under the surface path and the lateral path, and especially the mass transfer in the deep layer of cartilage was improved. This study may provide a reference for the treatment and repair of cartilage injury.
Cartilage, Articular
;
Rhodamines/pharmacology*
;
Chondrocytes
8.Autologous Chondrocytes Transplantation.
The Journal of the Korean Rheumatism Association 2001;8(3):147-152
Autologous chondrocyte transplantation (ACT)has been introduced more than 10 years ago and has been applied for the management of full thickness chondral defects of the knee.ACT is ideally indicated for a symptomatic full-thick-ness chondral injury of the femoral articular surface in physiologically young patients.At this moment there are patients with 10-13 years of follow-up who had continued to benefit from ACT.Treatment of other surfaces such as the patella and tibia have also been successful.The excellent clinical outcomes and good durability of repaired articular tissue of ACT procedure have made it a cost-effective procedure comparable to other procedures.However,thorough knowledge of indications,meticulous surgical techniques,understanding of normal time course of healing,the appropriate postoperative rehabilitation,and the ability to manage the specific complications are essential to get good clinical results of ACT.
Chondrocytes*
;
Follow-Up Studies
;
Humans
;
Patella
;
Tibia
9.EFFECT OF VARIOUS GROWTH FACTORS IN CULTURE OF EAR CHONDROCYTES OF RABBIT.
Sang Hoon HAN ; Jeong Hoon KANG ; Chang Gi SUNG ; Jae Dam LEE
Journal of the Korean Society of Plastic and Reconstructive Surgeons 1997;24(5):884-892
No abstract available.
Chondrocytes*
;
Ear*
;
Intercellular Signaling Peptides and Proteins*
10.Repair of Cartilage Defect by Transplantation of Cultured Chondrocyte in the Rabbit: Difference related to Size of Defect.
Gun Il IM ; Do Young KIM ; Joo Ho SHIN ; Jong Hoon KIM ; Sun Ho KEE ; Kyung Chan CHOI ; Hwa Jae JUNG ; Won Ho CHO
Journal of Korean Orthopaedic Research Society 1998;1(1):32-39
Chondrocytes were harvested from knee joints of immature rabbits and cultured as monolayer until confluence, then split, and grown in collgen gel. The cells were transplanted into osteochondral defect of two different sizes (Group I : 16.1mm2, Group II : 7.1mm2) made on the patellar groove of distal femur in 21 mature rabbits. Left legs were used as experimental group and right leg as control. After 7 weeks, 1 out of 5 in experimental side and none out of 5 in the control side showed cartilaginous repair in Group I and 3 out of 8 in experimental side and 2 out of 8 in control side showed cartilaginous repair in Group II. After 14 weeks, 1 out of 4 in experimental side and none out of 4 in control side showed cartilaginous repair in Group I and 2 out of 4 in experimental side and 2 out of 4 in control side showed cartilaginous repair in Group II.
Cartilage*
;
Chondrocytes*
;
Femur
;
Knee Joint
;
Leg
;
Rabbits