An increasing number of patients are treated by autologous chondrocyte implantation (ACI). This study tests the hypothesis that culture within a defined chondrogenic medium containing TGF-β enhances the reexpression of a chondrocytic phenotype and the subsequent production of cartilaginous extracellular matrix by human chondrocytes used in ACI. Chondrocytes surplus to clinical requirements for ACI from 24 patients were pelleted and cultured in either DMEM (Dulbecco’s modified eagles medium)/ITS+Premix/TGF-β1 or DMEM/10%FCS (fetal calf serum) and were subsequently analysed biochemically and morphologically. Pellets cultured in DMEM/ITS+/TGF-β1 stained positively for type-II collagen, while those maintained in DMEM/10%FCS expressed type-I collagen. The pellets cultured in DMEM/ITS+/TGF-β1 were larger and contained significantly greater amounts of DNA and glycosaminoglycans. This study suggests that the use of a defined medium containing TGF-β is necessary to induce the re-expression of a differentiated chondrocytic phenotype and the subsequent stimulation of glycosaminoglycan and type-II collagen production by human monolayer expanded chondrocytes

We have performed a prospective, single-surgeon study analysing the histological results of autologous chondrocyte implantation. Fourteen patients underwent autologous chondrocyte implantation of the knee and were evaluated at one year by clinical assessment and arthroscopy. Standard staining was used to examine the sections. In addition, in situ hybridisation was used to establish type-IIa and type-IIb collagen mRNA expression and immunolocalisation techniques demonstrated the positions of type-II and type-X collagen. Eight patients regenerated hyaline cartilage and also contained type-X collagen in the deepest layers and type-II collagen in the deep layers. Three demonstrated fibrocartilage and had type-II collagen in the deep layers. In situ hybridisation revealed that all 14 samples had the potential to express both type-IIa and type-IIb collagen. We have shown that one year after the initial implantation chondrocytes are capable of producing type-II collagen and that they continue to proliferate and mature

In this study a combination of autologous chondrocyte implantation (ACI) and the osteochondral autograft transfer system (OATS) was used and evaluated as a treatment option for the repair of large areas of degenerative articular cartilage. We present the results at three years post-operatively. Osteochondral cores were used to restore the contour of articular cartilage in 13 patients with large lesions of the lateral femoral condyle (n = 5), medial femoral condyle (n = 7) and patella (n = 1). Autologous cultured chondrocytes were injected underneath a periosteal patch covering the cores. After one year, the patients had a significant improvement in their symptoms and after three years this level of improvement was maintained in ten of the 13 patients. Arthroscopic examination revealed that the osteochondral cores became well integrated with the surrounding cartilage. We conclude that the hybrid ACI/OATS technique provides a promising surgical approach for the treatment of patients with large degenerative osteochondral defects

We compared the quality of debridement of chondral lesions performed by four arthroscopic (SH, shaver; CU, curette; SHCU, shaver and curette; BP, bipolar electrodes) and one open technique (OPEN, scalpel and curette) which are used prior to autologous chondrocyte implantation (ACI). The ex vivo simulation of all five techniques was carried out on six juvenile equine stifle joints. The OPEN, SH and SHCU techniques were tested on knees harvested from six adult human cadavers. The most vertical walls with the least adjacent damage to cartilage were obtained with the OPEN technique. The CU and SHCU methods gave inferior, but still acceptable results whereas the SH technique alone resulted in a crater-like defect and the BP method undermined the cartilage wall. The subchondral bone was severely violated in all the equine samples which might have been peculiar to this model. The predominant depth of the debridement in the adult human samples was at the level of the calcified cartilage. Some minor penetrations of the subchondral end-plate were induced regardless of the instrumentation used. Our study suggests that not all routine arthroscopic instruments are suitable for the preparation of a defect for ACI. We have shown that the preferred debridement technique is either open or arthroscopically-assisted manual curettage. The use of juvenile equine stifles was not appropriate for the study of the cartilage-subchondral bone interface

In order to determine the usefulness of MRI in assessing autologous chondrocyte implantation (ACI) the first 57 patients (81 chondral lesions) with a 12-month review were evaluated clinically and with specialised MRI at three and 12 months. Improvement 12 months after operation was found subjectively (37.6 to 51.9) and in knee function levels (from 85% International Cartilage Repair Society (ICRS) III/IV to 61% I/II). The International Knee Documentation Committee (IKDC) scores showed an initial deterioration at three months (56% IKDC A/B) but marked improvement at 12 months (88% A/B). The MRI at three months showed 82% of patients with at least 50% defect fill, 59% with a normal or nearly normal signal at repair sites, 71% with a mild or no effusion and 80% with a mild or no underlying bone-marrow oedema. These improved at 12 months to 93%, 93%, 94% and 91%, respectively. The overall MR score at 12 months suggested production of normal or nearly normal cartilage in 82%, corresponding to a subjective improvement in 81% of patients and 88% IKDC A/B scores. Second-look surgery and biopsies in 15 patients (22 lesions) showed a moderate correlation of MRI with visual scoring; 70% of biopsies showed hyaline and hyaline-like cartilage. Thus, MRI at 12 months is a reasonable non-invasive means of assessment of ACI

Symptomatic articular cartilage defects are one of the most common knee injuries, arising from acute trauma, overuse, ligamentous instability, malalignment, meniscectomy, osteochondritis dissecans. Surgical treatment options include bone marrow–stimulating techniques such as abrasion arthroplasty and microfracture, osteochondral mosaicplasty, corrective osteotomy, cartilage resurfacing techniques and tissue engineering techniques using combinations of autologous cells (chondrocytes and mesenchymal stem cells), bioscaffolds, and growth factors. Matrix induced autologous chondrocyte implantation (MACI) is considered the most surgically simple form of autologous chondrocyte implantation. Our group has involved in the development of MACI since 2000 and has led to the FDA approval of MACI as the first tissue engineering product for cartilage repair in 2016. In this article, we have documented the characterisation of autologous chondrocytes, the surgical procedure of MACI and the long term clinical assessment (15 years) of patients with treatment of MACI. We have also reported the retrospective survey in patients with MACI in Australia. Our results suggest that MACI has gained good to excellent long term clinical outcome and probably can delay total knee replacement. However, restoration of hyaline-like cartilage by MACI may be interrupted by the osteoarthritic condition of the joint in patients with progressed osteoarthritis. In addition, because articular cartilage and subchondral bone are considered a single functional unit that is essential for joint function, many cartilage repair technologies including MACI and microfractures have failed short to address the functional barrier structure of osteochondral unit. Further studies are required to develop tissue engineering osteochondral construct that is able to fulfil the function of articular cartilage-subchondral bone units

The aim of this study was to determine whether the clinical outcome of autologous chondrocyte transplantation was dependent on the timing of a high tibial osteotomy in tibio-femoral mal-aligned knees. Between 2000 and 2005, forty-eight patients underwent autologous chondrocyte implantation with HTO performed at varying times relative to the second stage autologous chondrocyte implantation procedure. 24 patients had HTO performed simultaneously with their second stage cartilage transplantation, (the HTO Simultaneous Group). 5 patients had HTO prior to their cartilage procedure, (the HTO pre-ACI Group) and 19 had HTO performed between 1 to 4 years after their second stage cartilage implantation, (the HTO post-ACI Group). There were 29 men and 19 women with a mean age of 37 years (Range 28 to 50) at the time of their second stage procedure. With average follow-up of 72 months we have demonstrated a significant functional benefit in performing the HTO either prior to or simultaneously with the ACI procedure in the mal-aligned knee. The failure rate in the Post-ACI group was 45% compared to the Pre-ACI and Simultaneous group, with failure rates of 20% and 25%, respectively. An HTO performed prior to or simultaneously with an autologous chondrocyte implantation procedure in the mal-aligned knee, provides a significant protective effect by reducing the failure rate by approximately 50%

Abstract. Objective. Clinical treatments to repair articular cartilage (AC) defects such as autologous cartilage implantation (mosaicplasty) often suffer from poor integration with host tissue, limiting their long-term efficacy. Thus to ensure the longevity of AC repair, understanding natural repair mechanisms that allow for successful integration between cartilaginous surfaces, as has been reported in juvenile tissue, may be key. Here, we evaluated cartilage integration over time in a pig explant model of natural tissue repair by assessing expression and localisation of major ECM proteins, enzymatic cross-linkers including the five isoforms of lysyl oxidase (LOX), small leucine-rich repeat proteoglycans (SLRP's), and proteases (e.g. ADAMTS4). Methods. AC was retrieved from the femoral condyles of 8-week-old pigs. Full thickness 6mmØ AC discs were prepared, defects were induced, and explants cultured for up to 28 days. After fixation, sections were stained using Safranin-O and antibodies against Collagen types I & II, LOX, and ADAMTS4. Gene expression analyses were performed using qPCR. We also cultured devitalized samples, either with or without enzymatic treatment to deplete proteoglycans, for 28 days and similarly assessed repair. Results. Safranin-O staining demonstrated successful integration of cartilage defects over a 28-day period. No significant regulation in the expression of Col1a1, Col2a1, LOX or SLPR genes was observed at any time point. Immunofluorescence staining revealed that only ADAMTS4 localized at the injury surface in integrated samples. Interestingly, we also observed successful spontaneous integration of proteoglycan-depleted devitalized tissue. Conclusion. Cartilage integration in our pig cartilage explant model did not appear to be mediated by upregulation of major cartilage ECM components, enzymatic cross-linkers, or SLRPs. However, spontaneous integration of devitalized, proteoglycan-depleted AC, and localised upregulation of ADAMTS4 at the injured surface in successfully integrated samples, suggest that ADAMTS4 may enhances normal repair in injured AC through local aggrecan depletion, therefore enabling spontaneous cross-linking of collagen fibrils. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Osteoarthritis (OA) is a progressive and degenerative joint disease resulting in changes to articular cartilage. In focal early OA defects, autologous chondrocyte implantation (ACI) has a 2-fold failure rate due to poor graft integration and presence of inflammatory factors (e.g. Interleukin-1β). Bone marrow derived mesenchymal stem cells (MSCs) are an alternative cell source for cell-based treatments due to their chondrogenic capacity, though in vivo implantation leads to bone formation. In vivo, chondrocytes reside under an oxygen tension between 2–7% oxygen or physioxia. Physioxia enhances MSC chondrogenesis with reduced hypertrophic marker (collagen X and MMP13) expression compared to hyperoxic conditions (20% oxygen). This study sought to understand whether implantation of physioxic preconditioned MSCs improves cartilage regeneration in an early OA defect model compared to hyperoxic MSCs. Bone marrow extracted from New Zealand white rabbits (male: 5–6 months old; n = 6) was split equally for expansion under 2% (physioxia) or 20% (hyperoxia) oxygen. Chondrogenic pellets (2 × 105 cells/pellet) formed at passage 1 were cultured in the presence of TGF-β1 under their expansion conditions and measured for their wet weight and GAG content after 21 days. During bone marrow extraction, a dental drill (2.5mm diameter) was applied to medial femoral condyle on both the right and left knee and left untreated for 6 weeks. Following this period, physioxia and hyperoxia preconditioned MSCs were seeded into a hyaluronic acid (TETEC) hydrogel. Fibrous tissue was scraped and then MSC-hydrogel was injected into the right (hyperoxic MSCs) and left (physioxia MSCs) knee. Additional control rabbits with drilled defects had fibrous tissue scrapped and then left untreated without MSC-hydrogel treatment for the duration of the experiment. Rabbits were sacrificed at 6 (n = 3) and 12 (n = 3) weeks post-treatment, condyles harvested, decalcified in 10% EDTA and sectioned using a cryostat. Region of interest was identified; sections stained with Safranin-O/Fast green and evaluated for cartilage regeneration using the Sellers scoring system by three blinded observers. Physioxic culture of rabbit MSCs showed significantly shorter doubling time and greater cell numbers compared to hyperoxic culture (∗p < 0.05). Furthermore, physioxia enhanced MSC chondrogenesis via significant increases in pellet wet weight and GAG content (∗p < 0.05). Implantation of physioxic preconditioned MSCs showed significantly improved cartilage regeneration (Mean Sellers score = 7 ± 3; ∗p < 0.05) compared to hyperoxic MSCs (Sellers score = 12 ± 2) and empty defects (Sellers score = 17 ± 3). Physioxia enhances in vitro rabbit MSC chondrogenesis. Subsequent in vivo implantation of physioxia preconditioned MSCs improved cartilage regeneration in an early OA defect model compared to hyperoxic MSCs. Future studies will investigate the mechanisms for enhanced in vivo regeneration using physioxia preconditioned MSCs

Implantation of autologous chondrocytes and matrix autologous chondrocytes are techniques of cartilage repair used in the young adult knee which require harvesting of healthy cartilage and which may cause iatrogenic damage to the joint. This study explores alternative sources of autologous cells. Chondrocytes obtained from autologous bone-marrow-derived cells and those from the damaged cartilage within the lesion itself are shown to be viable alternatives to harvest-derived cells. A sufficient number and quality of cells were obtained by the new techniques and may be suitable for autologous chondrocyte and matrix autologous chondrocyte implantation

Introduction. Autologous chondrocyte implantation (ACI) is contra-indicated in a joint rendered unstable by a ruptured anterior cruciate ligament (ACL). We present our experience of ACI repair with ACL reconstruction. Methods. Patients underwent arthroscopic examination and cartilage harvesting of the knee. A second operation was undertaken approximately six weeks later to repair the ruptured ACL with hamstring graft or Bone patella-Bone (BPB) and to implant the chondrocytes via formal arthrotomy. Three groups were assessed: Group 1: Simultaneous ACL Reconstruction and ACI; Group 2: Previous ACL Reconstruction with subsequent ACI repair; Group 3: Previously proven partial or complete ACL rupture, deemed stable and not treated with reconstruction with ACI procedure subsequently. Patients then underwent a graduated rehabilitation program and were reviewed using three functional measurements: Bentley functional scale, the modified Cincinnati rating system, and pain measured on a visual analogue scale. All patients also underwent formal clinical examination at review. Results. Those who underwent simultaneous ACL Reconstruction and ACI had a 47% improvement in Bentley functional scale, 36% improvement in visual analogue score and 38% improvement in the modified Cincinnati rating system. This is in contrast to only a 15% improvement in the modified Cincinnati rating system, 30% improvement in Bentley functional scale, and 32% improvement in visual analogue score in patients who had ACI repair after previous ACL reconstruction. 68% of patients who had the procedures simultaneously rated their outcome as excellent/good and 27% felt it was a failure. In contrast 38% of patients rated their outcome as a failure if they had ACI repair without reconstruction of ACL rupture. Conclusion. Symptomatic cartilage defects and ACL deficiency may co-exist in many patients and represent a treatment challenge. Our results suggest that a combined ACL and ACI repair is a viable option in this group of patients and should reduce the anaesthetic and operative risks of a two-stage repair. Patients with complete rupture of ACL despite being deemed stable performed poorly at review and our study suggests all complete ruptures regardless of stability should be treated with a reconstruction when performing an autologous chondrocyte implantation

The main limitation of autologous chondrocyte implantation techniques is the necessity for in vitro cell expansion, which is associated with phenotypic drift and loss of extracellular matrix synthesis. Although media supplements (e.g. TGF-β) are extensively used to mitigate the tendency of de-differentiation, the lack of extracellular matrix is still one of the major obstacles to obtaining engineered cartilage substitutes with long-term clinical efficacy. Macromolecular crowding (MMC) is a biophysical phenomenon that increases tissue-specific extracellular matrix deposition. This study aimed to test whether MMC can be used to enhance hyaline-like ECM deposition in human chondrocyte culture: this hypothesis was tested in cells at P2 and at P7. Cells at P2 were cultured using a standard medium (DMEM/F12) in monolayer or alginate beads, whilst cells at P7 were cultured and re-differentiated using the system Clonetics™ of Lonza in the presence of 5 % HS or 5 % FBS, in monolayer and alginate beads. Macromolecular crowding medium was added 14 days after the start of re-differentiation. Collagen deposition was evaluated after 2, 5 and 10 days using SDS-PAGE and immunocytochemistry. MMC enhanced matrix deposition in all the conditions tested. However, although cells at P7 were cultured using a commercially available system, their deposited matrix was richer in collagen type I, whilst collagen type II was barely detectable. This was even more evident for cells in monolayer in HS and indicates that cells acquired a fibroblastic phenotype. To conclude, we showed that MMC increased matrix deposition in chondrocyte culture and that, unfortunately, commercially available systems are not always able to maintain chondrogenic phenotype. Since ECM produced is often undetectable and collagen expression and synthesis are not always correlated with its secretion, we propose to use MMC to assess chondrocyte phenotype maintenance and effectiveness of re-differentiation media

The aim of this study was to evaluate the cultivation potential of cartilage taken from the debrided edge of a chronic lesion of the articular surface. A total of 14 patients underwent arthroscopy of the knee for a chronic lesion on the femoral condyles or trochlea. In addition to the routine cartilage biopsy, a second biopsy of cartilage was taken from the edge of the lesion. The cells isolated from both sources underwent parallel cultivation as monolayer and three-dimensional (3D) alginate culture. The cell yield, viability, capacity for proliferation, morphology and the expressions of typical cartilage genes (collagen I, COL1; collagen II, COL2; aggrecan, AGR; and versican, VER) were assessed. The cartilage differentiation indices (COL2/COL1, AGR/VER) were calculated. The control biopsies revealed a higher mean cell yield (1346 cells/mg vs 341 cells/mg), but similar cell proliferation, viability and morphology compared with the cells from the edge of the lesion. The cartilage differentiation indices were superior in control cells: COL2/COL1 (threefold in biopsies (non-significant)); sixfold in monolayer cultures (p = 0.012), and 7.5-fold in hydrogels (non-significant), AGR/VER (sevenfold in biopsies (p = 0.04), threefold (p = 0.003) in primary cultures and 3.5-fold in hydrogels (non-significant)). Our results suggest that the cultivation of chondrocytes solely from the edges of the lesion cannot be recommended for use in autologous chondrocyte implantation

Background. Structural and functional outcome of bone graft with first or second generation autologous chondrocyte implantation (ACI) in osteochondral defects has not been reported. Methods. Seventeen patients (mean age of 27±7 years, range 17–40), twelve with osteochondritis dissecans (OD) (ICRS Grade 3 and 4) and five with isolated osteochondral defect (OCD) (ICRS Grade 4) were treated with a combined implantation of a unicortical autologous bone graft with ACI (the Osplug technique). Functional outcome was assessed with Lysholm scores. The repair site was evaluated with the Oswestry Arthroscopy Score (OAS), MOCART score and ICRS II histology score. Formation of subchondral lamina and lateral integration of the bone grafts were evaluated from MRI scans. Results. The mean defect size was 4.5±2.6SD cm. 2. (range 1–9) and depth was 11.3±5SD mm (range 5–18). The pre-operative Lysholm score improved from 45 (IQR 24, range 16–79) to 77 (IQR 28, range 41–100) at 1 year (p-value 0.001) and 70 (IQR 35, range 33–91) at 5 years (p-value 0.009). The mean OAS of the repair site was 6.2 (range 0–9) at a mean of 1.3 years. The mean MOCART score was 61 ± 22SD (range 20–85) at 2.6 ± 1.8SD years. Histology demonstrated generally good integration of the repair cartilage with the underlying bone. Poor lateral integration of the bone graft on the MRI scan and a low OAS were significantly associated with a poor Lysholm score and failure. Conclusion. Osplug technique shows significant improvement of functional outcome for up to 5 years in patients with a high grade OD or OCD. This is the first report describing association of bone graft integration with functional outcome after such a procedure. It also demonstrates histological evidence of integration of the repair cartilage with the underlying bone graft. Level of Evidence. III

Background. Treatment of cartilage defects requires in vitro expansion of human articular chondrocytes (HACs) for autologous chondrocyte implantation (ACI). During standard expansion culture (i.e. plasma osmolarity, 280 mOsm) chondrocytes inevitably lose their specific phenotype (i.e. collagen type II (COL2) expression). This de-differentiation makes them inappropriate for ACI. Physiological osmolarity (i.e. 380 mOsm) improves COL2 expression in vitro, but the underlying reason is unknown. However, an accepted key regulator of chondrocyte differentiation, transforming growth factor beta (TGFβ), is known to stimulate COL2 production. In this study we aimed to elucidate if TGFβ signaling could potentially be driving the COL2 expression under physiological culture conditions. Material and methods. After informed consent was obtained, HACs were isolated from five osteoarthritis (OA) patients and cultured in cytokine-free medium of 280 or 380 mOsm, respectively, under standard 2D in vitro conditions with or without lentiviral TGFβ2 knockdown (RNAi). Expression of TGFβ isoforms, superfamily receptors and chondrocyte marker genes was evaluated by qRT-PCR, TGFβ2 protein secretion by ELISA and TGFβ bioactivity using luciferase reporter assays. Statistical significance was assessed by a student's t-test. Results. TGFβ isoform expression was differentially altered by physiological osmolarity. Specifically, 380 mOsm increased TGFβ2 expression and protein secretion, as well as TGFβ activity. Upon TGFβ2 isoform-specific knockdown COL2 expression was induced. Physiological osmolarity and TGFβ2 RNAi also induced TGFβ1, TGFβ3 and their type I receptor ALK5. Conclusions. We showed that TGFβ2 knockdown increases COL2 expression in human osteoarthritic chondrocytes in vitro, possibly through a regulatory feedback loop involving TGFβ1, TGFβ3 induction and an increased ALK5/ALK1 ratio. This study indicates that TGFβ signalling is involved in osmolarity-induced chondrocyte marker gene expression. Pharmacological targeting of this pathway holds potential to further improve future osmolarity-mediated phenotypic stabilisation in advanced cell-based cartilage repair strategies. Level of Evidence. preclinical. Disclosure. We have nothing to disclose

As cartilage has poor intrinsic repair capacity, in vitroexpansion of human articular chondrocytes (HACs) is required for cell-based therapies to treat cartilage pathologies. During standard expansion culture (i.e. plasma osmolarity, 280 mOsm) chondrocytes inevitably lose their specific phenotype and de-differentiate, which makes them inappropriate for autologous chondrocyte implantation. It has been shown that physiological osmolarity (i.e. 380 mOsm) increases collagen type II (COL2) expression in vitro, but the underlying molecular mechanism is unknown. Transforming growth factor beta (TGFβ) super family members are accepted key regulators of chondrocyte differentiation and known to stimulate COL2 production. In this study we aimed to elucidate the role of TGFβ superfamily member signalling as a molecular mechanism potentially driving the COL2 expression under physiological (380 mOsm) culture conditions. HACs from OA patients (p1) were cultured in cytokine-free medium of 280 or 380 mOsm, under standard 2D in vitroconditions, with or without lentiviral TGFβ2 knockdown (RNAi). Expression of TGFβ isoforms, BMPs and chondrocyte marker genes was evaluated by QPCR. TGFβ2 protein secretion was evaluated using ELISA and bioactivity was determined using an established reporter cell line. Involvement of BMP signaling was investigated by culturing OA HACs (p1) in the presence or absence of dorsomorphin (10 µM). Physiological osmolarity increased TGFβ2 and TGFβ3 mRNA expression, TGFβ2 protein secretion as well as general TGFβ activity by 380 mOsm. Upon TGFβ2 isoform-specific knockdown COL2 mRNA expression was induced. TGFβ2 RNAi induced expression of several BMPs (e.g. BMP2,-4,-6) and this induction was enhanced in culture conditions with physiological osmolarity. Dorsomorphin inhibited physiological osmolarity induced COL2 mRNA expression. TGFβ2 knockdown under 380 mOsm increases COL2 expression in human osteoarthritic chondrocytes in vitromost likely through a regulatory feedback loop via BMP signaling, which is involved in osmolarity-induced COL2 expression. Future studies will further elucidate the BMP-mediated regulatory feedback loop after TGF β2 knockdown and its influence on COL2 expression

One reason why NICE (National Institute for Clinical Excellence) does not support operations by the NHS to heal hyaline cartilage lesions using a patients own cells is because there is no clear evidence to show that these operations are beneficial and cost-effective in the long term. Specifically, NICE identified a deficiency of high quality cartilage being produced in repaired joints. The presence of high quality cartilage is linked to long-lasting and functional repair of cartilage. The benchmark for quality, NICE stipulate, is repair cartilage that is stiff and strong and looks similar to the normal tissue surrounding it, i.e. mature hyaline articular cartilage. Biopsy material from autologous cartilage implantation surgical procedures has the appearance of immature articular cartilage and is frequently a mixture of hyaline and fibrocartilage. Osteoarthritic cartilage, in its early stages, also exhibits characteristics of immature articular cartilage in that it expresses proteins found in embryonic and foetal developmental stages, and is highly cellular as evidenced through the presence of chondrocyte clusters. Therefore, an ability to modulate the phenotype and the structure of the extracellular matrix of articular cartilage could positively affect the course of repair and regeneration of articular cartilage lesions. In order to do this, the biochemical stimuli that induce the transition of an essentially unstructured amorphous cartilage mass (immature articular cartilage) to one that is highly structured and ordered, and biomechanically adapted to its particular function (mature articular cartilage) has to be identified. We show for the first time, that fibroblast growth factor-2 and transforming growth factor beta-1 induce precocious maturation of immature articular cartilage. Our data demonstrates that it is possible to significantly enhance maturation of cartilage tissue using growth factor stimulation; consequently this may have applications in transplantation therapy, or through phenotypic modulation of osteoarthritic chondrocytes in diseased cartilage in order to stimulate growth and maturation of repair tissue

Tissue engineering is an increasingly popular method of addressing pathological disorders of cartilage. Recent studies have demonstrated its clinical efficacy, but there is little information on the structural organisation and biochemical composition of the repair tissue and its relation to the adjacent normal tissue. We therefore analysed by polarised light microscopy and immunohistochemistry biopsies of repair tissue which had been taken 12 months after implantation of autologous chondrocytes in two patients with defects of articular cartilage. Our findings showed zonal heterogeneity throughout the repair tissue. The deeper zone resembled hyaline-like articular cartilage whereas the upper zone was more fibrocartilaginous. The results indicate that within 12 months autologous chondrocyte implantation successfully produces replacement cartilage tissue, a major part of which resembles normal hyaline cartilage

Autologous chondrocyte implantation (ACI) has been used for many years for the treatment of symptomatic defects in articular joints, predominantly the knee. Traditionally, cells were implanted behind a periosteal membrane, but in more recent times Chondrogide, a membrane consisting of porcine collagens I and III, has been used. There have been trials comparing the clinical outcome of these two groups of patients; in this study we compare the histological outcome using the two different patch types. In a study of 100 patients having received ACI treatment of cartilage defects in the knee, 41 received Chondrogide (ACI-C) and 59 received periosteum (ACI-P). All of these patients had a post-operative biopsy taken at a mean of 16.9±9.2 months and 20.8±23.2 months for ACI-C and ACI-P respectively for histology using the ICRS II scoring system. Lysholm scores, a measure of knee function, were obtained pre- and post-operatively at the time of biopsy and statistical differences tested for via a Mann-Whitney U-test. The mean age of the two groups at treatment was 37±8 and 35±10 years, the size of defect treated was 6.1±5.4 and 4.4±2.7 cm2 and the biopsy follow-up time was 50.6±22.2 and 81.2±34.8 months for ACI-C and ACI-P patients respectively. Both groups exhibited a significant improvement in Lysholm score from pre-operative to the time of biopsy (14.3±25.7; n=100), although there was no significant difference in improvement in Lysholm score between the two patch types. There was no significant difference between the histology score of the two groups, nor was the score found to correlate with the Lysholm score at that time. The individual components of the ICRS II score did not differ significantly with patch type (even for the surface architecture) apart from cellular morphology which was 6.5±3 and 8.2±1.6 for ACI-C and ACI-P respectively. The histological quality of repair tissue formed with ACI-C differed little from that seen with ACI-P, despite the former group being biopsied ∼4 months sooner after treatment and being used to treat defects which were 39% larger. Hence Chondrogide appears just as suitable as periosteum for use as a patch in the procedure of ACI

Objectives

The aim of this study was to investigate the effect of granulocyte-colony stimulating factor (G-CSF) on mesenchymal stem cell (MSC) proliferation in vitro and to determine whether pre-microfracture systemic administration of G-CSF (a bone marrow stimulant) could improve the quality of repaired tissue of a full-thickness cartilage defect in a rabbit model.