Objectives

We sought to determine if a durable bilayer implant composed of trabecular metal with autologous periosteum on top would be suitable to reconstitute large osteochondral defects. This design would allow for secure implant fixation, subsequent integration and remodeling.

Introduction and Objective. Current cartilage repair strategies lack adequate tissue integration capacity and often present mechanical failure at the graft-to-host tissue junction. The design of multilayered osteochondral tissue engineering (TE) constructs is an attractive approach to overcome these problems. However, calcium ion-release from resorbable bone-replacement materials was suggested to compromise chondrogenic differentiation of adjacent cartilage tissue and it is unclear whether articular chondrocytes (AC) or mesenchymal stroma cells (MSC) are more sensitive to such conditions. Aim of the study was to compare how elevated calcium levels affect cartilage matrix production during re-differentiation of AC versus chondrogenic differentiation of MSC. The results of this study will help to identify the ideal cell source for growth of neocartilage adjacent to a calcified bone replacement material for design of multilayered osteochondral TE approaches. Materials and Methods. Expanded human AC and MSC (6–12 donors per group) were seeded in collagen type I/III scaffolds and cultured under standard chondrogenic conditions at control (1.8mM) or elevated (8.0mM) CaCl2 for 35 days. Proteoglycan and collagen production were assessed via radiolabel-incorporation, ELISA, qPCR and Western blotting. Differences between groups or cell types were calculated using the non-parametric Wilcoxon or Mann-Whitney U test, respectively, with p < 0.05 considered significant. Results. Elevated calcium significantly reduced GAG synthesis (63% of control, p=0.04) and chondrogenic marker expression of AC, lowering the GAG/DNA content (47% of control, p=0.004) and collagen type II deposition (24% of control, p=0.05) of neocartilage compared to control conditions. Opposite, at elevated calcium levels MSC-derived chondrocytes significantly increased GAG synthesis (130% of control, p=0.02) and collagen type II content (160% of control, p=0.03) of cartilage compared to control tissue. Chondrogenic and hypertrophic marker expression was insensitive to calcium levels in MSC-derived chondrocytes. As a result, maturation under elevated calcium allowed for a significantly higher GAG/DNA content in MSC-derived samples compared to AC constructs, although under control conditions both groups developed similarly. Conclusions. AC and MSC showed an opposite reaction to elevation of calcium levels regarding cartilage matrix production and we propose MSC as a preferred cell source to grow chondrocytes in vicinity to calcified bone replacement materials. Since MSC remained prone to hypertrophy under elevated calcium, trizonal cartilage TE constructs, where an AC-layer is separated from the bone replacement phase by an intermediate layer of MSC appear as an ideal design for multilayered osteochondral TE with respect to calcium sensitivity of cells and protection of the upper cartilage layer from hypertrophy

Lesions in the joint surface are commonly treated with osteoarticular autograft transfer system (OATS), autologous cell implantation (ACI/MACI), or microfracture. Tissue formed buy the latter commonly results in mechanically inferior fibrocartilage that fails to integrate with the surrounding native cartilage, rather than durable hyaline cartilage. Fractional laser treatment to make sub-millimeter (<500 µm) channels has been employed for tissue regeneration in the skin to facilitate rejuvenation without typical scarring. Additionally, we have pioneered a means to generate articular cartilage matrix from chondrocytes—dynamic Self-Regenerating Cartilage (dSRC). Combining these two approaches by performing fractional laser treatment of the joint cartilage and treating with dSRC is a new paradigm for joint surface restoration. This approach was refined in a series of in vitro experiments and tested in swine knee defects during a 6-month study in 12 swine. dSRC are generated by placing 10. 7. swine knee chondrocytes into sealed 15-mL polypropylene tubes and cultured on a rocker at 40 cycles per minute for 14 days at 37°C. The chondrocytes aggregate and generate new extracellular matrix to form a pellet of dSRC. Channels of approximately 300-500 µm diameter were created by infrared laser ablation in swine cartilage (in vitro) and swine knees (in vivo). The diameter and depth of the ablated channel in the cartilage was controlled by the light delivery parameters (power, spot size, pulse duration) from a fractional 2.94 µm Erbium laser. The specimens were evaluated with histology (H&E, safranin O, toluidine blue) and polarized-sensitive optical coherence tomography for collagen orientation. We can consistently create laser-ablated channels in the swine knee and successfully implant new cartilage from dSRC to generate typical hyaline cartilage in terms of morphology and biochemical properties. The neocartilage integrates with host cartilage in vivo. These findings demonstrate our novel combinatorial approach for articular cartilage rejuvenation

Aim of the study was to evaluate if abrasion-arthroplasty (AAP) and abrasion-chondroplasty (ACP) leads to a release of mesenchymal stem cell (MSC) like cells from the bone marrow to the joint cavity where they probably differentiate into a chondrogenic phenotype. Introduction. Cartilage demage is a sever problem in our aging society. About 5 million people only in Germany are affected. Osteoathritis is a degeneration of cartilage caused by aging or traumata 50 % of the people over 40 have signs of osteoarthritis. But the ability of self-regeneration of cartilage is strongly limited. There are different approaches to therapy osteoathritic lesions. Arthroscopic treatment of OA includes bone marrow stimulation technique such as abrasion arthroplasty (AAP) and microfracturing (MF). Beside the support of chondrocyte progenitor cells the environment is also important for the commitment to chondrocytes. Therefore insulin-like growth factor-1 (IGF-1) and transforming growth factor beta-1 (TGF-β1) are important factors during the regeneration process. In the present study we characterised the heamarthrosis and the released cells after AAP and its ability to differentiate into the chondrocyte lineage. Material and Methods. Postoperative haemarthrosis was taken 5, 22 or 44 hours after surgery. 7.5 mg Dexamethasone (Corticosteroid) was administered into the knee joint to prevent postoperative inflammation. Mononuclear cells were isolated from haemarthrosis from the drainage bottle by ficoll density gradient centrifugation. The isolated cells were characterised using fluorescence-activated cell-sorting (FACS) analysis for characteristic markers of MSC such as CD 44, 73, 90, 105. After expanding cells were cultured in a pellet culture. After 3 weeks, histochemistry and immunohistochemistry against Sox9, collagen II and proteoglycan were performed. The release of IGF1, BMP4 and BMP7 was analysed in haemarthrosis serum by ELISA and Luminex technology. Results. The isolated cells after AAP are positive for the mesenchymal stem cell marker CD105, CD90, CD73, CD 44 and negative for the marker of hematopoetic stem cells CD 34. Isolated cells after ACP couldn't be expanded for further characterizations. The staining of the 3D-culture revealed a positive signal for the chondrogen transcription factor Sox9 and the expression of extracellular markerproteins like collagen type II and proteoglycan. Both surgery techniques, AAP and ACP provides a chondrogenic environment. We were able to detect IGF-1, TGFß, BMP4 and BMP7 in the haemarthrosis. Discussion. The benefit of abrasion arthroplasty surgery and microfracturing is controversial discussed because they do not consistently result in hyaline cartilage. But the opening of the bone marrow allows the release of monocytic cells which have the potential to differentiate into a chondrogenic phenotype. In 3D-culture these cells express Sox9 and a collagen proteoglycan rich matrix. The haemarthrosis provides also a cartilage-stimulating environment. We could detect IGF1, TGFβ, BMP4 and 7 which could enhance the commitment concerning differentiation of MSCs to a chondrogenic lineage concerning the production of cartilage specific extracellular matrix. Taken together our study provides the evidence for a therapeutic benefit of opening bone marrow in order to generate neocartilage after AAP

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.