An ultra scale-down methodology to characterize aspects of the response of human cells to processing by membrane separation operations.

Tools that allow cost-effective screening of the susceptibility of cell lines to operating conditions which may apply during full scale processing are central to the rapid development of robust processes for cell-based therapies. In this paper, an ultra scale-down (USD) device has been developed for the characterization of the response of a human cell line to membrane-based processing, using just a small quantity of cells that is often all that is available at the early discovery stage. The cell line used to develop the measurements was a clinically relevant human fibroblast cell line. The impact was evaluated by cell damage on completion of membrane processing as assessed by trypan blue exclusion and release of intracellular lactate dehydrogenase (LDH). Similar insight was gained from both methods and this allowed the extension of the use of the LDH measurements to examine cell damage as it occurs during processing by a combination of LDH appearance in the permeate and mass balancing of the overall operation. Transmission of LDH was investigated with time of operation and for the two disc speeds investigated (6,000 and 10,000 rpm or ϵmax ≈ 1.9 and 13.5 W mL-1 , respectively). As expected, increased energy dissipation rate led to increased transmission as well as significant increases in rate and extent of cell damage. The method developed can be used to test the impact of varying operating conditions and cell lines on cell damage and morphological changes. Biotechnol. Bioeng. 2017;114: 1241-1251. © 2017 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.

Follow-up of a new arthroscopic technique for implantation of matrix-encapsulated autologous chondrocytes in the knee.

PURPOSE: The purpose of this study was to evaluate the clinical and sequential imaging follow-up results at a mean of 36 months after an arthroscopic technique for implantation of matrix-encapsulated autologous chondrocytes for the treatment of articular cartilage lesions on the femoral condyles. METHODS: Ten patients underwent arthroscopic implantation of autologous chondrocytes seeded onto a bioabsorbable scaffold. The patients were evaluated clinically using a visual analog scale (VAS) for pain and International Knee Documentation Committee (IKDC), Lysholm, and Tegner scores. Magnetic resonance imaging (MRI) T2-mapping and magnetic resonance observation of cartilage repair tissue (MOCART) evaluations were also performed. Second-look arthroscopic evaluation using the International Cartilage Repair Society (ICRS) grading classification was performed at 12 months. RESULTS: Compared with their preoperative values, at 36 months mean values ± standard deviation for the VAS scale for pain were 6.0 ± 1.5 to 0.3 ± 0.4. Improvement in clinical scores between preoperative values and 36-month follow-up values in subjective IKDC scores was 46.9 ± 18.5 to 77.2 ± 12.8; in Lysholm scores, it was 51.8 ± 25.1 to 87.9 ± 6.5, and in the Tegner activity scale it was 2.9 ± 1.7 to 5.9 ± 1.9. Mean T2 mapping and MOCART scores improved over time to 38.1 ± 4.4 ms and 72.5 ± 10, respectively. Mean ICRS score by second-look arthroscopy at 1 year was 10.4 ± 0.1. CONCLUSIONS: All clinical scores improved over time compared with the preoperative values. Clinical results are comparable with MRI T2 mapping and ICRS evaluations, suggesting that this arthroscopic technique for cell-based cartilage repair is efficacious and reproducible at a mean of 36 months of follow-up. LEVEL OF EVIDENCE: Level IV, therapeutic case series.

[Cartilage repair: cell-based techniques]. / Reparación del cartílago articular: técnicas basadas en cultivos celulares.

INTRODUCTION: The field of cartilage repair continues to advance after cell based and single-stage chondrocyte transplantation technologies. These strategies have been widely used in developed countries, and clinical, histologic and functional outcomes are of special interest. OBJECTIVE: To describe evidence of cartilage repair techniques by means of a literature review. RESULTS AND DISCUSSION: Cartilage restoration through osteochondral allografting or autologous chondrocyte implantation (ACI) had proven efficacy, but technical and biologic limitations to these procedures exist. However, newer second-generation and third-generation cell-based technologies are being developed and tested clinically with purposes of decreasing operative morbidity, the ability to use a single-stage approach, and improve the viability and durability of cartilage repair tissue. These techniques can be used for treatment of important chondral defects in young patients and elite athletes, but well-designed randomized clinical trials should be done to confirm the value of these procedures.

Matrix-encapsulation cell-seeding technique to prevent cell detachment during arthroscopic implantation of matrix-induced autologous chondrocytes.

PURPOSE: The goal of this study is to evaluate the efficiency of obtaining a large number of viable cells within a construct that will not be detached by high fluid flow during arthroscopic implantation. METHODS: Arthroscopic osteochondral biopsy specimens were obtained from the medial femoral trochlea of 8 horses. Chondrocytes were isolated by collagenase digestion and expanded in M199 media until confluency. After 10 to 12 days, cultures were trypsinized and cells resuspended in culture media. Then, 5 x 10(6) cells x mL(-1) were seeded on a culture dish and the same amount in a flask. Once extracellular matrix was formed, a polyglycolic/polylactic acid disk was placed in the culture dish. Cells obtained from the culture flasks (2 x 10(7) cells) were seeded onto the polymer and encapsulated by lifting the monolayer of cells and matrix from the bottom of the dish with surgical forceps. On days 1, 3, 5, 7, and 9, viability was evaluated by calcein fluorescence. Fiber cell attachment was evaluated before implantation by environmental scanning electron microscopy. Six horses were implanted with naive cell-polymer constructs, and two horses were implanted with adenoviral vector with green fluorescent protein (AdGFP)-transduced cells. Biopsy specimens of repair tissue were evaluated at 8 weeks in 6 horses and at 4 weeks in the 2 horses implanted with AdGFP-transduced cells by second-look arthroscopy and biopsy, histochemistry, and confocal laser scanning microscopy via MitoTracker Red 580 (Invitrogen [Molecular Probes], Gibco, Carlsbad, CA) to assess cell viability. RESULTS: Viability and attachment of cells to polymer were confirmed by calcein fluorescence microscopy and environmental scanning electron microscopy. Consistency of the construct was ideal for implantation between 7 and 9 days. Repair tissue with AdGFP chondrocytes after 4 weeks showed fluorescent cells also positive to MitoTracker probe by confocal laser scanning microscopy. Repair tissue after 8 weeks showed very cellular new tissue formation with good attachment to subchondral bone and adjacent cartilage. CONCLUSIONS: The matrix-encapsulation cell-seeding technique allowed us to maintain a sufficient number of viable cells within the polymer construct despite the high-pressure fluid flow that occurred during arthroscopic implantation when we used a pump for direct visualization. CLINICAL RELEVANCE: Arthroscopic implantation of cell-polymer constructs via a fluid pump can be performed without the risk of cell loss with the use of a simple cell-seeding technique.