Divisions of Orthopaedic Surgery and Surgical Research, Department of Surgery, University of Alberta , Edmonton, Alberta, Canada .
Tissue Eng Part A. 2018 May;24(9-10):761-774. doi: 10.1089/ten.TEA.2017.0235. Epub 2017 Nov 30.
Bone marrow-derived mesenchymal stromal stem cells (BMSCs) are a promising cell source for treating articular cartilage defects. The objective of this study was to assess a protocol that involved autologous transplantation of BMSCs into full-thickness cartilage defects in sheep following isolation, expansion, and a short period (4 days) of chondrogenic priming. The impact of oxygen tension during preimplantation culture was investigated. It was hypothesized that chondrogenically primed BMSCs would produce superior cartilaginous repair tissue relative to control defects, and that culture under hypoxia would yield improved repair tissue in comparison to normoxia. Ovine BMSCs were isolated, expanded to passage 2, seeded within a hyaluronic acid (HYAFF) scaffold, and primed ex vivo in chondrogenic medium for 4 days under normoxia (21% oxygen) or hypoxia (3% oxygen). Full-thickness, 7-mm-diameter articular cartilage defects were created in the femoral condyles of five sheep. Twenty defects were treated with normoxia-cultured, autologous BMSC-seeded scaffolds (eight); hypoxia-cultured, autologous BMSC-seeded scaffolds (eight); cell-free scaffolds (two); or no implants (two). Preimplantation priming was evaluated through gene expression analysis using reverse transcription quantitative polymerase chain reaction. After 6 months, histological assessment was performed on repair tissues with a modified O'Driscoll scoring system and tissue dimension analysis. Priming of preimplantation BMSC-seeded scaffolds in chondrogenic medium for 4 days resulted in significantly increased gene expression of hyaline cartilage-related collagen II and aggrecan relative to unprimed BMSCs (p < 0.05). Defects implanted with chondrogenically primed BMSC-seeded scaffolds developed cartilaginous repair tissues that contained safranin O-positive proteoglycans, and had significantly larger repair tissue areas, higher percentages of defect fill, and improved histological scores than cell-free controls (p < 0.05). Although hypoxic culture improved the preimplantation gene expression profile, a consistent difference in histological scores was not found between normoxia- and hypoxia-seeded BMSC-seeded scaffolds after 6 months (p = 0.90). This study demonstrates in a sheep model that (1) chondrogenic priming ex vivo improves the gene expression profile of BMSCs; (2) chondrogenically primed BMSCs are associated with the development of superior cartilaginous tissue to cell-free controls within cartilage defects; and (3) oxygen tension during preimplantation ex vivo culture does not consistently modulate cartilaginous repair tissue formation following BMSC transplantation into cartilage defects.
骨髓间充质基质干细胞(BMSCs)是治疗关节软骨缺损的有前途的细胞来源。本研究的目的是评估一种方案,即在绵羊全层软骨缺损中进行自体 BMSC 移植,在分离、扩增和短期(4 天)软骨形成诱导后进行。研究了植入前培养过程中氧张力的影响。假设经过软骨形成诱导的 BMSCs 将产生优于对照缺损的软骨修复组织,并且与常氧相比,缺氧培养将产生改善的修复组织。分离绵羊 BMSCs,扩增至第 2 代,接种于透明质酸(HYAFF)支架内,并在常氧(21%氧气)或缺氧(3%氧气)下在体外软骨形成培养基中预培养 4 天。在五只绵羊的股骨髁中创建了 7mm 直径的全层关节软骨缺损。20 个缺损用常氧培养的、自体 BMSC 接种的支架(8 个);缺氧培养的、自体 BMSC 接种的支架(8 个);无细胞支架(2 个);或无植入物(2 个)进行治疗。通过逆转录定量聚合酶链反应的基因表达分析评估植入前的预培养。6 个月后,使用改良的 O'Driscoll 评分系统和组织尺寸分析对修复组织进行组织学评估。与未经诱导的 BMSCs 相比,植入前预培养的 BMSC 接种的支架在软骨形成培养基中培养 4 天,导致透明软骨相关胶原 II 和聚集蛋白聚糖的基因表达显著增加(p<0.05)。用软骨形成诱导的 BMSC 接种的支架植入的缺损形成了含有硫酸软骨素 O 阳性蛋白聚糖的软骨修复组织,并且与无细胞对照相比,修复组织面积显著增大,缺损填充百分比更高,组织学评分改善(p<0.05)。尽管缺氧培养改善了植入前的基因表达谱,但在 6 个月后,常氧和缺氧接种的 BMSC 接种的支架之间并未发现组织学评分的一致差异(p=0.90)。本研究在绵羊模型中证明:(1)体外软骨形成诱导可改善 BMSC 的基因表达谱;(2)与无细胞对照相比,软骨形成诱导的 BMSC 与软骨缺损内更优的软骨组织的形成有关;(3)植入前体外培养过程中的氧张力不会一致调节 BMSC 移植到软骨缺损后软骨修复组织的形成。
