Download PDF
Evid Based Spine Care J 2010; 1(2): 62-66
DOI: 10.1055/s-0028-1100918
Selected abstracts
© Georg Thieme Verlag KG Stuttgart · New York

Total disc replacement using a tissue-engineered intervertebral disc in vivo: new animal model and initial results

Harry Gebhard1 , Robby Bowles2 , Jonathan Dyke3 , Tatianna Saleh1 , Stephen Doty4 , Lawrence Bonassar2 , Roger Härtl1
  • 1 New York-Presbyterian Hospital/Weill Cornell Medical College, New York, NY, USA
  • 2 Department of Biomedical Engineering/Sibley School of Mechanical and Aerospace Engineering, Cornell University, Ithaca, NY, USA
  • 3 Citigroup Biomedical Imaging Center/Weill Medical College of Cornell University, New York, NY, USA
  • 4 Hospital for Special Surgery, New York, NY, USA
Further Information

Publication History

Publication Date:
23 November 2010 (online)

Also available at
   Permissions and Reprints

ABSTRACT

Study type: Basic science

Introduction: Chronic back pain due to degenerative disc disease (DDD) is among the most important medical conditions causing morbidity and significant health care costs. Surgical treatment options include disc replacement or fusion surgery, but are associated with significant short- and long-term risks [1]. Biological tissue-engineering of human intervertebral discs (IVD) could offer an important alternative [2]. Recent in vitro data from our group have shown successful engineering and growth of ovine intervertebral disc composites with circumferentially aligned collagen fibrils in the annulus fibrosus (AF) (Figure [1]) [3].

Objective: The next step is to investigate if biological disc implants survive, integrate, and restore function to the spine in vivo. A model will be developed that allows efficient in vivo testing of tissue-engineered discs of various compositions and characteristics.

Methods: Athymic rats were anesthetized and a dorsal approach was chosen to perform a microsurgical discectomy in the rat caudal spine (Figures [2] and [3]). Control group I (n = 6) underwent discectomy only, Control group II (n = 6) underwent discectomy, followed by reimplantation of the autologous disc. Two treatment groups (group III, n = 6, 1 month survival; group IV, n = 6, 6 months survival) received a tissue-engineered composite disc implant. The rodents were followed clinically for signs of infection, pain level and wound healing. X-rays and magnetic resonance imaging (MRI) were assessed postoperatively and up to 6 months after surgery (Figures [6] and [7]). A 7 Tesla MRI (Bruker) was implemented for assessment of the operated level as well as the adjacent disc (hydration). T2-weighted sequences were interpreted by a semiquantitative score (0 = no signal, 1 = weak signal, 2 = strong signal and anatomical features of a normal disc). Histology was performed with staining for proteoglycans (Alcian blue) and collagen (Picrosirius red) (Figures [4] and [5]).

Results: The model allowed reproducible and complete discectomies as well as disc implantation in the rat tail spine without any surgical or postoperative complications. Discectomy resulted in immediate collapse of the disc space. Preliminary results indicate that disc space height was maintained after disc implantation in groups II, III and IV over time. MRI revealed high resolution images of normal intervertebral discs in vivo. Eight out of twelve animals (groups III and IV) showed a positive signal in T2-weighted images after 1 month (grade 0 = 4, grade 1 = 4, grade 2 = 4). Positive staining was seen for collagen as well as proteoglycans at the site of disc implantation after 1 month in each of the six animals with engineered implants (group III). Analysis of group IV showed positive T2 signal in five out of six animals and disc-height preservation in all animals after 6 months.

Conclusions: This study demonstrates for the first time that tissue-engineered composite IVDs with circumferentially aligned collagen fibrils survive and integrate with surrounding vertebral bodies when placed in the rat spine for up to 6 months. Tissue-engineered composite IVDs restored function to the rat spine as indicated by maintenance of disc height and vertebral alignment. A significant finding was that maintenance of the composite structure in group III was observed, with increased proteoglycan staining in the nucleus pulposus region (Fig. [4]d–f). Proteoglycan and collagen matrix as well as disc height preservation and positive T2 signals in MRI are promising parameters and indicate functionality of the implants.

REFERENCES

  • 1 Resnick D K, Watters W C. Lumbar disc arthroplasty: a critical review.  Clin Neurosurg. 2007;  54 83-87. Review
    PubMedGoogle Scholar
  • 2 Mizuno H, Roy A, Zaporojan V. et al . Biomechanical and biochemical characterization of composite tissue-engineered intervertebral discs.  Biomaterials. 2006;  27(3) 362-370
    CrossrefPubMedGoogle Scholar
  • 3 Bowles R D, Williams R M, Zipfel W R. et al . Self-Assembly of Aligned Tissue-Engineered Annulus Fibrosus and Intervertebral Disc Composite Via Collagen Gel Contraction.  Tissue Eng Part A. 2010;  16(4) 1339-1348
    CrossrefPubMedGoogle Scholar