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  Cornell University

MAE Publications and Papers

Sibley School of Mechanical and Aerospace Engineering

New article: Tissue-engineered Intervertebral Discs: MRI results and histology in the rodent spine presented at the 2013 Spine Section Meeting Laboratory Investigation

Article: Grunert P, Gebhard HH, Bowles RD, James AR, Potter HG, Macielak M, Hudson KD, Alimi M, Ballon DJ, Aronowitz E, Tsiouris AJ, Bonassar LJ, Hartl R; (2014) Tissue-engineered Intervertebral Discs:  MRI results and histology in the rodent spine presented at the 2013 Spine Section Meeting Laboratory Investigation.  Journal of Neurosurgery-Spine, 20(4):443-451

DOI

Abstract:  Object. Tissue-engineered intervertebral discs (TE-IVDs) represent a new experimental approach for the treatment of degenerative disc disease.

Compared with mechanical implants, TE-IVDs may better mimic the properties of native discs. The authors conducted a study to evaluate the outcome of TE-IVDs implanted into the rat-tail spine using radiological parameters and histology.

Methods. Tissue-engineered intervertebral discs consist of a distinct nucleus pulposus (NP) and anulus fibrosus (AF) that are engineered in vitro from sheep IVD chondrocytes. In 10 athymic rats a discectomy in the caudal spine was performed. The discs were replaced with TE-IVDs.

Animals were kept alive for 8 months and were killed for histological evaluation. At 1,5, and 8 months, MR images were obtained; T1-weighted sequences were used for disc height measurements, and T2-weighted sequences were used for morphological analysis. Quantitative T2 relaxation time analysis was used to assess the water content and Tip-relaxation time to assess the proteoglycan content of TE-IVDs.

Results. Disc height of the transplanted segments remained constant between 68% and 74% of healthy discs. Examination of TE-IVDs on MR images revealed morphology similar to that of native discs.

T2-relaxation time did not differ between implanted and healthy discs, indicating similar water content of the NP tissue. The size of the NP decreased in TE-IVDs. Proteoglycan content in the NP was lower than it was in control discs. Ossification of the implanted segment was not observed. Histological examination revealed an AF consisting of an organized parallel-aligned fiber structure. The NP matrix appeared amorphous and contained cells that resembled chondrocytes.

Conclusions. The TB-IVDs remained viable over 8 months in vivo and maintained a structure similar to that of native discs.

Tissue-engineered intervertebral discs should be explored further as an option for the potential treatment of degenerative disc disease.

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