Biomechanical and endplate effects on nutrient transport in the intervertebral disc.

Biomechanical and endplate effects on nutrient transport in the intervertebral disc.

World Neurosurg. 2016 Dec 21;:

Authors: Giers MB, Munter BT, Eyster KJ, Ide GD, Newcomb AG, Lehrman JN, Belykh E, Byvaltsev VA, Kelly BP, Preul MC, Theodore N

Abstract
BACKGROUND: Physical data are lacking on nutrient transport in human intervertebral discs (IVDs), which supports regeneration. Our objective was to study nutrient transport in porcine IVDs to determine the effects of biomechanical and physiological factors.
METHODS: In vitro testing of whole porcine IVDs was performed under different loading conditions. Fifty cervical, thoracic, and lumbar discs with attached end plates were removed from 4 Yorkshire pigs (90-150 pounds). Discs were placed in Safranin O or Fast Green FCF histological stains in diffusion or diurnal compression-tested groups. The end plate was studied by using polyurethane to block it. Traction was studied with a mechanical testing frame. Discs were cut transversely and photographed. Images were analyzed for depth of annulus fibrosus (AF) stained. The nucleus pulposus (NP) was assigned a staining score.
RESULTS: Results showed no difference in AF staining between the two stains (P=0.60). The depth of AF staining did not increase (P=0.60) due to convection or disc height change via diurnal loading. The NP in all open end plate samples was completely stained by day 3. NP staining was decreased in blocked end plate samples (P=0.07) and AF staining was significantly less in traction samples than in diffusion-only samples (P=0.04).
CONCLUSIONS: This method showed that most small molecule nutrient transport occurs via the end plate. Compressive load was a negligible benefit or hindrance to transport. Traction hindered transport in the short term. This method can be used to study strategies for increasing nutrient transport in IVDs.

PMID: 28012886 [PubMed - as supplied by publisher]

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