Tensile behaviour of individual fibre bundles in the human lumbar anulus fibrosus.

Disc degeneration is a common medical affliction whose origins are not fully understood. An improved understanding of its underlying mechanisms could lead to the development of more effective treatments. The aim of this paper was to investigate the effect of (1) degeneration, (2) circumferential region and (3) strain rate on the microscale mechanical properties (toe region modulus, linear modulus, extensibility, phase angle) of individual fibre bundles in the anulus fibrosus lamellae of the human intervertebral disc. Healthy and degenerate fibre bundles excised from different circumferential regions in the outer anulus (posterolateral, lateral, anterolateral, anterior) were tensile tested at slow (0.1%/s), medium (1%/s) and fast (10%/s) strain rates using a micromechanical testing system. Our preliminary results showed that neither degeneration nor circumferential region significantly affected the fibre bundles' mechanical behaviour. However, when the fibre bundles were tested at higher strain rates, this resulted in significantly higher linear moduli and lower phase angles. These findings, compared with data from other studies investigating single and multiple lamellae sections, suggest that degeneration has minimal effect on outer anulus mechanics irrespective of structural level, and the inter- and intra-lamellar arrangement and continuity of the fibre bundles may influence the lamellae's regional behaviour and viscoelasticity.

The Biomechanics of eyelid tarsus tissue.

Reconstruction of the eyelid remains challenging due to the unique properties of the tarsal plate, which is a fibrocartilagenous structure within the eyelid providing structural support and physical form. There are no previous studies investigating the biomechanical properties of tarsus tissue, which is vital to the success of bioengineered tarsal substitutes. We therefore aimed to determine the biomechanical properties of human tarsus tissue, and used a CellScale BioTester 5000 (CellScale, Waterloo, Canada) to perform uniaxial tensile tests on ten samples of healthy eyelid tarsus. All samples were tested 'fresh' within two hours of harvest. A tensile preload of 50 mN was applied for 10 min before the sample was subjected to uniaxial tension under linear ramp displacement control. Maximum strain was 30% of the original tissue length and thirty dynamic cycles were performed at a strain rate of 1%/s using a triangular waveform. Of the samples tested, the mean (SD) width was 5.51 mm (1.45 mm) whilst mean thickness was 1.6mm (0.51 mm). The mean toe modulus was 0.14 (0.10) MPa, elastic modulus was 1.73 (0.61) MPa, with an extensibility of 15.8 (2.1)%, and phase angle of 6.4° (2.4)°. After adjusting for the initial tissue slack, the maximum strain ranged from 23.8% to 30.0%. At maximum strain, it was observed that the linear region of the stress-strain curve was reached without the sample slipping out of the clamps. Our results establish a benchmark for native tarsus tissue, which can be used when evaluating tissue engineered tarsal substitutes in the future.