Mechanical overloading initiates intervertebral disc degeneration, presumably because cells break down the extracellular matrix (ECM). We used Fourier Transform Infrared Spectroscopy (FTIR) imaging to identify, visualize and quantify the ECM and aimed to identify spectroscopic markers for early disc degeneration. In seven goats, one disc was injected with chondroitinase ABC (mild degeneration) and after three months compared to control.
Purpose of study and background
Methods and Results
Biomechanical overloading initiates intervertebral disc degeneration. We hypothesized that this is due to mechanosensitivity of the cells, which break down the extracellular matrix. Previously, we found that overloading in a loaded disc culture system causes upregulation of remodeling- and inflammatory gene expressions. Fourier Transform Infrared Spectroscopy is a novel technique to identify, visualize and quantify ECM. In this research, we first identified novel spectroscopic markers for disc degeneration, and then applied these markers to investigate the first steps into disc degeneration by overloading. In dataset 1, 18 discs of 9 goats were injected with chondroitinase ABC (degenerated) or not (control), and obducted 3 months after injection. This was used to find new spectroscopic markers for degeneration. In dataset 2, 42 goat discs were loaded with a physiological loading regime (50–150N) or overloading (50–400N) in a loaded disc culture system. In 18 of these discs, the cell activity was diminished in advance by freeze-thaw cycles and culturing on saline alone (non-vital group)). 24 additional discs were cultured in culture medium immediately post-mortem (vital group). Thereby, we are able to control whether the effect of the overloading is due to cell activity. The discs were fixed in formaldehyde, and 4 μm mid-sagittal were mounted to steel reflectance slides. Infrared spectroscopic mosaic images (23 × 57 images) were collected in transflectance mode at a spectral region of 1025–1150 cm−1. Data was pre-processed by second derivative transformation and MCR-MALS with two factors. The two factors were transferable between datasets, confirming the reliability. The first factor represents proteoglycans, as confirmed by Saffrin-O staining. In dataset 1, the degenerated group had less proteoglycan factor overall, especially in the nucleus (p<0.05). The second factor was found to have a lower entropy (p<0.01), showing a disorganization in the matrix. In dataset 2, no significant reduction in proteoglycan was found due to overloading in any group. However, the entropy was lower in the overloaded vital group (p<0.05), but not in the overloaded non-vital group (p>0.5). Therefore, we conclude that infrared spectroscopy is a promising tool to investigate early disc degeneration. Overloading can cause changes in the extracellular matrix, but only due to cell activity. Entropy is an early marker for early disc degeneration, implying that cutting of the extracellular matrix by cell activity is the first step into intervertebral disc degeneration.
We have evaluated four different fixation techniques for the reconstruction of a standard Mason type-III fracture of the radial head in a sawbone model. The outcome measurements were the quality of the reduction, and stability. A total of 96 fractures was created. Six surgeons were involved in the study and each reconstructed 16 fractures with 1.6 mm fine-threaded wires (Fragment Fixation System (FFS)), T-miniplates, 2 mm miniscrews and 2 mm Kirschner (K-) wires; four fractures being allocated to each method using a standard reconstruction procedure. The quality of the reduction was measured after definitive fixation. Biomechanical testing was performed using a transverse plane shear load in two directions to the implants (parallel and perpendicular) with respect to ultimate failure load and displacement at 50 N. A significantly better quality of reduction was achieved using the FFS wires (Tukey’s The ultimate failure load was similar for the FFS wires (parallel, 196.8 N ( The fixation of a standard Mason type-III fracture in a sawbone model using the FFS system provides a better quality of reduction than that when using conventional techniques. There was a significantly better stability using FFS implants, miniscrews and K-wires than when using miniplates.
Our aim in this prospective study was to evaluate a minimally invasive technique for percutaneous arthrodesis of the small joints in the hand. Thirteen arthrodeses were undertaken in 11 patients, eight women and three men. After the percutaneous removal of articular cartilage, the bony surfaces were aligned in a predetermined position and stabilised using a percutaneous screw system. The mean follow-up was 38.6 months (36 to 56). Bony union was achieved in 12 cases (ten patients) between nine and 12 weeks after surgery. In one patient a second operation was required to obtain union and another developed a painless nonunion after premature removal of the implants.