Trevor J. Sims

Mechanical properties of adult vertebral cancellous bone: correlation with collagen intermolecular cross-links.

Although the mechanical strength of cancellous bone is well known to depend on its apparent density, little is known about the influence of other structural or biochemical parameters. This study specifically investigates the cross‐linking of the collagen in human vertebral bone samples and its potential influence on their mechanical behavior. Multiple cylindrical samples were cored vertically in the vertebral bodies of nine subjects (aged 44–88 years). Three spinal levels (T9, T12 or L1, and L4) and three sample sites within a vertebral body (anterior, posterior, and lateral) were used, for a total of 68 samples. The density was measured with peripheral quantitative computed tomography (pQCT) and all cylinders were mechanically tested in compression. After mechanical testing, they were unmounted and used for biochemical analysis. The amount of collagen (wt/wt of bone) and its content in reduced immature cross‐links, that is, hydroxylysinonorleucine (HLNL, mol/mol of collagen) and dihydroxylysinornorleucine (DHLNL), as well as stable mature cross‐links, that is, hydroxylysyl‐pyridinoline (HP), lysyl‐pyridinoline (LP), and pyrrole cross‐link were determined for each cylinder. None of the biochemical parameters correlated to the density. On multiple linear regression, the prediction of the mechanical properties was improved by combining density data with direct collagen cross‐link assessment. The HP/LP ratio appeared as a significant predictor to the strength (r = 0.40; p = 0.001) and stiffness (r = 0.47; p < 0.001) samples with a high HP/LP ratio being stronger and stiffer. Additionally, the ultimate strain correlated to the HP or LP concentration (r = 0.38 or 0.49; p < 0.01). Different subjects had different HP/LP ratios and different HP or LP concentrations in their vertebral bone samples, and the location of origin within a subject had no influence on the concentration. These observations suggest that the nature of the organic matrix in adult vertebral bone is variable and that these variations influence its mechanical competence.

Changes in collagen cross-linking in degenerative disc disease and scoliosis

Study Design. Biochemical study of the changes in the collagen cross‐link profile of human intervertebral discs collected at surgery from patients with either low back pain associated with disc degeneration or scoliosis. Objective. To determine whether changes occur in the collagen cross‐link profile in the disc of patients with either low back pain associated with disc degeneration or scoliosis, which may well influence matrix integrity. Such changes in the cross‐link profile of a tissue indicates increased matrix turnover and tissue remodeling and may have implications for the progression of these disorders. Summary of Background Data. The diseases of the intervertebral disc, degenerative disc disease and scoliosis, are both characterized by changes in the extracellular matrix components that will affect the mechanical function of the tissue. The stability of the collagenous components and hence the mechanical integrity of connective tissues such as the disc is dependent on the degree and type of cross‐links between the collagen molecules. This article reports results on the distribution of the different cross‐links in the disc and the changes that occur with age, degenerative disc disease, and scoliosis. Methods. Thirty‐three discs were obtained from patients with degenerative disc disease and 29 discs from patients with scoliosis. Samples were acid hydrolyzed and the collagen cross‐links analyzed by either fractionation on an amino acid analyzer configured for cross‐link analysis using ninhydrin postcolumn detection or fractionation by high‐pressure liquid chromatography with fluorescence detection. Results. The reducible cross‐links and the mature cross‐link all increased from the outer anulus fibrosus through into the nucleus pulposus. The highest levels of the mature cross‐link were found in the cartilage endplate. The nonenzymic derived cross‐link, pentosidine, in contrast, showed little difference across the disc, but did show the expected age‐related increase. In degenerative disc disease, no change in the levels of the reducible or mature cross‐links was found, but a decrease was observed in the levels of the age‐related cross‐link pentosidine in the more severe disease samples. In scoliosis, significantly higher levels of the reducible cross‐links were found on the convex than on the concave side of the scoliotic disc. Conclusions. These changes in the cross‐link profile of the intervertebral disc in degenerative disc disease and scoliosis are indicative of increased matrix turnover and tissue remodeling and likely to have implications for the progression of these disorders.

Quantitative analysis of collagen and elastin cross-links using a single-column system

The separation of both the immature and mature cross-links present in collagen together with the stable cross-links of elastin has been achieved on a single ion-exchange column. This technique avoids the current necessity for two different systems, ion-exchange and high-performance liquid chromatography-fluorescence techniques. The value of the method is illustrated by the comparison of the cross-link contents of aging bovine skin, from foetal to old age.

Quantitative Determination of Collagen Cross-links

The primary functional role of collagen is as a supporting tissue and it is now established that the aggregated forms of the collagen monomers are stabilised to provide mechanical strength by a series of intermolecular cross-links. In order to understand the mechanical properties of collagen, it is necessary to identify and quantitatively determine the concentration of the cross-links during their changes with maturation, ageing and disease. These cross-links are formed by oxidative deamination of the epsilon-amino group of the single lysine or hydroxylysine in the amino and carboxy telopeptides of collagen by lysyl oxidase, the aldehyde formed reacting with a specific lysine or hydroxylysine in the triple helix. The divalent Schiff base and keto-amine bonds so formed link the molecules head to tail and spontaneously convert during maturation to trivalent cross-links, a histidine derivative and cyclic pyridinolines and pyrroles, respectively. These latter bonds are believed to be transverse inter-fibrillar cross-links, and are tissue rather than species specific. We describe the determination of these cross-links in detail.Elastin is also stabilised by cross-linking based on oxidative deamination of most of its lysine residues to yield tetravalent cross-links, desmosine and iso-desmosine, the determination of which is also described.A second cross-linking pathway occurs during ageing (and to a greater extent in diabetes mellitus) involving reaction with tissue glucose. The initial product glucitol-lysine can be determined as furosine and pyridosine, and determination of advanced glycation end-products believed to be cross-links, such as pentosidine, are also described.

The role of the α2 chain in the stabilization of the collagen type I heterotrimer: A study of the type I homotrimer in oim mouse tissues

We have previously reported that the fragility of skin, tendon and bone from the oim mouse is related to a significant reduction in the intermolecular cross-linking. The oim mutation is unlikely to affect the efficacy of the lysyl oxidase, suggesting that the defect is in the molecule and fibre. We have therefore investigated the integrity of both the oim collagen molecules and the fibre by differential scanning calorimetry. The denaturation temperature of the oim molecule in solution and the fibre from tail tendon were found to be higher than the wild-type by 2.6deg.C and 1.9deg.C, respectively. With the loss of the alpha2 chain, the hydroxyproline content of the homotrimer is higher than the heterotrimer, which may account for the increase. There is a small decrease in the enthalpy of the oim fibres but it is not significant, suggesting that the amount of disorder of the triple-helical molecules and of the fibres is small and involves only a small part of the total bond energy holding the helical structure together. The difference in denaturation temperature of the skin collagen molecules (t(m)) and fibres (t(d)) is significantly lower for the oim tissues, 19.9deg.C against 23.1deg.C, indicating reduced molecular interactions and hence packing of the molecules in the fibre. Computation of the volume fraction of the water revealed that the interaxial separation of the oim fibres was indeed greater, increasing from 19.6A to 21.0A. This difference of 1.4A, equivalent to a C-C bond, would certainly decrease the ability of the telopeptide aldehyde to interact with the epsilon -amino group from an adjacent molecule and form a cross-link. We suggest, therefore, that the reduction of the cross-linking is due to increased water content of the fibre rather than a distortion of the molecular structure. The higher hydrophobicity of the alpha2 chain appears to play a role in the stabilisation of heterotrimeric type I collagen, possibly by increasing the hydrophobic interactions between the heterotrimeric molecules, thereby reducing the water content and increasing the binding of the molecules in the fibre.

Identification of an Intermediate State in the Helix-Coil Degradation of Collagen by Ultraviolet Light*

Differential scanning calorimetry has revealed the presence of a new denaturation endotherm at 32 °C following UV irradiation of collagen, compared with 39 °C for the native triple helix. Kinetic analyses showed that the new peak was a previously unknown intermediate state in the collagen helix-coil transition induced by UV light, and at least 80% of the total collagen was transformed to random chains via this state. Its rate of formation was increased by hydrogen peroxide and inhibited by free radical scavengers. SDS-polyacrylamide gels showed evidence of competing reactions of cross-linking and random primary chain scission. The cross-linking was evident from initial gelling of the collagen solution, but there was no evidence for a dityrosine cross-link. Primary chain scission was confirmed by end group analysis using fluorescamine. Electron microscopy showed that the segment long spacing crystallites formed from the intermediate state were identical to the native molecules. Clearly, collagen can undergo quite extensive damage by cleavage of peptide bonds without disorganizing the triple helical structure. This leads to the formation of a damaged intermediate state prior to degradation of the molecules to short random chains.

Phenotypic expression of osteoblast collagen in osteoarthritic bone: production of type I homotrimer.

The metabolism and total amount of the collagen of subchondral bone are increased several fold in osteoathritic femurs compared with controls. We now report for the first time that the quality of the collagen is modified by the formation of type I homotrimer. The homotrimer fibre has been reported to possess a reduced mechanical strength and mineralisation in bone. The presence of the latter therefore accounts for narrower disorganised collagen fibres and decreased mineralisation, and a reduction in mechanical stability of the osteoarthritic femoral head. These changes in the subchondral bone are likely to be of considerable importance in the pathogenesis of osteoarthritis.

Age related changes in the non-collagenous components of the extracellular matrix of the human lamina cribrosa

AIMS To investigate age related alterations in the non-collagenous components of the human lamina cribrosa. METHODS Fibronectin, elastin, and glial fibrillary acidic protein (GFAP) staining were assessed in young and old laminae cribrosae. An age range (7 days to 96 years) of human laminae cribrosae were analysed for lipid content (n=9), cellularity (n=28), total sulphated glycosaminoglycans (n=28), elastin content (n=9), and water content (n=56), using chloroform-methanol extraction, fluorimetry, the dimethylmethylene blue assay, and ion exchange chromatography, respectively. RESULTS Qualitatively, an increase in elastin and a decrease in fibronectin and GFAP were demonstrated when young tissue was compared with the elderly. Biochemical analysis of the ageing human lamina cribrosa demonstrated that elastin content increased from 8% to 28% dry tissue weight, total sulphated glycosaminoglycans decreased, and lipid content decreased from 45% to 25%. There were no significant changes in total cellularity or water content. CONCLUSION These alterations in composition may be indicative of the metabolic state of the lamina cribrosa as it ages, and may contribute to changes in mechanical integrity. Such changes may be implicated in the susceptibility of the elderly lamina cribrosa and also its response to glaucomatous optic neuropathy.

Biomechanical and biochemical study of a standardized wound healing model

Standardized protocols were developed for use in a detailed investigation into the biomechanical and biochemical properties of a dermal wound healing model in the rat. The use of a rapid freezing method at -80 degrees C minimized the detrimental effects of freezing on the biomechanical properties of the tissue and also allowed for convenient inter-laboratory collaboration to be performed. The methodology described allowed for the simultaneous and reproducible measurement of tensile strength, collagen cross-linking and proteolytic enzyme activity. Increases in the tensile properties of the tissue with time were consistent with an active process of remodelling process as indicated by changes in the cross-link and enzyme profiles. Initially the granulation tissue was comparatively rich in the keto-imine cross-link hydroxylysino-keto-norleucine, which was later replaced by the aldimine cross-link dehydro-hydroxy-lysinonorleucine. The mature cross-link histidino-hydroxy-lysinonorleucine was not observed within the granulation tissue at any stage and was also absent in aged control skin. A peak of matrix metalloproteinase-9 activity was observed at early timepoints (48 hr) and then decreased rapidly to normal levels and is consistent with an acute inflammatory response. In contrast matrix metalloproteinase-2 activity peaked later (3 days) and then decreased gradually, consistent with its role as one of the predominant enzymes involved in the remodelling process. The results described validate the animal model used and emphasize its potential for use in combined biomechanical and biochemical studies of acute wound healing.

Cross-link profile of bone collagen correlates with structural organization of trabeculae

Little is known regarding the mechanisms that govern the structural organization of cancellous bone. In this study, we compare the nature of the collagen in vertebral cancellous bone with the structural organization of its trabecular network. Cylindrical specimens of cancellous bone from vertebrae were obtained from nine autopsy subjects (ages 46-88). In each subject, eight pairs of corresponding samples were obtained from three levels in the spine and three areas within the vertebral body, leading to a total of 68 pairs of samples. The cylinders from one side were used for morphometry and the classical morphometrical parameters were obtained (BV/TV, bone volume fraction; Tb.Th, trabecular thickness; Tb.N, number; Tb.Sp, trabecular spacing) and strut analysis (TSL, total strut length; Nd, number of nodes; Fe, number of free-ends). The amount of osteoid bone was also quantified. The cylinders from the other side were powdered and used for collagen assessment, including the amount of collagen (% w/w), and its content in immature cross-links; such as hydroxylysinonorleucine (mol/mol of collagen) and dihydroxylysinornorleucine, as well as stable mature cross-links, such as hydroxylysylpyridinoline (HP), lysylpyridinoline (LP), and the pyrrole cross-links. A random regression model was used to explore the correlations. None of the biochemical parameters correlated with the BV/TV except the ratio between immature and mature cross-links (eta(2) = 0.34, p < 0.05). There was no relationship between the amount of osteoid bone and the cross-link profile. However, the concentration of pyrrole and HP cross-links in the bone samples correlated with the structural organization of its trabeculae, but in an opposite direction. Hence, the pyrrole/HP ratio was a good predictor of Tb.Th, Tb.N, Tb.Sp, and TSL (eta(2) > 0.65 and p < 0.01) as well as Fe and star marrow space (eta(2) > 0.45 and p < 0.05). The cylinders from subjects with high pyrrole or low HP in their bone collagen had a relatively thick and simple structure. Those with low pyrrole and high HP had relatively thin trabeculae that were more numerous and spread over a complex network. The relative concentrations of the pyrrole and pyridinoline cross-links appear to reflect the structural organization of the trabeculae.