Tracking calcification in tissue-engineered bone using synchrotron micro-FTIR and SEM.

One novel tissue engineering approach to mimic in vivo bone formation is the use of aggregate or micromass cultures. Various qualitative and quantitative techniques, such as histochemical staining, protein assay kits and RT-PCR, have been used previously on cellular aggregate studies to investigate how these intricate arrangements lead to mature bone tissue. However, these techniques struggle to reveal spatial and temporal distribution of proliferation and mineralization simultaneously. Synchrotron-based Fourier transform infrared microspectroscopy (micro-FTIR) offers a unique insight at the molecular scale by coupling high IR sensitivity to organic matter with the high spatial resolution allowed by diffraction limited SR microbeam. This study is set to investigate the effects of culture duration and aggregate size on the dynamics and spatial distribution of calcification in engineered bone aggregates by a combination of micro-FTIR and scanning electron microscopy (SEM)/energy-dispersive X-ray spectroscopy (EDX). A murine bone cell line has been used, and small/large bone aggregates have been induced using different chemically treated culture substrates. Our findings suggest that bone cell aggregate culturing can greatly increase levels of mineralization over short culture periods. The size of the aggregates influences mineralisation rates with larger aggregates mineralizing at a faster rate than their smaller counterparts. The micro-FTIR mapping has demonstrated that mineralization in the larger aggregates initiated from the periphery and spread to the centre, whilst the smaller aggregates have more minerals in the centre at the early stage and deposited more in the periphery after further culturing, implying that aggregate size influences calcification distribution and development over time. SEM/EDX data correlates well with the micro-FTIR results for the total mineral content. Thus, synchrotron-based micro-FTIR can accurately track mineralization process/mechanism in the engineered bone.

A facile in vitro model to study rapid mineralization in bone tissues.

BACKGROUND: Mineralization in bone tissue involves stepwise cell-cell and cell-ECM interaction. Regulation of osteoblast culture microenvironments can tailor osteoblast proliferation and mineralization rate, and the quality and/or quantity of the final calcified tissue. An in vitro model to investigate the influencing factors is highly required. METHODS: We developed a facile in vitro model in which an osteoblast cell line and aggregate culture (through the modification of culture well surfaces) were used to mimic intramembranous bone mineralization. The effect of culture environments including culture duration (up to 72 hours for rapid mineralization study) and aggregates size (monolayer culture as control) on mineralization rate and mineral quantity/quality were examined by osteogenic gene expression (PCR) and mineral markers (histological staining, SEM-EDX and micro-CT). RESULTS: Two size aggregates (on average, large aggregates were 745 µm and small 79 µm) were obtained by the facile technique with high yield. Cells in aggregate culture generated visible and quantifiable mineralized matrix within 24 hours, whereas cells in monolayer failed to do so by 72 hours. The gene expression of important ECM molecules for bone formation including collagen type I, alkaline phosphatase, osteopontin and osteocalcin, varied temporally, differed between monolayer and aggregate cultures, and depended on aggregate size. Monolayer specimens stayed in a proliferation phase for the first 24 hours, and remained in matrix synthesis up to 72 hours; whereas the small aggregates were in the maturation phase for the first 24 and 48 hour cultures and then jumped to a mineralization phase at 72 hours. Large aggregates were in a mineralization phase at all these three time points and produced 36% larger bone nodules with a higher calcium content than those in the small aggregates after just 72 hours in culture. CONCLUSIONS: This study confirms that aggregate culture is sufficient to induce rapid mineralization and that aggregate size determines the mineralization rate. Mineral content depended on aggregate size and culture duration. Thus, our culture system may provide a good model to study regulation factors at different development phases of the osteoblastic lineage.

Trans-femoral amputation in elderly dysvascular patients: reliable results with a technique of myodesis.

The clinical and functional results of traditional techniques for trans-femoral amputation are often poor. The ISPO consensus conference on amputation surgery in 1990 at Glasgow recommended myodesis as an important integral part of surgical procedure and should be carried out as much as possible. Muscle stabilization provides a stable functional amputation stump. This improves the prosthetic management and walking ability. A technique of myodesis for trans-femoral amputation has been developed in Dundee, especially for elderly dysvascular patients. The functional and clinical results of this technique were studied in 33 patients, who underwent the surgical procedure. Data regarding patient demographics, postoperative morbidity, mortality and functional status were obtained from a prospectively recorded pro forma. Fourteen patients out of 33, who were operated using this technique, were fitted with artificial limbs. Of these, 11 (78.5%) were still using the prosthesis at a mean follow-up of 40 months. There was 100% primary wound healing. Two patients underwent further revision surgery for delayed stump problems. Good clinical and functional results were obtained using this technique. It is particularly suited for the elderly dysvascular patients, whose stumps are shorter and bone quality poor. The low rate of stump problems and consequent revision surgery enables a more comfortable stump for non-prosthetic users.