Correlating Changes in Collagen Secondary Structure with Aging and Defective Type II Collagen by Raman Spectroscopy

Dehring, Karen A.; Smukler, Abigail R.; Roessler, Blake J.; Morris, Michael D.

doi:10.1366/000370206776593582

Cited by 66 publications

(59 citation statements)

References 25 publications

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“…Del1 (C/¡) mice have a mutation in the COL2A1 gene, which causes a truncation in collagen polypeptide chains. Band ratio of 1,241 cm ¡1 (random coil content) to 1,269 cm ¡1 (alpha-helix content) was used to measure the degree of disorder in the collagen secondary structure (74). In a later study, deconvolution of the amide III band region was also used to assess the differences between healthy control and osteoarthritic human knee tibial plateau samples.…”

Section: ¡1mentioning

confidence: 99%

Vibrational spectroscopy of articular cartilage

Rieppo

Töyräs

Saarakkala

2016

Applied Spectroscopy Reviews

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Articular cartilage is a connective tissue that is located at the ends of long bones. Type II collagen, proteoglycans, water, and chondrocytes are the main constituents of articular cartilage. Osteoarthritis, the most common joint disease in the world, causes degenerative changes in articular cartilage tissue. Fourier transform infrared, Raman, and near infrared spectroscopic techniques offer versatile tools to assess biochemical composition and quality of articular cartilage. These vibrational spectroscopic techniques can be used to broaden our understanding about the compositional changes during osteoarthritis, and they also hold promise in disease diagnostics. In this article, the current literature of articular cartilage spectroscopic studies is reviewed.

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Section: ¡1mentioning

confidence: 99%

Vibrational spectroscopy of articular cartilage

Rieppo

Töyräs

Saarakkala

2016

Applied Spectroscopy Reviews

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“…Raman spectroscopy has been used widely to investigate the mineralogy of and to document the collagen in bone materials [10,11,[13][14][15]38,[45][46][47][48]. The most characteristic spectral regions of typical bone materials are 400-1200 cm −1 for mineral bands and 2500-3150 cm −1 for organic bands.…”

Section: Raman Microprobe Spectroscopymentioning

confidence: 99%

“…Increasing evidence, however, indicates that both chemical (e.g., concentration of carbonate and acid phosphate) and physical properties (e.g., degree of crystallinity and crystallite size) of the bone mineral can be changed during removal of collagen [8,9]. In recent years, nondestructive spectroscopic techniques, such as Raman and IR spectroscopy, have been used to obtain separate spectral information on the mineral and the collagen components in situ in bone samples, typically with little to no chemical preparation of the sample [10][11][12][13][14][15]. However, the presence of collagen does complicate the interpretation of vibrational spectra [9], and such techniques do not permit detailed chemical (elemental) analysis or mechanical testing of the bone mineral.…”

Section: Introductionmentioning

confidence: 99%

Hypermineralized whale rostrum as the exemplar for bone mineral

Li¹,

Pasteris²,

Novack³

2013

Connect Tissue Res

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Although bone is a nanocomposite of mineral and collagen, mineral has been the more elusive component to study. A standard for bone mineral clearly is needed. We hypothesized that the most natural, least-processed bone mineral could be retrieved from the most highly mineralized bone. We therefore studied the rostrum of the toothed whale Mesoplodon densirostris, which has the densest recognized bone. Essential to establishment of a standard for bone mineral is documentation that the proposed tissue is bone-like in all properties except for its remarkably high concentration of mineral. Transmitted-light microscopy of unstained sections of rostral material shows normal bone morphology in osteon geometry, lacunae concentration, and vasculature development. Stained sections reveal extremely low density of thin collagen fibers throughout most of the bone, but enrichment in and thicker collagen fibers around vascular holes and in a minority of osteons. FE-SEM shows the rostrum to consist mostly of dense mineral prisms. Most rostral areas have the same chemical-structural features, Raman spectroscopically dominated by strong bands at ~962 cm −1 and weak bands at ~2940 cm −1 . Spectral features indicate that the rostrum is composed mainly of the calcium phosphate mineral apatite and has only about 4 wt.% organic content. The degree of carbonate substitution (~8.5 wt.% carbonate) in the apatite is in the upper range found in most types of bone. We conclude that, despite its enamel-like extraordinarily high degree of mineralization, the rostrum is in all other features bone-like. Its mineral component is the long-sought uncontaminated, unaltered exemplar of bone mineral.

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“…Raman analysis has been performed for the analysis of collagen in the sclera, articular cartilage, and subchondral bone of wild-type and transgenic mice harboring structural truncations in the introduced collagen type II transgene. 31 Moreover, Raman microspectroscopic mapping studies have already been carried out on human bronchial tissue. 32 FTIR spectroscopy is usually a more common tool to study articular cartilage.…”

Section: Confocal Raman Microspectroscopymentioning

confidence: 99%

Recognizing different tissues in human fetal femur cartilage by label-free Raman microspectroscopy

et al. 2012

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Abstract. Traditionally, the composition of bone and cartilage is determined by standard histological methods. We used Raman microscopy, which provides a molecular "fingerprint" of the investigated sample, to detect differences between the zones in human fetal femur cartilage without the need for additional staining or labeling. Raman area scans were made from the (pre)articular cartilage, resting, proliferative, and hypertrophic zones of growth plate and endochondral bone within human fetal femora. Multivariate data analysis was performed on Raman spectral datasets to construct cluster images with corresponding cluster averages. Cluster analysis resulted in detection of individual chondrocyte spectra that could be separated from cartilage extracellular matrix (ECM) spectra and was verified by comparing cluster images with intensity-based Raman images for the deoxyribonucleic acid/ ribonucleic acid (DNA/RNA) band. Specific dendrograms were created using Ward's clustering method, and principal component analysis (PCA) was performed with the separated and averaged Raman spectra of cells and ECM of all measured zones. Overall (dis)similarities between measured zones were effectively visualized on the dendrograms and main spectral differences were revealed by PCA allowing for label-free detection of individual cartilaginous zones and for label-free evaluation of proper cartilaginous matrix formation for future tissue engineering and clinical purposes.

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Correlating Changes in Collagen Secondary Structure with Aging and Defective Type II Collagen by Raman Spectroscopy

Cited by 66 publications

References 25 publications

Vibrational spectroscopy of articular cartilage

Vibrational spectroscopy of articular cartilage

Hypermineralized whale rostrum as the exemplar for bone mineral

Recognizing different tissues in human fetal femur cartilage by label-free Raman microspectroscopy

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