Fourier Transform Infrared (FT-IR) spectroscopic imaging has been earlier applied for the spatial estimation of the collagen and the proteoglycan (PG) contents of articular cartilage (AC). However, earlier studies have been limited to the use of univariate analysis techniques. Current analysis methods lack the needed specificity for collagen and PGs. The aim of the present study was to evaluate the suitability of partial least squares regression (PLSR) and principal component regression (PCR) methods for the analysis of the PG content of AC. Multivariate regression models were compared with earlier used univariate methods and tested with a sample material consisting of healthy and enzymatically degraded steer AC. Chondroitinase ABC enzyme was used to increase the variation in PG content levels as compared to intact AC. Digital densitometric measurements of Safranin O –stained sections provided the reference for PG content. The results showed that multivariate regression models predict PG content of AC significantly better than earlier used absorbance spectrum (i.e. the area of carbohydrate region with or without amide I normalization) or second derivative spectrum univariate parameters. Increased molecular specificity favours the use of multivariate regression models, but they require more knowledge of chemometric analysis and extended laboratory resources for gathering reference data for establishing the models. When true molecular specificity is required, the multivariate models should be used.
References
[1]
Mow VC, Ratcliffe A, Poole AR (1992) Cartilage and diarthrodial joints as paradigms for hierarchical materials and structures. Biomaterials 13: 67–97.
[2]
Armstrong CG, Mow VC (1982) Variations in the intrinsic mechanical properties of human articular cartilage with age, degeneration, and water content. J Bone Joint Surg Am 64: 88–94.
[3]
Julkunen P, Wilson W, Jurvelin JS, Rieppo J, Qu CJ, et al. (2008) Stress-relaxation of human patellar articular cartilage in unconfined compression: prediction of mechanical response by tissue composition and structure. J Biomech 41: 1978–1986.
[4]
Camacho NP, West P, Torzilli PA, Mendelsohn R (2001) FTIR microscopic imaging of collagen and proteoglycan in bovine cartilage. Biopolymers 62: 1–8.
[5]
Rieppo L, Saarakkala S, Narhi T, Holopainen J, Lammi M, et al. (2010) Quantitative analysis of spatial proteoglycan content in articular cartilage with Fourier transform infrared imaging spectroscopy: Critical evaluation of analysis methods and specificity of the parameters. Microsc Res Tech 73: 503–512.
[6]
Mark H, Workman J (2003) Derivatives in spectroscopy Part II - The true derivative. Spectroscopy 18: 25–28.
[7]
Martens H, Naes T (1989) Multivariate Calibration. Chichester: John Wiley & Sons Ltd.
[8]
Baykal D, Irrechukwu O, Lin PC, Fritton K, Spencer RG, et al. (2010) Nondestructive assessment of engineered cartilage constructs using near-infrared spectroscopy. Appl Spectrosc 64: 1160–1166.
[9]
Kim M, Bi X, Horton WE, Spencer RG, Camacho NP (2005) Fourier transform infrared imaging spectroscopic analysis of tissue engineered cartilage: histologic and biochemical correlations. J Biomed Opt 10: 031105.
[10]
Theodoropoulos JS, De Croos JN, Park SS, Pilliar R, Kandel RA (2011) Integration of tissue-engineered cartilage with host cartilage: an in vitro model. Clin Orthop Relat Res 469: 2785–2795.
[11]
Mouw JK, Case ND, Guldberg RE, Plaas AH, Levenston ME (2005) Variations in matrix composition and GAG fine structure among scaffolds for cartilage tissue engineering. Osteoarthritis Cartilage 13: 828–836.
[12]
Wang QG, Hughes N, Cartmell SH, Kuiper NJ (2010) The composition of hydrogels for cartilage tissue engineering can influence glycosaminoglycan profile. Eur Cell Mater 19: 86–95.
[13]
Saarakkala S, Julkunen P (2010) Specificity of Fourier Transform Infrared (FTIR) Microspectroscopy to Estimate Depth-Wise Proteoglycan Content in Normal and Osteoarthritic Human Articular Cartilage. Cartilage 1: 262–269.
[14]
Yin J, Xia Y (2010) Macromolecular concentrations in bovine nasal cartilage by fourier transform infrared imaging and principal component regression. Appl Spectrosc 64: 1199–1208.
[15]
Bonifacio A, Beleites C, Vittur F, Marsich E, Semeraro S, et al. (2010) Chemical imaging of articular cartilage sections with Raman mapping, employing uni- and multi-variate methods for data analysis. Analyst 135: 3193–3204.
[16]
Rieppo J, T?yr?s J, Nieminen MT, Kovanen V, Hyttinen MM, et al. (2003) Structure-function relationships in enzymatically modified articular cartilage. Cells Tissues Organs 175: 121–132.
[17]
Király K, Lapvetel?inen T, Arokoski J, T?rr?nen K, Modis L, et al. (1996) Application of selected cationic dyes for the semiquantitative estimation of glycosaminoglycans in histological sections of articular cartilage by microspectrophotometry. Histochem J 28: 577–590.
[18]
Kiviranta I, Jurvelin J, Tammi M, S??m?nen AM, Helminen HJ (1985) Microspectrophotometric quantitation of glycosaminoglycans in articular cartilage sections stained with Safranin O. Histochemistry 82: 249–255.
[19]
Martens HA, Dardenne P (1998) Validation and verification of regression in small data sets. Chemometrics and Intelligent Laboratory Systems 44: 99–121.
[20]
Boskey A, Pleshko Camacho N (2007) FT-IR imaging of native and tissue-engineered bone and cartilage. Biomaterials 28: 2465–2478.
[21]
Kohler A, Bertrand D, Martens H, Hannesson K, Kirschner C, et al. (2007) Multivariate image analysis of a set of FTIR microspectroscopy images of aged bovine muscle tissue combining image and design information. Anal Bioanal Chem 389: 1143–1153.
[22]
Servaty R, Schiller J, Binder H, Arnold K (2001) Hydration of polymeric components of cartilage–an infrared spectroscopic study on hyaluronic acid and chondroitin sulfate. Int J Biol Macromol 28: 121–127.
[23]
Jackson M, Sowa MG, Mantsch HH (1997) Infrared spectroscopy: a new frontier in medicine. Biophys Chem 68: 109–125.
[24]
Steiger JH (1980) Tests for Comparing Elements of a Correlation Matrix. Psychological Bulletin 87: 245–251.
[25]
Rieppo J, Hyttinen MM, Halmesmaki E, Ruotsalainen H, Vasara A, et al. (2009) Changes in spatial collagen content and collagen network architecture in porcine articular cartilage during growth and maturation. Osteoarthritis Cartilage 17: 448–455.
[26]
Klein TJ, Chaudhry M, Bae WC, Sah RL (2007) Depth-dependent biomechanical and biochemical properties of fetal, newborn, and tissue-engineered articular cartilage. J Biomech 40: 182–190.
[27]
Venn MF (1978) Variation of chemical composition with age in human femoral head cartilage. Ann Rheum Dis 37: 168–174.
[28]
Venn M, Maroudas A (1977) Chemical composition and swelling of normal and osteoarthrotic femoral head cartilage. I. Chemical composition. Ann Rheum Dis 36: 121–129.
[29]
Buckwalter JA, Mankin HJ (1997) Articular Cartilage, Part II: Degeneration and osteoarthritis, repair, regeneration, and transplantation. J Bone Joint Surg Am 79: 612–632.
[30]
Korhonen RK, Wong M, Arokoski J, Lindgren R, Helminen HJ, et al. (2002) Importance of the superficial tissue layer for the indentation stiffness of articular cartilage. Med Eng Phys 24: 99–108.
[31]
Jackson M, Choo LP, Watson PH, Halliday WC, Mantsch HH (1995) Beware of connective tissue proteins: assignment and implications of collagen absorptions in infrared spectra of human tissues. Biochim Biophys Acta 1270: 1–6.
[32]
Rieppo J, Hyttinen MM, Jurvelin JS, Helminen HJ (2004) Reference sample method reduces the error caused by variable cryosection thickness in Fourier transform infrared imaging. Appl Spectrosc 58: 137–140.
