Browsing by Subject "Atomic Force Microscopy"

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    Applications of atomic force microscopy for the assessment of nanoscale morphological and mechanical properties of bone
    (2012-01) Wallace, Joseph M.
    Scanning probe microscopy (SPM) has been in use for 30 years, and the form of SPM known as atomic force microscopy (AFM) has been around for 25 of those years. AFM has been used to produce high resolution images of a variety of samples ranging from DNA to carbon nanotubes. Type I collagen and many collagen-based tissues (including dentin, tendon, cartilage, skin, fascia, vocal cords, and cornea) have been studied with AFM, but comparatively few studies of bone have been undertaken. The purpose of this review is to introduce the general principles of AFM operation, demonstrate what AFM has been used for in bone research, and discuss the new directions that this technique can take the study of bone at the nanoscale.
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    Nanoscale Changes in Collagen are Reflected in Physical and Mechanical Properties of Bone at the Microscale in Diabetic Rats
    (2014-03) Hammond, Max A.; Gallant, Maxime A.; Burr, David B.; Wallace, Joseph M.
    Diabetes detrimentally affects the musculoskeletal system by stiffening the collagen matrix due to increased advanced glycation end products (AGEs). In this study, tibiae and tendon from Zucker diabetic Sprague–Dawley (ZDSD) rats were compared to Sprague–Dawley derived controls (CD) using Atomic Force Microscopy. ZDSD and CD tibiae were compared using Raman Spectroscopy and Reference Point Indentation (RPI). ZDSD bone had a significantly different distribution of collagen D-spacing than CD (p = 0.015; ZDSD n = 294 fibrils; CD n = 274 fibrils) which was more variable and shifted to higher values. This shift between ZDSD and CD D-spacing distribution was more pronounced in tendon (p < 0.001; ZDSD n = 350; CD n = 371). Raman revealed significant increases in measures of bone matrix mineralization in ZDSD (PO43 − ν1/Amide I p = 0.008; PO43 − ν1/CH2 wag p = 0.047; n = 5 per group) despite lower bone mineral density (aBMD) and ash fraction indicating diabetes may preferentially reduce the Raman signature of collagen. Decreased indentation distance increase (p = 0.010) and creep indentation distance (p = 0.040) measured by RPI (n = 9 per group) in ZDSD rats suggest a matrix more resistant to indentation under the high stresses associated with RPI at this length scale. There were significant correlations between Raman and RPI measurements in the ZDSD population (n = 18 locations) but not the CD population (n = 16 locations) indicating that while RPI is relatively unaffected by biological noise, it is sensitive to disease-induced compositional changes. In conclusion, diabetes in the ZDSD rat causes changes to the nanoscale morphology of collagen that result in compositional and mechanical effects in bone at the microscale.