UNLABELLED: NMR was used to measure matrix water content in normal and hypomineralized cortical bone. Water content showed an inverse relationship with mineral content, suggesting it could serve as a surrogate measure for the bone's degree of mineralization. INTRODUCTION: So far, true bone mineral density (DMB; degree of mineralization of bone) can not be measured nondestructively. MATERIALS AND METHODS: Here, a new technique combining 1H nuclear magnetic resonance (NMR) spectroscopy and deuterium isotope exchange was used to measure water content in cortical bone from two groups of rabbits: a control group and a group fed a low-phosphorus (P) diet to induce hypomineralization of the bone matrix. RESULTS: NMR-derived water content was higher in the P-depleted group and showed an inverse relationship with mineral content (measured gravimetrically and by 31p NMR). Hypomineralized bone was found to be weaker than normal bone as demonstrated by mechanical testing. More importantly, the data showed a strong inverse correlation between water content and bone mechanical properties, which indicates that water content could be predictive of the bone's mechanical competence. CONCLUSIONS: Water content could potentially serve as a surrogate measure for the bone's degree of mineralization, and this technique could be used to study other disorders of mineral homeostasis known to alter the mineralization state of the matrix. Although the method presented here is not suitable for in vivo measurements of bone water content, the authors have previously shown that 1H NMR images of bone can be acquired; thus, noninvasive quantification of bone water may be feasible.
UNLABELLED: NMR was used to measure matrix water content in normal and hypomineralized cortical bone. Water content showed an inverse relationship with mineral content, suggesting it could serve as a surrogate measure for the bone's degree of mineralization. INTRODUCTION: So far, true bone mineral density (DMB; degree of mineralization of bone) can not be measured nondestructively. MATERIALS AND METHODS: Here, a new technique combining 1H nuclear magnetic resonance (NMR) spectroscopy and deuterium isotope exchange was used to measure water content in cortical bone from two groups of rabbits: a control group and a group fed a low-phosphorus (P) diet to induce hypomineralization of the bone matrix. RESULTS: NMR-derived water content was higher in the P-depleted group and showed an inverse relationship with mineral content (measured gravimetrically and by 31p NMR). Hypomineralized bone was found to be weaker than normal bone as demonstrated by mechanical testing. More importantly, the data showed a strong inverse correlation between water content and bone mechanical properties, which indicates that water content could be predictive of the bone's mechanical competence. CONCLUSIONS:Water content could potentially serve as a surrogate measure for the bone's degree of mineralization, and this technique could be used to study other disorders of mineral homeostasis known to alter the mineralization state of the matrix. Although the method presented here is not suitable for in vivo measurements of bone water content, the authors have previously shown that 1H NMR images of bone can be acquired; thus, noninvasive quantification of bone water may be feasible.
Authors: Hamidreza Saligheh Rad; Shing Chun Benny Lam; Jeremy F Magland; Henry Ong; Cheng Li; Hee Kwon Song; James Love; Felix W Wehrli Journal: NMR Biomed Date: 2011-01-28 Impact factor: 4.044
Authors: Alan C Seifert; Cheng Li; Chamith S Rajapakse; Mahdieh Bashoor-Zadeh; Yusuf A Bhagat; Alexander C Wright; Babette S Zemel; Antonios Zavaliangos; Felix W Wehrli Journal: NMR Biomed Date: 2014-05-21 Impact factor: 4.044
Authors: Cheng Li; Alan C Seifert; Hamidreza Saligheh Rad; Yusuf A Bhagat; Chamith S Rajapakse; Wenli Sun; Shing Chun Benny Lam; Felix W Wehrli Journal: Radiology Date: 2014-05-02 Impact factor: 11.105