Kinetics of <sup>1</sup>H → <sup>31</sup>P NMR cross‐polarization in bone apatite and its mineral standards

Kaflak, Agnieszka; Kołodziejski, Wacław

doi:10.1002/mrc.2207

Cited by 38 publications

(46 citation statements)

References 43 publications

(71 reference statements)

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“…This is why in such experiments signal intensity must be compared over a variety of contact times, and not only for its fixed value. Such investigations were carried out considering the phosphorus components and their structure in bone (the graph of intensity vs. contact time is strongly dependent on the material structure) [36–39] and bone implants [33] (Fig. 9).…”

Section: Solid-state Nmr (Ssnmr)mentioning

confidence: 99%

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

Kruk

Doskocz²,

Jodłowska

et al. 2016

Appl Magn Reson

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Metabolomics is a rapidly developing branch of science that concentrates on identifying biologically active molecules with potential biomarker properties. To define the best biomarkers for diseases, metabolomics uses both models (in vitro, animals) and human, as well as, various techniques such as mass spectroscopy, gas chromatography, liquid chromatography, infrared and UV–VIS spectroscopy and nuclear magnetic resonance. The last one takes advantage of the magnetic properties of certain nuclei, such as 1H, 13C, 31P, 19F, especially their ability to absorb and emit energy, what is crucial for analyzing samples. Among many spectroscopic NMR techniques not only one-dimensional (1D) techniques are known, but for many years two-dimensional (2D, for example, COSY, DOSY, JRES, HETCORE, HMQS), three-dimensional (3D, DART-MS, HRMAS, HSQC, HMBC) and solid-state NMR have been used. In this paper, authors taking apart fundamental division of nuclear magnetic resonance techniques intend to shown their wide application in metabolomic studies, especially in identifying biomarkers.

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Section: Solid-state Nmr (Ssnmr)mentioning

confidence: 99%

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

Kruk

Doskocz²,

Jodłowska

et al. 2016

Appl Magn Reson

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“…Bone consists of approximately 65% mineral, 25% organic matrix, and 10% water by weight [5]. Electron microscopy studies have revealed that chemically isolated bone minerals have globular morphologies of sizes from 70 to 90 nm, which are aggregates of smaller particles with sizes around 20 nm [6].…”

Section: Introductionmentioning

confidence: 99%

“…The biological apatite nanocrystal consists of a nanocrystalline apatite core enclosed by a 1-2 nm amorphous layer of calcium phosphate that has been postulated to be a precursor of hydroxyapatite formation [4,5,7,8,16,17]. Minerals octacalcium phosphate (Ca 8 (HPO 4 ) 2 (PO4) 4 ·5H 2 O) and brushite (CaHPO 4 ·2H 2 O) have been considered possible compositions of the amorphous layer [15,16].…”

Section: Introductionmentioning

confidence: 99%

Analyses of mineral specific surface area and hydroxyl substitution for intact bone

Taylor

Rendina

Smith

et al. 2013

Chemical Physics Letters

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Bone minerals possess two primary hydrogen sources: hydroxide ions in the nanocrystalline core and structural water in the amorphous surface layer. In order to accurately measure their concentrations using hydrogen to phosphorus cross polarization NMR spectroscopy, it is necessary to analyze the dependence of signal intensities on serial contact times, namely, cross polarization kinetics. A reliable protocol is developed to iteratively decompose the severely overlapped spectra and to analyze the cross-polarization kinetics, leading to measurement of hydroxyl and structural water concentrations. Structural water concentration is used to estimate mineral specific surface area and nanocrystal thickness for intact bone.

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“…Since CP relies on heteronuclear dipolar couplings between the source and target spins, its efficiency is uniquely dependent on the concentration, distribution and mobility of the nuclei involved. In particular, CP has been widely used to obtain insights about the composition of different calcium phosphate salts and thus distinguish them—for instance, bone apatites from synthetic ones [24,25], or ACP salts from crystalline ones [26]—based on the different percentages of water molecules and hydroxyl groups that characterize each particular calcium phosphate type. In the particular case of crystalline apatites and amorphous calcium phosphate salts, CP efficiency is typically linear for contact times longer than 8 ms in the former case, whereas it reaches a maximum earlier in the latter because there are fewer apatite-structural-hydroxyl groups than water molecules occupying the interstices among the ACP clusters [26].…”

Section: Resultsmentioning

confidence: 99%

Macroporous Calcium Phosphate/Chitosan Composites Prepared via Unidirectional Ice Segregation and Subsequent Freeze-Drying

et al. 2017

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Calcium phosphate chitosan-based composites have gained much interest in recent years for biomedical purposes. In this paper, three-dimensional calcium phosphate chitosan-based composites with different mineral contents were produced using a green method called ice segregation induced self-assembly (ISISA). In this methodology, ice crystals were used as a template to produce porous structures from an aqueous solution of chitosan (CS) and hydroxyapatite (Hap) also containing acetic acid (pH = 4.5). For better characterization of the nature of the inorganic matter entrapped within the resulting composite, we performed either oxygen plasma or calcination processes to remove the organic matter. The nature of the phosphate salts was studied by XRD and NMR studies. Amorphous calcium phosphate (ACP) was identified as the mineral phase in the composites submitted to oxygen plasma, whereas crystalline Hap was obtained after calcination. SEM microscopy revealed the formation of porous structures (porosity around 80–85%) in the original composites, as well as in the inorganic matrices obtained after calcination, with porous channels of up to 50 µm in diameter in the former case and of up to 20 µm in the latter. The biocompatibility of the composites was assessed using two different cell lines: C2C12GFP premyoblastic cells and MC3T3 preosteoblastic cells.

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Kinetics of ¹H → ³¹P NMR cross‐polarization in bone apatite and its mineral standards

Cited by 38 publications

References 43 publications

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

Analyses of mineral specific surface area and hydroxyl substitution for intact bone

Macroporous Calcium Phosphate/Chitosan Composites Prepared via Unidirectional Ice Segregation and Subsequent Freeze-Drying

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Kinetics of 1H → 31P NMR cross‐polarization in bone apatite and its mineral standards

Cited by 38 publications

References 43 publications

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

NMR Techniques in Metabolomic Studies: A Quick Overview on Examples of Utilization

Analyses of mineral specific surface area and hydroxyl substitution for intact bone

Macroporous Calcium Phosphate/Chitosan Composites Prepared via Unidirectional Ice Segregation and Subsequent Freeze-Drying

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Product

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Kinetics of ¹H → ³¹P NMR cross‐polarization in bone apatite and its mineral standards