فهرس المقالات Hardystonite

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  1 - Survey and Evaluation of Hardystonite Nanostructure (HTN) Bioactivity in Biomedical Engineering
  hassan GHEISARI
  10.22034/jna.2022.1955260.1297
  Hardystonite (HT) is a monoclinic pyroxene mineral with composition Ca2ZnSi2O7. Lately, Hardystonite (HT) has been introduced as a bioceramics due to its best bioactivity and biocompatibility. It has a good strength and toughness than those of hydroxyapatite (HA). In th أکثر

  Hardystonite (HT) is a monoclinic pyroxene mineral with composition Ca2ZnSi2O7. Lately, Hardystonite (HT) has been introduced as a bioceramics due to its best bioactivity and biocompatibility. It has a good strength and toughness than those of hydroxyapatite (HA). In this project, bioactivity of hardystonite (HT) powder were evaluated and investigated. For synthesized of hardystonite (HT) powder, Zinc (Zn), calcite (CaCO3) and nano silicium (SiO2) powders was mechanically activate for different times. After that, the prepared powders were blended with ammonium chloride (NH4Cl) and put on various temperatures. In this part, for survey of bioactivity evaluation, the obtained hardystonite (HT) powders were pressed and immersed in Kukobo solution (SBF)The results indicated that nano-struacture hadystonite powder with crystalline size is 40 nm. The apatite formation ability,bioactivity and good mechanical behavior make it a good candidate in bone implant materials and open new insights in biomedical engineering. The apatite formation ability,bioactivity and good mechanical behavior make it a good candidate in bone implant materials and open new insights in biomedical engineering. تفاصيل المقالة
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  2 - In Vitro Behavior of a Novel Nanostructure Hardystonite/Biphasic Calcium Phosphate Scaffolds (HT/BCPS); Evaluation and Investigation
  hassan gheisari
  10.22034/jna.2020.582966.1129
  An important compete in bone tissue engineering is the development of constructs serving as scaffolds to fill bone defects, and promote bone regeneration. In this study, highly porous almost (75%) nanostructured Hardystonite/biphasic calcium phosphate scaffolds (BCPS) w أکثر

  An important compete in bone tissue engineering is the development of constructs serving as scaffolds to fill bone defects, and promote bone regeneration. In this study, highly porous almost (75%) nanostructured Hardystonite/biphasic calcium phosphate scaffolds (BCPS) with interconnected porosity was developed using various hardystonite (HT) contents via space holder technique. Transmission electron microscopy (TEM), X ray diffraction (XRD) and scanning electron microscopy (SEM) techniques was employed to evaluate different samples. In addition to, the agents of scaffold composition on mechanical behavior , bioactivity and biodegradability was studied. Also, the results showed that the produced scaffolds had an average pore size and density between 250-350 µm and 2.2 ± 0.4 - 1.7 ± 0.2 gr/cm3, respectively, depending on the Hardystonite (HT) with different contents. Furthermore, increasing the hardystonite content of scaffolds from 0 (control) to 30 wt. % enhanced the bioactivity test, biodegradability, and compressive strength from 1.1 ± 0.1 to 3.1 ± 0.2 MPa, respectively. Besides, MTT assay also confirmed that the BCPS30 (containing 30 wt. % of hardystonite) significantly promoted cell viability and cell adhesion compared to BCPS 0. Totally, our project suggests that nanostructured hardystonite/BCPS with improved biological and mechanical behavior (properties) could potentially be used for biomedical engineering such as bone tissue engineering application. تفاصيل المقالة
• حرية الوصول المقاله
  • صفحة الملخص
  • نص كامل
  
  3 - In Vitro Behavior of a Novel Nanostructure Hardystonite/Biphasic Calcium Phosphate Scaffolds (HT/BCPS); Evaluation and Investigation
  Hassan Gheisari
  10.22034/jna.2021.685449
  In this study, highly porous almost (75%) nanostructured Hardystonite/biphasic calcium phosphate scaffolds (BCPS) with interconnected porosity were developed using various hardystonite (HT) contents via space holder technique. Transmission electron microscopy (TEM), X-r أکثر

  In this study, highly porous almost (75%) nanostructured Hardystonite/biphasic calcium phosphate scaffolds (BCPS) with interconnected porosity were developed using various hardystonite (HT) contents via space holder technique. Transmission electron microscopy (TEM), X-ray diffraction (XRD), and scanning electron microscopy (SEM) techniques were employed to evaluate different samples. Inaddition, the agents of scaffold composition of mechanical behavior, bioactivity, and biodegradability were studied. Also, the results showed that the produced scaffolds had an average pore size and density between 250-350 μm and 2.2 ± 0.4 - 1.7 ± 0.2 gr/cm3, respectively, depending on the Hardystonite (HT) with different contents. Furthermore, increasing the hardystonite content of scaffolds from 0 (control) to 30 wt. % enhanced the bioactivity test, biodegradability, and compressive strength from 1.1 ± 0.1 to 3.1 ± 0.2 MPa, respectively. Besides, MTT assay also confirmed that the BCPS30 (containing 30 wt. % of hardystonite) significantly promoted cell viability and cell adhesion compared to BCPS 0. Totally, our project suggests that nanostructured hardystonite/BCPS with improved biological and mechanical behavior (properties) could potentially be used for biomedical engineering such as bone tissue engineering applications. تفاصيل المقالة