Product: Diamond Nanoparticles (C, Purity: 75.65 %, APS: 2-5nm)
Quality Control: Each lot of NANOSHEL Diamond Nanoparticles was tested successfully.
|APS||2-5nm (95.2 %), 5.1-10nm (4.1 %), 10.1-20nm (0.7 %)|
|Molecular Weight||12.01 g/mol||Confirm|
|Melting Point||3727 °C||Confirm|
|True Density||3.05-3.3 g/cm³||Confirm|
|Bulk Density||0.16-0.18 g/cm³||Confirm|
|BET Specific Surface Area||200-450 m²/g||Confirm|
|Available Quantities||25Gms, 50Gms, 100Gms and larger quantities|
|Main Inspect Verifier||Manager QC|
Typical Chemical Analysis
|Diamond (C)||75.65 %|
Jules L. Routbort (Argonne National Laboratory, Argonne, USA)
Diamond Nanoparticles use of diamond in a variety of medical applications, including drug delivery devices, microelectromechanical devices, and cardiovascular devices. Diamond-based materials and devices must be overcome. Reproducible, scalable processes must be developed to facilitate the translation of diamond coatings to clinical use. The short-term toxicity, long-term toxicity, and fate of diamond, impurities, and breakdown products must be carefully considered using medical application-specific parameters26 and 77. The properties of diamond for particular medical applications. Diamond-based materials and devices may be translated to use in medical devices, drug delivery, and medical diagnostic applications over the next few decades.
Dr. Ms. Kamiko Chang, Ph.D(University of Science and Technology Beijing, China)
Diamond Nanoparticles coatings have been applied to a number of medical devices in recent years, including temporomandibular joint prostheses, heart valves, and microelectromechanical systems, for the purpose of extending implant lifetime. Diamond may find use in microscale devices for sensing and/or drug delivery, which are known as biomedical microelectromechanical systems (bioMEMS). Conventional micro electromechanical systems are commonly fabricated using silicon; however, silicon demonstrates undesirable mechanical and tribological properties, including poor brittle fracture strength and a tendency to adhere to surfaces (stiction).
Dr. Nicholaos G. Demas (Newcastle University School Of Machanical & Systems Engg. UK)
Diamond Nanoparticles Surface-modified diamond nanoparticles can be used as highly effective antigen delivery carriers, which suggests that modified nanodiamonds have immense potential to be utilized as an alternative to traditional catalysts. Studies have shown that small photoluminescent diamond nanoparticles that remain free in the cytosol are excellent contenders for the transport of biomolecule. The interaction of the catalyst with the ND surface was also found to be an important factor in the investigated iron oxide ND and nickel-modified ND in the catalysis of methanol decomposition. In general, ND-based catalytic materials exhibited better activity, with a direct correlation between the rate of methanol decomposition and the amount of ND incorporated in the catalyst.
Takeo Oku (Department of Materials Science, The University of Shiga Prefecture, Hassaka 2500, Hikone, Shiga 522-8533, Japan)
Diamond Nanoparticles, also known as nanodiamonds, are single crystal diamonds that range anywhere from 5 to 500 nm. Because of their inexpensive, large-scale synthesis, potential for surface functionalization, and high biocompatibility, nanodiamonds are widely investigated as a potential material in biological and electronic applications and quantum engineering. Diamond nanoparticles have the potential to be utilized in a myriad of biological applications and due to their unique properties such as inertness and hardness, nanodiamonds may prove to be a better alternative to the traditional nanomaterials currently utilized to carry drugs, coat implantable materials, and synthesize biosensors and biomedical robots. The low cytotoxicity of diamond nanoparticles affirms their utilization as biologically compatible materials.
Dr. Ms. Guixin (Susan), Ph.D (Switzerland-Institute for Inorganic Chemistry, Zurich, Switzerland)
Diamond Nanoparticles -based nucleic acid sensors have recently been developed. described fabrication of diamond nanowires through use of an electrochemical phenyl-linker molecule attachment and functionalized thiol-modified DNA. Sensitivity to hybridization of complementary DNA sequences with a concentration of 2 pM over a 3 mm2 sensor area was demonstrated. No degradation in DNA bonding was noted over thirty hybridization/denaturation cycles. Diamond is the hardest known material. The industrial production of nano-scaled diamonds takes place at high temperatures and under high pressure. Applications of diamond Nanoparticles include their use as filling components in synthetic materials and in the production of polishes.
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