Nano/submicron-scale TiO2 network on titanium surface for dental implant application

Yang, Wei; Hsu, Ming Lun; Lin, Mau Chin; Chen, Zhi Hwa; Chen, Li Kai; Huang, Her Hsiung

doi:10.1016/j.jallcom.2009.01.021

Cited by 61 publications

(33 citation statements)

References 28 publications

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“…Radiological and histological examinations confirmed that the new bony tissue had grown easily into the entire n-HPC scaffold fabricated by LMP. We suggest that the well-interconnected pores in the LMP scaffolds might encourage cell attachment, proliferation, and migration to stimulate cell functions, thus enhancing bone formation in the LMP scaffolds [132].…”

Section: Stem Cell Nanotechnology For Tissue Engineering Scaffoldsmentioning

confidence: 91%

Advances of Nanotechnology in the Stem Cells Research and Development

Ji¹,

Ruan²,

Cui³

2010

Nano BioMed ENG

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In decades, stem cell nanotechnology has become a new promising field for stem cell research and development. So, stem cell nanotechnology has attracted lots of researchers' attention and made great progress. The unique properties of nanomaterials and nanostructures which applied in the fundamental research of stem cell-based therapies have been recognized. Nanomaterials and nanotechnology have been highlighted as promising candidates for efficient control over proliferation and differentiation of stem cells, revolutionizing the treatment of neurodegenerative disorders, neuroprotection in traumatic brain injury, improving the osteospecific differentiation and function, tissue engineering scaffold, dental implant application, drug delivery, gene therapy and cell imaging or tracking. Here we summarize the main progress in this field, explore the application prospects in injuries, diseases, regenerative medicine, etc. and discuss the methods and challenges with the aim of improving application of nanotechnology in the stem cell research and development.

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Section: Stem Cell Nanotechnology For Tissue Engineering Scaffoldsmentioning

confidence: 91%

Advances of Nanotechnology in the Stem Cells Research and Development

Ji¹,

Ruan²,

Cui³

2010

Nano BioMed ENG

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“…They are used in cosmetics, textiles, bioimaging, medicine and diagno sis [1][2][3][4][5][6][7][8]. The widespread applications of NMs increase their chances of entering the human body via a number of pathways, such as the respi ratory system [9], skin absorption [10,11], intra venous injection [12] and implantation [13]. As a result, there is an urgent need to understand the potential physiological and patho logical reac tions after exposure to NMs [14,15].…”

Section: Reviewmentioning

confidence: 99%

Advances in The Understanding of Nanomaterial–Biomembrane Interactions and Their Mathematical and Numerical Modeling

Lin

et al. 2013

Nanomedicine

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The widespread application of nanomaterials (NMs), which has accompanied advances in nanotechnology, has increased their chances of entering an organism, for example, via the respiratory system, skin absorption or intravenous injection. Although accumulating experimental evidence has indicated the important role of NM–biomembrane interaction in these processes, the underlying mechanisms remain unclear. Computational techniques, as an alternative to experimental efforts, are effective tools to simulate complicated biological behaviors. Computer simulations can investigate NM–biomembrane interactions at the nanoscale, providing fundamental insights into dynamic processes that are challenging to experimental observation. This paper reviews the current understanding of NM–biomembrane interactions, and existing mathematical and numerical modeling methods. We highlight the advantages and limitations of each method, and also discuss the future perspectives in this field. Better understanding of NM–biomembrane interactions can benefit various fields, including nanomedicine and diagnosis.

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“…Yang et al (Yang et al, 2009) produced through the electrochemical anodizing treatment a mixed nano/submicron-scale TiO2 network layer (lateral pore size: 20-160 nm) on polished Ti surface. Results showed that a nano/submicron-scale TiO2 network layer with a lateral pore size of 20-160nm could be rapidly produced on Ti surface through electrochemical anodizing treatment.…”

Section: Nanoroughnessmentioning

confidence: 99%

Factors Affecting the Success of Dental Implants

Elias¹

2011

Implant Dentistry - A Rapidly Evolving Practice

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Nano/submicron-scale TiO2 network on titanium surface for dental implant application

Cited by 61 publications

References 28 publications

Advances of Nanotechnology in the Stem Cells Research and Development

Advances of Nanotechnology in the Stem Cells Research and Development

Advances in The Understanding of Nanomaterial–Biomembrane Interactions and Their Mathematical and Numerical Modeling

Factors Affecting the Success of Dental Implants

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