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    Korte, M. Influence of aquatitan tape in nerve cells of the central nervous system. J. Clin. Biochem. Nutr. 2008, 43 Suppl 1, 44–47.

被如下文章引用:

  • TITLE: The Effects of Uniquely-Processed Titanium on Biological Systems: Implications for Human Health and Performance
  • AUTHORS: David S. Rowlands,Sarah P. Shultz,Takahiro Ogawa,Wataru Aoi,Martin Korte
  • KEYWORDS: Aqua Titan, action potential, long-term potentiation, tendon compliance, musculotendinous function, cell adhesion and growth, autonomic nervous system, pico-nanometer scale
  • JOURNAL NAME: Journal of Functional Biomaterials DOI: 10.3390/jfb5010001 Sep 07, 2014
  • ABSTRACT: Titanium is biocompatible and widely utilized in a variety of applications. Recently, titanium in pico-nanometer scale and soluble form (Aqua Titan) has expanded its use to applied human health and performance. The purpose of this article is to review the current evidence associated with specific physiological responses to Aqua Titan-treated materials. In vitro studies have shown that application of Aqua Titan can modify membrane potential and long-term potentiation in isolated hippocampal neurons, suggesting reduced pain memory as a possible mechanism for reported analgesia. Proximal contact with Aqua Titan-treated titanium increased gene expression, protein synthesis, cell growth and adhesion in normal cultured muscle and bone cells, suggesting application for Aqua Titan in clinical implant procedures and wound healing. Evidence for beneficial effects on neuromuscular control of muscle-tendon function and improvements in running economy in human athletes was seen when Aqua Titan-treated tape was applied to the human triceps surae following fatigue induced by prior strenuous exercise. Finally, behavioral responses and effects on the autonomic nervous system to environmental exposure suggest Aqua Titan may promote a mild relaxant, or stress-suppressive response. Together, data suggest exposure to Aqua Titan-treated materials modulates aspects of growth and function in neuronal and other musculoskeletal cells with possible benefits to musculotendinous recovery from exercise and to the systemic response to stress.