Andrei P Sommer, Uri Oron, Anne-Marié Pretorius, David S McKay, Neva Ciftcioglu, Adam R Mester, E Olavi Kajander, Harry T Whelan
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引用次数: 16
Abstract
Objective: The purpose of this preliminary study is to evaluate the effect of various wavelengths of light on nanobacteria (NB).
Background data: NB and mitochondria use light for biological processes. NB have been described as multifunctional primordial nanovesicles with the potential to utilize solar energy for replication. NB produce slime, a process common to living bacteria. Slime release is an evolutionary important stress-dependent phenomenon increasing the survival chance of individual bacteria in a colony. In the cardiovascular system, stress-induced bacterial colony formation may lead to a deposition of plaque.
Methods: Cultured NB were irradiated with NASA-LEDs at different wavelengths of light: 670, 728 and 880 nm. Light intensities were about 500k Wm(-2), and energy density was 1 x 10(4) J m(-2).
Results: Monochromatic light clearly affected replication of NB. Maximum replication was achieved at 670 nm.
Conclusions: The results indicate that suitable wavelengths of light could be instrumental in elevating the vitality level of NB, preventing the production of NB-mediated slime, and simultaneously increasing the vitality level of mitochondria. The finding could stimulate the design of cooperative therapy concepts that could reduce death caused by myocardial infarcts.
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