Research References

Microbubbles, Nanobubbles

Tsuge, H. Micro- and Nanobubbles: Fundamentals and Applications. (Pan Stanford Publishing, 2014).
Ebina, K. et al. Oxygen and air nanobubble water solution promote the growth of plants, fishes, and mice. PloS one 8, e65339 (2013).
Agarwal, A., Ng, W. J. & Liu, Y. Principle and applications of microbubble and nanobubble technology for water treatment. Chemosphere 84, 1175-1180 (2011).
Yang, S. & Duisterwinkel, A. Removal of nanoparticles from plain and patterned surfaces using nanobubbles. Langmuir 27, 11430-11435 (2011).
Wen, D. Intracellular hyperthermia: Nanobubbles and their biomedical applications. International Journal of Hypothermia 25, 533-541 (2009).
Bunkin, N. F., Yurchenko, S. O., Suyazov, N. V. & Shkirin, A. V. Structure of the nanobubble clusters of dissolved air in liquid media. Journal of biological physics 38, 121-152 (2012).
Craig, V. S. J. Very small bubbles at surfaces—the nanobubble puzzle. Soft Matter 7, 40- 48 (2011).
Ohgaki, K., Khanh, N. Q., Joden, Y., Tsuji, A. & Nakagawa, T. Physicochemical approach to nanobubble solutions. Chem Eng Sci 65, 1296-1300 (2010).
Häbich, A., Ducker, W., Dunstan, D. E. & Zhang, X. Do stable nanobubbles exist in mixtures of organic solvents and water? The Journal of Physical Chemistry B 114, 6962- 6967 (2010).
Chaplin, M. Water Structure and Science: Nanobubbles. (2015).
Kikuchi, K. et al. Concentration determination of oxygen nanobubbles in electrolyzed water. Journal of colloid and interface science 329, 306-309 (2009).
Seddon, J. R., Lohse, D., Ducker, W. A. & Craig, V. S. A deliberation on nanobubbles at surfaces and in bulk. ChemPhysChem 13, 2179-2187 (2012).
Attard, P., Moody, M. P. & Tyrrell, J. W. Nanobubbles: the big picture. Physica A: Statistical Mechanics and its Applications 314, 696-705 (2002).
Brenner, M. P. & Lohse, D. Dynamic equilibrium mechanism for surface nanobubble stabilization. Physical review letters 101, 214505 (2008).
Xue-Hua, Z., Gang, L., Zhi-Hua, W., Xiao-Dong, Z. & Jun, H. Effect of temperature on the morphology of nanobubbles at mica/water interface. Chinese Physics 14, 1774 (2005).
Petsev, N. D., Shell, M. S. & Leal, L. G. Dynamic equilibrium explanation for nanobubbles' unusual temperature and saturation dependence. Physical Review E 88, 010402 (2013).
Attard, P. The stability of nanobubbles. The European Physical Journal Special Topics, 1-22.
Seddon, J. R., Zandvliet, H. J. & Lohse, D. Knudsen gas provides nanobubble stability. Physical review letters 107, 116101 (2011).
PANDEY, P. K., JAIN, A. & DIXIT, S. Micro and nanobubble water. Int. J. Eng. Sci. Technol 4, 4734-4738 (2012).
Li, D., Jing, D., Pan, Y., Wang, W. & Zhao, X. Coalescence and Stability Analysis of Surface Nanobubbles on the Polystyrene/Water Interface. Langmuir 30, 6079-6088 (2014).
Matsuki, N. et al. Oxygen supersaturated fluid using fine micro/nanobubbles. International journal of nanomedicine 9, 4495 (2014).
Li, P. & Tsuge, H. Water treatment by induced air flotation using microbubbles. Journal of chemical engineering of Japan 39, 896-903 (2006).
Oliveira, C., Rodrigues, R. & Rubio, J. A new technique for characterizing aerated flocs in a flocculation–microbubble flotation system. International Journal of Mineral
Chu, L.-B. et al. Enhanced ozonation of simulated dyestuff wastewater by microbubbles. Chemo-sphere 68, 1854-1860 (2007).
Onari, H. Development and current issues in microbubble technology. Clean Technol 17,1-5 (2007).
Chu, L.-B., Xing, X.-H., Yu, A.-F., Sun, X.-L. & Jurcik, B. Enhanced treatment of practical textile wastewater by microbubble ozonation. Process Safety and Environmental Protection 86, 389-393 (2008).
Miyamoto, M. et al. Degreasing of solid surfaces by microbubble cleaning. Japanese journal of applied physics 46, 1236 (2007).
Barak, M. & Katz, Y. Microbubbles: pathophysiology and clinical implications. CHEST Journal 128, 2918-2932 (2005).
Unger, E. C. et al. Therapeutic applications of microbubbles. European journal of radiology 42, 160-168 (2002).
Ferrante, A. & Elghobashi, S. Reynolds number effect on drag reduction in a microbubble-laden spatially developing turbulent boundary layer. Journal of Fluid Mechanics 543, 93-106 (2005).
Madavan, N., Merkle, C. & Deutsch, S. Numerical investigations into the mechanisms of microbubble drag reduction. Journal of Fluids Engineering 107, 370-377 (1985).
BURNS, P. N., WILSON, S. R. & SIMPSON, D. H. Pulse inversion imaging of liver blood flow: improved method for characterizing focal masses with microbubble contrast. Investigative radiology 35, 58 (2000).
Hohmann, J., Albrecht, T., Hoffmann, C. & Wolf, K.-J. Ultrasonographic detection of focal liver lesions: increased sensitivity and specificity with microbubble contrast agents. European journal of radiology 46, 147-159 (2003).
Blomley, M. J., Cooke, J. C., Unger, E. C., Monaghan, M. J. & Cosgrove, D. O. Science, medicine, and the future: Microbubble contrast agents: a new era in ultrasound. BMJ: British Medical Journal 322, 1222 (2001).
Hettiarachchi, K., Talu, E., Longo, M. L., Dayton, P. A. & Lee, A. P. On-chip generation
of microbubbles as a practical technology for manufacturing contrast agents for ultrasonic imaging. Lab Chip 7, 463-468 (2007).
Zimmerman, W. B. Microbubbles Keep Green Energy Blooming. advantage, 44 (2011).
Luttrell, G., Weber, A., Adel, G. & Yoon, R. Microbubble flotation of fine coal. Column Flotation 88, 205-211 (1988).
Himuro, S. D., T. et. al. Effects of Microbubbles on Bacteria. Progress in Multiphase Flow Research 4, 95-102 (2009).
Choi, Y. J., Park, J. Y., Kim, Y. J. & Nam, K. Flow characteristics of microbubble suspensions in porous media as an oxygen carrier. Clean–Soil, Air, Water 36, 59-65 (2008).
LYU, Y., LIU, C. & WU, K.-h. Characteristics of microbubble's shrinkage in microbubble aeration. Hebei Journal of Industrial Science and Technology 6, 001 (2012).
Turner, W. Microbubble persistence in fresh water. The Journal of the Acoustical Society of America 33, 1223-1233 (1961).
Chaplin, M. F. The memory of water: an overview. Homeopathy 96, 143-150 (2007).
O'Brian, J.-P. Improved Characterisation and Modelling of Microbubbles in Biomedical Applications PhD thesis, University College, (2013).
Li, P., Takahashi, M. & Chiba, K. Degradation of phenol by the collapse of microbubbles. Chemosphere 75, 1371-1375 (2009).

Skin Heath , Metabolism, Wounds & Burns

Basra, M. K. & Shahrukh, M. Burden of skin diseases. (2009).
Bickers, D. R. et al. The burden of skin diseases: 2004: A joint project of the American Academy of Dermatology Association and the Society for Investigative Dermatology. Journal of the American Academy of Dermatology 55, 490-500 (2006).
Markova, A. & Mostow, E. N. US skin disease assessment: ulcer and wound care. Dermatologic clinics 30, 107-111 (2012).
Hess, C. T. Skin and Wound Care. (Lippincott Williams & Wilkins, 2008). Liedberg, N. C.-F., Reiss, E. & Artz, C. P. The effect of bacteria on the take of split thickness skin grafts in rabbits. Annals of Surgery 142, 92 (1955).
Association, A. B. Burn incidence and treatment in the US: 2000 fact sheet. Chicago: ABA (2000).
Brigham, P. A. & McLoughlin, E. Burn incidence and medical care use in the United States: estimates, trends, and data sources. Journal of Burn Care & Research 17, 95-107(1996).
Monafo, W. W. Initial management of burns. New England Journal of Medicine 335,1581-1586 (1996).
Munster, A., Smith-Meek, M. & Sharkey, P. The effect of early surgical intervention on mortality and cost-effectiveness in burn care, 1978-91. Burns 20, 61-64 (1994).
Herndon, D. N. Total burn care. 4th edn, (Saunders Elsevier, 2012).
Hur, J. et al. Inflammatory Cytokines and Their Prognostic Ability in Cases of Major Burn Injury. Annals of laboratory medicine 35, 105-110 (2015).
Subrahmanyam, M. A prospective randomized clinical and histological study of superficial burn wound healing with honey and silver sulfadiazine. Burns 24, 157-161 (1998).
Queen, D., Evans, J., Gaylor, J., Courtney, J. & Reid, W. Burn wound dressings—a review. Burns 13, 218-228 (1987).
Eming, S. A., Krieg, T. & Davidson, J. M. Inflammation in wound repair: molecular and cellular mechanisms. Journal of Investigative Dermatology 127, 514-525 (2007).
Leaper, D. J. & Harding, K. G. Wounds: biology and management. (Oxford University Press, USA, 1998).
Epstein, F. H., Singer, A. J. & Clark, R. A. Cutaneous wound healing. New England Journal of Medicine 341, 738-746 (1999).
Widgerow, A. D. Cellular resolution of inflammation—catabasis. Wound Repair and Regeneration 20, 2-7 (2012).
Wolcott, R., Kennedy, J. & Dowd, S. Regular debridement is the main tool for maintaining a healthy wound bed in most chronic. J Wound Care 18, 54 (2009).
Schultz, G., Phillips, P., Yang, Q. & Stewart, P. Biofilm maturity studies indicate sharp debridement opens a time-dependent therapeutic window. Journal of wound care 19, 320 (2010).
Trengove, N. Bacteriology of wounds. Current Therapeutics 41, 33 (2000).
Siddiqui, A. R. & Bernstein, J. M. Chronic wound infection: facts and controversies. Clinics in dermatology 28, 519-526 (2010).
Edwards, R. & Harding, K. G. Bacteria and wound healing. Current opinion in infectious diseases 17, 91-96 (2004).
Wolcott, R. D., Rhoads, D. D. & Dowd, S. E. Biofilms and chronic wound inflammation.
J Wound Care 17, 333-341 (2008).
Roy, S. et al. Mixed‐ species biofilm compromises wound healing by disrupting epidermal barrier function. The Journal of pathology 233, 331-343 (2014)
James, G. A. et al. Biofilms in chronic wounds. Wound Repair and Regeneration 16, 37-44 (2008).
Davis, S. C. et al. Microscopic and physiologic evidence for biofilm-associated wound colonization in vivo. Wound Repair and Regeneration 16, 23-29 (2008).
Luedtke-Hoffmann, K. A. & Schafer, D. S. Pulsed lavage in wound cleansing. Physical Therapy 80, 292-300 (2000).
Sussman, C. & Bates-Jensen, B. M. Wound care: a collaborative practice manual for physical therapists and nurses. (Aspen Publishers Gaithersburg, MD, 1998).
Subrahmanyam, M. A prospective randomized clinical and histological study of superficial burn wound healing with honey and silver sulfadiazine. Burns 24, 157-161(1998).
Helfman, T., Ovington, L. & Falanga, V. Occlusive dressings and wound healing. Clinicsin dermatology 12, 121-127 (1994).
Bolton, L., Monte, K. & Pirone, L. Moisture and healing: beyond the jargon.Ostomy/wound management 46, 51S-62S; quiz 63S-64S (2000).
Bowler, P., Jones, S., Davies, B. & Coyle, E. Infection control properties of some wound dressings. Journal of wound care 8, 499-502 (1999).
Queen, D., Evans, J., Gaylor, J., Courtney, J. & Reid, W. Burn wound dressings—a review. Burns 13, 218-228 (1987).
Armstrong, D. G. & Lavery, L. A. Negative pressure wound therapy after partial diabetic foot amputation: a multicentre, randomized controlled trial. Lancet 366, 1704 (2005).
Thompson, J. T. & Marks, M. W. Negative pressure wound therapy. Clinics in plastic surgery 34, 673-684 (2007).
Gregor, S. et al. Negative pressure wound therapy: a vacuum of evidence? Archives of Surgery 143, 189 (2008).
Gasbarro, R. Negative pressure wound therapy: a clinical review. Wounds 19 (2007).
Jerome, D. Advances in negative pressure wound therapy: the VAC instill. Journal of Wound Ostomy & Continence Nursing 34, 191-194 (2007).
Fries, R. B. et al. Dermal excisional wound healing in pigs following treatment with topically applied pure oxygen. Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis 579, 172-181 (2005).
Banin, E., Brady, K. M. & Greenberg, E. P. Chelator-induced dispersal and killing of Pseudomonas aeruginosa cells in a biofilm. Applied and environmental microbiology 72, 2064-2069 (2006).
Burmølle, M., Ren, D., Bjarnsholt, T. & Sørensen, S. J. Interactions in multispecies biofilms: do they actually matter? Trends in microbiology 22, 84-91 (2014).
Römling, U. & Balsalobre, C. Biofilm infections, their resilience to therapy and innovative treatment strategies. Journal of internal medicine 272, 541-561 (2012).
Macià, M. D., Rojo‐ Molinero, E. & Oliver, A. Antimicrobial susceptibility testing in biofilm‐ growing bacteria. Clinical Microbiology and Infection 20, 981-990 (2014).
Grumbein, S., Opitz, M. & Lieleg, O. Selected metal ions protect Bacillus subtilis biofilms from erosion. Metallomics 6, 1441-1450 (2014).
Gorur, A., Lyle, D. M., Schaudinn, C. & Costerton, J. W. Biofilm removal with a dental water jet. Compendium of continuing education in dentistry (Jamesburg, NJ: 1995) 30, 1- 6 (2009).
Banin, E., Brady, K. M. & Greenberg, E. P. Chelator-induced dispersal and killing ofPseudomonas aeruginosa cells in a biofilm. Applied and environmental microbiology 72, 2064-2069 (2006).

Oxygen

Schreml, S. et al. Oxygen in acute and chronic wound healing. British Journal of Dermatology 163, 257-268 (2010).
Sharp, G. & Secombes, C. The role of reactive oxygen species in the killing of the bacterial fish pathogen Aeromonas salmonicida by rainbow trout macrophages. Fish & Shellfish Immunology 3, 119-129 (1993).
Dauphinee, D. M. Hyperbaric Oxygen vs Topical Oxygen: why are we still comparing the two? Podiatric Medical Association Texas (2013).
Stephens, F. O. & Hunt, T. K. Effect of changes in inspired oxygen and carbon dioxide tensions on wound tensile strength: an experimental study. Annals of Surgery 173, 515 (1971).
Ebina, K. et al. Oxygen and air nanobubble water solution promote the growth of plants, fishes, and mice. PloS one 8, e65339 (2013).
Kawashima, M. et al. [abstract] Irrigation therapy using ozone nanobubble water in conjunction with hyperbaric oxygen therapy. (2011).
Choi, Y. J., Park, J. Y., Kim, Y. J. & Nam, K. Flow characteristics of microbubble suspensions in porous media as an oxygen carrier. Clean–Soil, Air, Water 36, 59-65 (2008).
Kikuchi, K. et al. Concentration determination of oxygen nanobubbles in electrolyzed water. Journal of colloid and interface science 329, 306-309 (2009).
Glazer, B. T., Marsh, A. G., Stierhoff, K. & Luther, G. W. The dynamic response of optical oxygen sensors and voltammetric electrodes to temporal changes in dissolved oxygen concentrations. Analytica Chimica Acta 518, 93-100 (2004).
Montgomery, H., Thom, N. & Cockburn, A. Determination of dissolved oxygen by the Winkler method and the solubility of oxygen in pure water and sea water. Journal of Applied Chemistry 14, 280-296 (1964).
Culberson, C. H., Knapp, G. P., Stalcup, M. C., Williams, R. T. & Zemlyak, F. A comparison of methods for the determination of dissolved oxygen in seawater. (1991).
Knapp, G. P., Stalcup, M. C. & Stanley, R. J. Dissolved oxygen measurements in seawater at the Woods Hole Oceanographic Institution. (Woods Hole Oceanographic Institution, 1989).
Truesdale, G. & Downing, A. Solubility of oxygen in water. (1954).
Tromans, D. Temperature and pressure dependent solubility of oxygen in water: a thermodynamic analysis. Hydrometallurgy 48, 327-342 (1998).
U.S. Geological Survey, Change to solubility equations for oxygen in water: Office of Water Quality Technical Memorandum 2011.03. (2011).
Garcia, H. E. & Gordon, L. I. Oxygen solubility in seawater: Better fitting equations. Limnology and oceanography 37, 1307-1312 (1992).
Carpenter, J. H. THE ACCURACY OF THE WINKLER METHOD FOR DISSOLVED OXYGEN ANALYSIS1. Limnology and oceanography 10, 135-140 (1965).
The Dissolved Oxygen Handbook - YSI, inc.
Kanwisher, J. Polarographic Oxygen Electrode. Limnology and oceanography 4, 210-217 (1959).
Clark, L. C., Wolf, R., Granger, D. & Taylor, Z. Continuous recording of blood oxygen tensions by polarography. Journal of applied physiology 6, 189-193 (1953).
Horwitz, O., Sayen, J., Sheldon, W. & Kuo, P. Experimental studies of intramyocardial oxygen tension: increases consequent on breathing pure oxygen in normal hearts and at the borders of ischaemic areas. The Journal of clinical investigation 29, 823 (1950).
Tobias, J. M. & Retondo, N. Syringe oxygen cathode for measurement of oxygen tension in solution and in respiratory gases. Review of Scientific Instruments 20, 519-523 (1949).
Edzwald, J. K., Walsh, J. P., Kaminski, G. S. & Dunn, H. J. Flocculation and air requirements for dissolved air flotation. Journal (American Water Works Association), 92-100 (1992).

Oxygen

Ozone

Hayakumo, S. et al. Effects of ozone nano-bubble water on periodontopathic bacteria and oral cells in -vitro studies. Science and Technology of Advanced Materials 15, 055003 (2014).
Inatsu, Y. et al. Effectiveness of stable ozone microbubble water on reducing bacteria on .the surface of selected leafy vegetables. Food Science and Technology Research 17, 479-485 (2011)
Hayakumo, S., Arakawa, S., Mano, Y. & Izumi, Y. Clinical and microbiological effects of ozone nano-bubble water irrigation as an adjunct to mechanical subgingival debridement in periodontitis patients in a randomized controlled trial. Clinical oral investigations 17, 379-388 (2013).
Roth, J. A. & Sullivan, D. E. Solubility of ozone in water. Industrial & Engineering Chemistry Fundamentals 20, 137-140 (1981).
Buchan, K. A., Martin-Robichaud, D. J. & Benfey, T. J. Measurement of dissolved ozone in seawater: a comparison of methods. Aquacultural Engineering 33, 225-231 (2005).
Berdichevsky, Y., Khandurina, J., Guttman, A. & Lo, Y.-H. UV/ozone modification of poly (dimethylsiloxane) microfluidic channels. Sensors and Actuators B: Chemical 97, 402-408 (2004).
Kawashima, M. et al. [abstract] Irrigation therapy using ozone nanobubble water in conjunction with hyperbaric oxygen therapy. (2011).
Takahashi, M., Chiba, K. & Li, P. Formation of hydroxyl radicals by collapsing ozone microbubbles under strongly acidic conditions. The Journal of Physical Chemistry B 111, 11443-11446 (2007).

Anions

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