%0 Journal Article
%T Disinfection Treatment of Heated Scallop-Shell Powder on Biofilm of <i>Escherichia coli</i> ATCC 25922 Surrogated for  <i>E. coli</i> O157:H7
%A Miki Kubo
%A Yori Ohshima
%A Fumio Irie
%A Mikio Kikuchi
%A Jun Sawai
%J Journal of Biomaterials and Nanobiotechnology
%P 10-19
%@ 2158-7043
%D 2013
%I Scientific Research Publishing
%R 10.4236/jbnb.2013.44A002
%X <p>
	<span><span style=\"font-family:Verdana;\">The ability of heated scallop-shell powder (HSSP) to disinfect </span><i><span style=\"font-family:Verdana;\">Escherichia coli </span></i><span style=\"font-family:Verdana;\">ATCC 25922 biofilm was investigated. On account of its cryotolerance and cell surface characteristics,</span><i> </i><span style=\"font-family:Verdana;\">the </span><i><span style=\"font-family:Verdana;\">E. coli</span></i><span style=\"font-family:Verdana;\"> strain is reportedly a useful surrogate for </span><i><span style=\"font-family:Verdana;\">E. coli</span></i><span style=\"font-family:Verdana;\"> O157: H7 in surface attachment studies. In this study, an </span><i><span style=\"font-family:Verdana;\">E. coli</span></i><span style=\"font-family:Verdana;\"> ATCC 25922 biofilm was formed on a glass plate, and immersed in a slurry of HSSP. Following treatment, the disinfection ability of the HSSP toward the biofilm was non-destructively and quantitatively measured by conductimetric assay. The disinfection efficacy increased with HSSP concentration and treatment time. HSSP treatment (10 mg/mL, pH 12.5) for 20 min completely eliminated biofilm bio</span></span><span><span style=\"font-family:Verdana;\">activity (approximately 10</span><sup><span style=\"font-family:Verdana;\">8</span></sup><span style=\"font-family:Verdana;\"> CFU/cm</span><sup><span style=\"font-family:Verdana;\">2</span></sup><span style=\"font-family:Verdana;\"> in non-treated biofilms). In contrast, treatment with NaOH solution at the same pH, and treatment with sodium hypochlorite (200 </span></span><span style=\"font-family:Verdana;\">m</span><span><span style=\"font-family:Verdana;\">g/mL) reduced the activity by approximately one to three log</span><sub><span style=\"font-family:Verdana;\">10</span></sub><span style=\"font-family:Verdana;\">. Fluorescence microscopy confirmed that no viable cells remained on the plate following HSSP treatment (10 mg/mL). Although alkaline and sodium hypochlorite treatments removed cells from the biofilm, under these treatments, many viable cells remained on the plate. To elucidate the mechanism of HSSP activity against </span><i><span style=\"font-family:Verdana;\">E. coli</span></i><span style=\"font-family:Verdana;\"> ATCC 25922, the active oxygen generated from the HSSP slurry was examined by chemiluminescence analysis. The luminescence intensity increased with increasing concentration of HSSP slurry. The results suggested that, besides being alkaline, HSSP gen</span></span><span><span style=\"font-family:Verdana;\">erates
%K Scallop-Shell Powder
%K Biofilm
%K &lt
%K i&gt
%K Escherichia coli&lt
%K /i&gt
%K Conductimetric Assay
%K Fluorescence Microscopy
%K Active Oxygen
%K Alkali
%U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=40636