Inhibition of microbial colonization of shipboard fuel systems

The aim of the investigation was to study the problem of colonization of shipboard fuel systems and to examine the effect of a number of environmental factors on microbial growth and survival in order to find potential preservative treatments. A variety of microbial species were isolated from sample...

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Main Author: Wycislik, Eric T.
Published: Aston University 1982
Subjects:
577
Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.292016
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spelling ndltd-bl.uk-oai-ethos.bl.uk-2920162017-04-20T03:25:34ZInhibition of microbial colonization of shipboard fuel systemsWycislik, Eric T.1982The aim of the investigation was to study the problem of colonization of shipboard fuel systems and to examine the effect of a number of environmental factors on microbial growth and survival in order to find potential preservative treatments. A variety of microbial species were isolated from samples taken from fuel storage tanks. Bacteria were more numerous than yeasts or fungi and most microorganisms were found at the fuel/water interface. 1he salinity, pH and phosphate concentration of some water bottoms were characteristic of sea water. Others were brackish, acidic and varied in phosphate content. Microorganisms were cultured under a number of environmental conditions. After prolonged incubation, the inoculum size had no effect on the final biomass of Cladosporium resinae but the time required to achieve the final mass decreased with increasing spore number. Undecane supported better growth of the fungus than diesel fuel and of four types of diesel fuel, two allowed more profuse growth. With sea water as the aqueous phase, a number of isolates were inhibited but the addition of nutrients allowed the development of many of the organisms. Agitation increased the growth of C. resinae on glucose but inhibited it on hydrocarbons. The optimum temperature fgr growth of C. resinae on surface culture lay between 25º C and 30º C and growth was evident at 5º C but not at 45º C. In aqueous suspension, 90% of spores were inactivated in around 60 hours at 45ºC and the same proportion of spores of C. resinae and Penicillium corylophilum were destroyed after about 30 seconds at 65ºC. The majority of bacteria and all yeasts in a water bottom sample were killed within 10 seconds at this temperature. An increase in the concentration of an organo-boron compound caused more rapid inactivation of C. resinae spores and raising the temperature from 25ºC to 45°C significantly enhanced the potency of the biocide.577Biological SciencesAston Universityhttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.292016http://publications.aston.ac.uk/10510/Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 577
Biological Sciences
spellingShingle 577
Biological Sciences
Wycislik, Eric T.
Inhibition of microbial colonization of shipboard fuel systems
description The aim of the investigation was to study the problem of colonization of shipboard fuel systems and to examine the effect of a number of environmental factors on microbial growth and survival in order to find potential preservative treatments. A variety of microbial species were isolated from samples taken from fuel storage tanks. Bacteria were more numerous than yeasts or fungi and most microorganisms were found at the fuel/water interface. 1he salinity, pH and phosphate concentration of some water bottoms were characteristic of sea water. Others were brackish, acidic and varied in phosphate content. Microorganisms were cultured under a number of environmental conditions. After prolonged incubation, the inoculum size had no effect on the final biomass of Cladosporium resinae but the time required to achieve the final mass decreased with increasing spore number. Undecane supported better growth of the fungus than diesel fuel and of four types of diesel fuel, two allowed more profuse growth. With sea water as the aqueous phase, a number of isolates were inhibited but the addition of nutrients allowed the development of many of the organisms. Agitation increased the growth of C. resinae on glucose but inhibited it on hydrocarbons. The optimum temperature fgr growth of C. resinae on surface culture lay between 25º C and 30º C and growth was evident at 5º C but not at 45º C. In aqueous suspension, 90% of spores were inactivated in around 60 hours at 45ºC and the same proportion of spores of C. resinae and Penicillium corylophilum were destroyed after about 30 seconds at 65ºC. The majority of bacteria and all yeasts in a water bottom sample were killed within 10 seconds at this temperature. An increase in the concentration of an organo-boron compound caused more rapid inactivation of C. resinae spores and raising the temperature from 25ºC to 45°C significantly enhanced the potency of the biocide.
author Wycislik, Eric T.
author_facet Wycislik, Eric T.
author_sort Wycislik, Eric T.
title Inhibition of microbial colonization of shipboard fuel systems
title_short Inhibition of microbial colonization of shipboard fuel systems
title_full Inhibition of microbial colonization of shipboard fuel systems
title_fullStr Inhibition of microbial colonization of shipboard fuel systems
title_full_unstemmed Inhibition of microbial colonization of shipboard fuel systems
title_sort inhibition of microbial colonization of shipboard fuel systems
publisher Aston University
publishDate 1982
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.292016
work_keys_str_mv AT wycislikerict inhibitionofmicrobialcolonizationofshipboardfuelsystems
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