Oil is a ubiquitous contaminant thr

Oil is a ubiquitous contaminant throughout the marine environment
(Wilson and LeBlank, 2000). Petroleum-derived hydrocarbons
are a major contributor to the contamination of aquatic
environments and approximately 5 million tons of crude oil enters
the marine environment each year from a variety of sources (Neff
et al., 2000).
The Arabian Gulf represents approximately 4.7% of the total oil
pollution in the world (Madany et al., 1998). The turnover and
flushing time has been estimated to be in the range of 3–5 years,
indicating that oil pollutants, particularly hydrocarbons, are likely
to reside in the Gulf for a considerable amount of time. The levels
of petroleum hydrocarbons in United Arab Emirates coastal waters
were reported to range from 76 mg/L to 180 mg/L between the years
1998 and 2004 (Khan et al., 1995; Shriadah, 2000; Tolosa et al.,
2005). Compared with seas in Europe and USA, where most oil
toxicity tests have been performed, the Arabian Gulf is particularly
characterized by lower depth, higher salinities and higher temperatures
(Sheppard, 1993) all of which can have an impact of the
effectiveness and impacts of dispersants. There is a need to do
toxicity tests that are representative of prevalent conditions (e.g.
temperature and salinity) and employs indigenous species.
Reynolds (1993) reported average summer surface temperatures
of between 24 1C and 30 1C and surface salinities of between 33
and 40 over the same period. Furthermore, the average depth of
the inner gulf is only 36 m. The light Arabian crude oil was found
to contain 54% saturated hydrocarbons, 35% aromatic hydrocarbons
and 11% polar compounds (Agamy. Unpublished data).
Crude oil is a complex mixture of organic compounds, 75% of
which consist of short and long chain hydrocarbons (Neff, 1979).
The water-accommodated fraction (WAF) contains hydrocarbons
that are less soluble and much more persistent in aquatic environments,
such as long chain hydrocarbons. Dispersants generally
consist of anionic and nonionic surfactants, which act to break up
the oil slick by promoting the formation of small mixed oilsurfactant
micelles (George-Ares and Clark, 2000). By decreasing
the surface tension of the oil layers, dispersants increase the surface areaand,consequently,facilitate the biodegradation of
crude oil.In marine environments,chemical dispersant salter the
normal behavior of petroleumhydrocarbon sby increasing their
functional water solubility,resulting in increased bioavailability
and alteredinteractionsbetweendispersant,oil,andbiological
membranes (Wolfeetal.,2001). Considerationoftheuseof
chemical dispersantsasanoilspillcountermeasurehasgrown
substantially inrecentyearsduetoanumberoffactors(Venosa
and Holder,2007). Althoughwidelyusedinthemitigationofoil
spills, dispersantsarealsoknowntopromoteatemporaryincrease
in theconcentrationofhydrocarbons,particularlyPAHs,inthe
watercolumn,therebyincreasingthebioavailabilityofthese
pollutants foruptakebyaquaticorganisms,especiallypelagic
and benthonicspecies(Wolfeetal.,2001; Ramachandran etal.,
2004). Theeffectivenessofadispersantinbreakingupanoilslick
in waterisstronglyinfluenced byenvironmentalfactorssuchas
temperature,salinityandwatervelocity,aswellasthecomposi-
tion ofthecrudeoilandthesurfactants.Thesefactorsarecritical
because oftheirabilitytoimposelimitationsontheratesof
mixture anddilutionofthesecompoundsinaquaticenvironments
(George-AresandClark,2000). Researchhasshownthatsuscept-
ibility tooilanddispersantsdifferbetweenspeciesanddevelop-
mental stages(Neff etal.,2000; Cohen andNugegoda,2000;
Ramachandran etal.,2004; Lin etal.,2009).
Fish gillisamultifunctionalorganresponsibleforrespiration,
osmoregulation,acid-basebalanceandnitrogenouswasteexcre-
tion (Dolenec andKuzir,2009). Althoughtherearemarked
differences inthegrossanatomyofthegillamongdifferentgroups
of fish, thecellsthatcomposethegillepitheliumareverysimilar
(Wilson andLaurent,2002). Themaincellsthatconstitutethe
filament epitheliumarenon-differentiated,neuroepithelial,chlor-
ide, mucousandpavementcells.Thepavementcellsofthe
lamellar epitheliumaredirectlyrelatedtogasexchangeandthe
chloride cellsarerelatedtotheionregulation(Sakuragui etal.,
2003; Fernandes etal.,2007). Themucushasbeenconsideredan
important protectionagainstabrasiveinjuriesbysolidmaterials
suspended inwaterandpollutants(Ledy etal.,2003; Robertsand
Powell,2005; Singh andBanerjee,2008). Gillsarethemajorroute
of uptakeofwaterbornepollutants,includinghydrocarbonsand
surfactants, byaquaticorganisms(Wood,1992; Evansetal.,2005).
Crude oilhydrocarbonsandsurfactantshavebeenshownto
promotestructuraldamageinthebranchialrespiratoryepithelium
(Engelhardtetal.,1981; Rosety-Rodriguezetal.,2002).
Histopathologicalinvestigationshavelongbeenrecognizedto
be reliablebiomarkersofstressin fish andgilllesionsasindicators
of exposuretocontaminantshavepreviouslybeenusedinnumer-
ous laboratoryand field studiesaroundtheworld(reviewedin
Mallatt (1985), Wood(2001), Au(2004), Hinton etal.(2008)).
There arealreadyseveralreportsabouthistologicalalterationsin
the gillsduetothetoxicityofspiltoil(Spies etal.,1996; Caldwell,
1997; Khan, 1998, 2003; Katsumiti etal.,2009) orinlaboratory
exposuresof fish topetroleumoil(Brand etal.,2001; Rudolph
et al.,2001; Akaishi etal.,2004; Simonatoetal.,2008). Gill
histopathological alterationsincludelamellarcapillaryaneurysms,
vasodilatationoflamellae,hemorrhage,edema,liftingoflamellar
and filamentary epitheliumandepitheliumnecrosis,epithelialand
chloride cellhypertrophyandhyperplasia,fusionofadjacent
lamellae andleukocyticinfiltration.Inaddition,epitheliocystisis
a commonconditionofaputativeinfectiousaetiologythathas
been describedinvariousteleoststoaffectboththegillandskin
epithelium (NowakandLaPatra,2006). Itischaracterizedby
cytoplasmic bacterialmembrane-boundinclusionsorcystsfound
in gillepithelialcellsof fish. Thepresenceofthesecystshasalso
been implicatedinproliferativegillinflammation thatrepresentsa
threat to fish healthinmanyspecies(Mitchell etal.,2010).
Epitheliocystishasbeenreportedtobeassociatedwithmortality
in manymarineandfreshwater fish species,especiallyinfarmed
fish (GrigorakisandRigos,2011).
The white-spottedspinefoot, Siganus canaliculatus, isamem-
ber ofthefamily Siganidae, commonlyknownasrabbitfish. Itis
distributed throughouttheIndo-Pacific fromtheArabianGulfto
the Indo-Malayregion,WesternAustraliaandnorthtoHongKong
and Taiwan(Woodland,1984, Grandcourtetal.,2007). Rabbit fish
arediurnal,someliveinschool,whileotherslivemoresolitary
livesamongthecorals.Theyareherbivorous,schoolingincoastal
sandy ormuddyareasandfeedmainlyonalgaeandseagrass.
Siganids aregenerallyregardedasgoodfood fish inspiteoftheir
relativelysmallsizeandisacommerciallyimportantspeciesinthe
ArabianGulfregion.
Additionalinformationisneededtodeterminethepotential
effects ofoilspillson fish speciesintheArabianGulf.Therefore,
the maingoalofthisstudywastoinvestigatetheeffectofoil
contamination onthegillofjuvenile Siganus canaliculatus as part
of aprojectinvestigatingtheimpactofoilpollutiononeconomic-
ally important fish speciesoftheArabianGulf.
There islittleexistinginformationontheeffectsofexperi-
mental exposureofArabianGulf fish tolightArabiancrudeoilor
dispersed oil.Thisstudyexaminedthehistopathologicaleffectsof
exposing fish toWAFofArabiancrudeoil,dispersedcrudeoil,and
dispersant (MaxiClean2)foraperiodofthreeweeks.Becausethe
dispersant usedinthepresentstudyhaskeroseneasthemain
constituent, whichisalsoahydrocarbon,acontrolgroupof fish is
treatedbydispersantalone.Significant alterationsinfourhealth
categories(circulatory,degenerative,proliferativeandinflammatory)wereidentified andformthebasisforunderstandingthe
short-termresponseof fish tooilanddispersedoil.Hopefully,this
study willhelpintheconductofpollutionmonitoringforboth
point andnon-pointsourcesofPAHsintheArabianGulf