This is an electronic reprint of the original article. This reprint may differ from the original in pagination and typographic detail. Yildiz, Hijran Yavuzcan; Robaina, Lidia; Pirhonen, Juhani; Mente, Elena; Domínguez, Author(s): David; Parisi, Giuliana Title: Fish Welfare in Aquaponic Systems : Its Relation to Water Quality with an Emphasis on Feed and Faeces : A Review Year: 2017 Version: Please cite the original version: Yildiz, H. Y., Robaina, L., Pirhonen, J., Mente, E., Domínguez, D., & Parisi, G. (2017). Fish Welfare in Aquaponic Systems : Its Relation to Water Quality with an Emphasis on Feed and Faeces : A Review. Water, 9(1), Article 13. https://doi.org/10.3390/w9010013 All material supplied via JYX is protected by copyright and other intellectual property rights, and duplication or sale of all or part of any of the repository collections is not permitted, except that material may be duplicated by you for your research use or educational purposes in electronic or print form. 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Electronic or print copies may not be offered, whether for sale or otherwise to anyone who is not an authorised user. water Review Fish Welfare in Aquaponic Systems: Its Relation to Water Quality with an Emphasis on Feed and Faeces—A Review HijranYavuzcanYildiz1,*,LidiaRobaina2,JuhaniPirhonen3,ElenaMente4, DavidDomínguez2andGiulianaParisi5 1 DepartmentofFisheriesandAquaculture,FacultyofAgriculture,UniversityofAnkara, 06110Ankara,Turkey 2 AquacultureResearchGroup,EcoaquaInstitute,UniversityofLasPalmasdeGranCanaria, MarineScientificTechnologicalPark,Taliarte,35200Telde,GranCanaria,Spain; [email protected](L.R.);[email protected](D.D.) 3 DepartmentofBiologicalandEnvironmentalScience,UniversityofJyvaskyla,P.O.Box35, FI-40014Jyvaskyla,Finland;juhani.pirhonen@jyu.fi 4 DepartmentofIchthyologyandAquaticEnvironment,SchoolofAgriculturalSciences, UniversityofThessaly,FytokoStreet,N.IoniaMagnesia’s,GR38446Volos,Greece;[email protected] 5 DepartmentofAgri-FoodProductionandEnvironmentalSciences—AnimalScienceSection, UniversityofFirenze,ViadelleCascine5,50144Florence,Italy;giuliana.parisi@unifi.it * Correspondence:[email protected];Tel.:+90-53236-58686 AcademicEditor:M.HaïssamJijakli Received:30September2016;Accepted:20December2016;Published:1January2017 Abstract: Aquaponicsisthecombinationofaquaculture(fish)andhydroponiccultivationofplants. Thisreviewexaminesfishwelfareinrelationtorearingwaterquality,fishfeedandfishwasteand faecestodevelopasustainableaquaponicsystemwheretheco-culturedorganisms,fish,bacteriain biofiltersandplants,shouldbeconsideredholisticallyinallaquaponicsoperations. Waterquality parametersaretheprimaryenvironmentalconsiderationforoptimizingaquaponicproductionand fordirectlyimpactingfishwelfare/healthissuesandplantneeds.Inaquaponicsystems,theuptakeof nutrientsshouldbemaximisedforthehealthyproductionoftheplantbiomassbutwithoutneglecting thebestwelfareconditionsforthefishintermsofwaterquality. Measurestoreducetherisksof the introduction or spread of diseases or infection and to increase biosecurity in aquaponics are alsoimportant. Inaddition,thepossibleimpactsofallelochemicals,i.e.,chemicalsreleasedbythe plants,shouldbetakenintoaccount. Moreover,theeffectofdietdigestibility,faecesparticlesize andsettlingratioonwaterqualityshouldbecarefullyconsidered. Asavailableinformationisvery limited,researchshouldbeundertakentobetterelucidatetherelationshipbetweenappropriatelevels ofmineralsneededbyplants,andfishmetabolism,healthandwelfare. Itremainstobeinvestigated whetherandtowhatextenttheconcentrationsofsuspendedsolidsthatcanbefoundinaquaponic systems can compromise the health of fish. Water quality, which directly affects fish health and well-being,isthekeyfactortobeconsideredinallaquaponicsystems. Keywords: fishwelfare;waterquality;suspendedsolids;micronutrients;aquaponics;sustainability 1. Introduction Aquaponics, the combined production of fish in recirculated aquaculture systems and hydroponically grown plants, has gained increased interest over the last several years due to its sustainability. Aquacultural waste contains nitrogen (in the form of ammonia and nitrate) and phosphorus (mainly in the form of phosphate), which are essential nutrients for plant growth. Water2017,9,13;doi:10.3390/w9010013 www.mdpi.com/journal/water Water2017,9,13 2of17 The plants filter dissolved waste products from the system by utilizing them as a nutrient source, therebyreducingtheneedforbiologicalorchemicalfiltrationforwaterchangesandwaterquality management. Theuseofdissolvednutrientsfromfishexcretaforplantproductionhasbeenshownto increaseplantbiomass,andfreshwateraquaponicsystemscanbeusedtoreducetheenvironmental effectsassociatedwithfoodproductiononland[1].Aquaponicallygrownproductsprovideconsumers with high quality, safe and nutritious freshwater fish and plants grown in a sustainable manner. Asaquaponicsisanintegratedsystemthatcoverstheco-productionofplantsandfish,thecombination offishandplantsshouldbecompatiblewiththecharacteristicsofeachproductiontypetobalance nutrientproductionfromfishcultureandnutrientuptakebyplants. Theselectionofplantandfish speciesbasedonthisfactisofcriticalimportanceintermsofsuitabilityforaquaponicsproduction. Duetotheircoherentfeatureswithrespecttoaquaponicproduction,tilapia,koi,goldfish,carp,catfish, barramundi,andvariousornamentalfishspeciesarethemainproducedfishspeciesandthelettuce, pakchoi,kale,basil,mint,watercress,tomatoes,peppers,cucumbers,beans,peas,squash,broccoli, cauliflower and cabbage are the main produced plants in the present conditions. In aquaculture operations,includingaquaponicssystems,fishwelfareisanimportantfactorthatplaysasignificant roleinasuccessfulbusinessoperation. Fishwelfareingeneralisacomprehensiveissueintegrating physiological,behaviouralandcognitiveresponses,indicatingadaptiveresponsestostressfulstimuli. Thus,Segneretal.[2]havestatedthatpoorwelfaremayprovideastrongindicationfortheexistenceof infectiousandnon-infectiousstressors,leadingtoimpairmentinmaintaininghomeostasis.Fishwelfare must be viewed as the interaction of multifactorial effects, such as stocking density, diet, feeding technique,andmanagementprocedures,possiblyaffectingstresslevels,subsequentstresstolerance, health,andthepresenceofaggressivebehaviour. Ithasbeenrevealedthattheseeffectsarerelated withthewelfareoffarmedfish. Toimprovethequalityoftheproductwithincreasingitsmarketvalue andtoachieveapositivepublicperception,weakfishmustbeavoided,andhealthyanimalsmustbe raisedinaccordancewithwelfarestandards[3]. Fishwelfareinaquaponicsystemscanbeanimportantcriterionfortheconsumer. Theconditions inaquaponicsystemsshouldpromotefishgrowthandhealth,commonlyregardedasindicatorsof fishwelfare, todeliverhighqualityproductstoconsumers. Inaddition, itiswellestablishedthat optimalgrowingconditionsarenecessarytofulfiltheessentialphysiologicalrequirementstopromote fishhealthandwelfare. However,thestudyoffishwelfareisstilllackingforthespeciesculturedin aquaponics. Theaimofthispaperistoreviewthepotentialfactorsresultingfromfishnutritionand waterqualityparametersonfishwell-beingunderaquaponiccultureconditions. 2. WaterQuality Water quality parameters are of major concern in hazard identification for the welfare risk assessment of various aquaculture operations; hence, aquaponic systems are not distinct from aquaculture. Fishraisedinaquaponicsystemsrequiregoodwaterqualityconditionswhichmeanthat parameterssuchasdissolvedoxygen,carbondioxide,ammonia,nitrate,nitrite,pHmustbewithin acceptablespecies-specificlimits. Suddenchangesinthefishstockingdensity,growthrate,feeding rateorwatervolumecanelicitrapidchangesinwaterquality;hence,regularmeasurementofthose criticalwaterqualityparametersisessential. Thedeteriorationofwaterqualityparametersaffects fishphysiology,growthrate,andfeedefficiency,leadingtopathologicalchangesandevenmortality underextremeconditions[4,5]. Intermsofaquaponicsystemsandconsideringthefishwelfareissues, carryingcapacityisofmajorconcernformaintainingthebalancebetweenplantandfishrequirements inaco-culturemedium. Carryingcapacityexpressesthemaximumbiomassoffishinthesystemwith acceptablewaterqualitylimits. Thecarryingcapacityofagivenamountofwaterisdeterminedby theoxygenconsumptionrateofthefishandtheirresponsestoammonia,CO andotherpotentially 2 toxicmetabolicwastesthatareproduced[5]. Stressinvolvesaseriesofphysiologicalandbehavioural reactionsthathelpfishresistdeathoradapttochangingconditions.Whenstressissevereorprolonged, thecapacityofthefishtore-establishhomeostaticnormscanbeinadequate. Theultimateresultmay Water2017,9,13 3of17 includeimpairedimmunefunctionordeath[6]. Thestressresponsesoffishtoenvironmentalstressors arecomplex;therefore,evaluatingtheenvironmentalconditionsandunderstandingtheirpotential deleteriouseffectsonfishareofutmostimportanceinanysystemthatholdsfishincaptivity. For the welfare of fish in an aquaponic system, water quality is the primary environmental consideration with a potential to markedly affect fish health. Fish exist in intimate contact with the water through the huge surface area of the gills and skin, and it is widely acknowledged that fish are vulnerable to inappropriate water quality. Water provides fish with the oxygen required tosurvive,dilutesandremovespotentiallytoxicmetabolites,andprovidessupportagainstgravity. Inappropriatelevelsofwaterqualityparametersaffectphysiology,growthrateandfeedefficiency (biomassincrease/feedfed)andmaycausenegativestimuli. Fromtheperspectiveofaquaponics, thestabilizationofthechemicalcompositionofwaternormallyrequiressometimedependingonthe temperatureandarangeofotherfactorssuchasstockingdensity. Thestabilityofwatercharacteristics in aquaponic systems may set the biological limits for sustainable production. In other words, aproductionformatforco-culturedspecies(aquaticorganismsandplants)impairingthebiological capacityofthefishmaybecausedbyunstablewaterconditions,whichaffectthewelfareconditions throughcomplexinteractionsbetweenwaterqualityparameters. Dissolved oxygen (DO) is the primary water quality consideration for aquaponic systems as in other aquaculture units. Fish extract oxygen from the water by passive diffusion through the gills. AnadequateconcentrationofDOinthewaterisrequiredtofacilitatepassivediffusiondown a concentration gradient from the water into the blood [7]. If DO concentrations fall below the requirementsofthefish,thenfishcannotconvertenergyasefficientlyintoausableform,resulting inreducedgrowthrate, feedefficiencyandswimmingability[8]. Theimmediateresponseoffish to decreased DO concentrations is to increase the opercular ventilation rate and show a gasping response[9]. Inaquaponics,theminimumoxygenlevelstopromotegoodhealthandphysiologicalconditionsin thefishstockcanchangebasedonfishspeciesandfishsize.Thesolubilityofoxygeninwaterdecreases asthetemperatureincreases. ColtandTomasso[7]contributedthebasicpointsinaquaculturepractise thatareofimportanceinaquaponicsystemswhenconsideringtheallowableDOlevels,i.e., • elevatedtemperatureincreasesthemetabolism,respirationandoxygendemandoffish; • fish increase their oxygen uptake after feeding due to the oxygen demand required for feed processing,calledspecificdynamicaction; • oxygenconsumptionisproportionaltothesizeandnumberoffishinagivensystem; • smallerfishusemoreoxygenperunitweightthanlargerfish; • stressful conditions such as impaired gill function, exposure to stressors and decrease in oxygen-carryingcapacityleadtotheincreaseinoxygendemandoffish. Ingeneral,therecommendedlimitforDOlevelsinfishcultureis6ppmforcoldwaterfishand 4ppmforwarmwaterfishtoprotectthehealth[9]. In aquaponics, the nitrogen cycle is a critical factor. The cycle begins with the introduction of protein in fish feed, which is ingested by fish and then excreted to the aqueous phase in the form of total ammonia nitrogen (TAN, i.e., NH and NH ). Ammonia is first oxidized to nitrite 3 4 (NO )byammonia-oxidizingbacteria(mainlyNitrosomonasspp.) inabiofilterandthenconverted 2 tonitrate(NO )bynitrite-oxidizingbacteria(mainlyNitrobacterspp.). Intheaquaticenvironment, 3 ammoniaexistsintwoformsinequilibrium: un-ionisedammoniaandionisedammonium. Thus, thetotalammoniaconcentrationisthesumoftheconcentrationsofun-ionisedammoniaandionised ammonium. TheequilibriumbetweentheNH andNH + variesinrelationtothevariousfactors, 3 4 mostsignificantlytheconcentrationofhydrogenions(i.e.,pH)andtemperature. Inanaquaponicsystem,mostoftheammoniafoundinafishfarmisproducedbythefishasin aquaculturesystems. Ammoniaistheprimarywastemetaboliteproducedbyfishfromthecatabolism ofproteincontainedwithinthefeed.Mostbiologicalmembranesarepermeabletoun-ionisedammonia Water2017,9,13 4of17 and relatively impermeable to ionised ammonium. Therefore, in fish, ammonia in the external environmenteitherinducesretentionofendogenousammoniainthefishorentersviathegillsby passive diffusion down a concentration gradient. The ammonia is excreted from the fish via the gills[10].AmmoniatoxicityisdependentprimarilyontheconcentrationofammoniaandthepHofthe environment. RandallandTsui[11]reportedthatacuteammoniatoxicityaffectsthecentralnervous system of fish and manifests as a neurological disorder. Ammonia interferes with physiological processesthateventuallyresultinthedeathofcellsinthebrain;however,ammoniatoxicityandits exactnaturearenotunderstoodinfish. Highconcentrationsofammoniadecreasesurvival,inhibit growth,andcauseavarietyofphysiologicaldysfunctions. Thehighlevelofammoniainwateracts asastressorinthatitstimulatesthereleaseofcorticosteroidhormonesintocirculation,affectingthe welfareofthefish. Masseretal.[12]statedthatun-ionizedammonianitrogenconcentrationsaslowas 0.02–0.07ppmhavebeenshowntoslowgrowthandcausetissuedamageinseveralspeciesofwarm waterfish. However,tilapiatoleratehighun-ionizedammoniaconcentrationsandseldomdisplay toxiceffectsinwell-bufferedrecirculatingsystems. However, insensitivespeciessuchasrainbow trout(Oncorhynchusmykiss),therecommendedlevelofun-ionisedammoniais<0.02mg·L−1[9]. Inthe management of recirculating systems, ammonia should be monitored daily. If the total ammonia concentrationsstarttoincrease,thebiofiltermaynotbeworkingproperlyorthefeedingrate/ammonia nitrogenproductionishigherthanthedesigncapacityofthebiofilter. Nitritebecomestoxicevenatlowconcentrationsformanyfishspecies[13]. Thedegreeoftoxicity to nitrite varies with species. In freshwater fish, nitrite enters through the gills. Nitrite ions are actively taken up through the chloride cells, and they can be pumped in against a concentration gradient[14]. Bloodplasmaconcentrationsofnitritecanaccumulateuptotentimesgreaterthanthe ambientwaterconcentration[15]. Infish,bloodisthemaintargetofnitriteaction. Nitritediffuses from the blood plasma into red blood cells, where it oxidises the Fe2+ in haemoglobin (Hb) to the Fe3+oxidationstate,convertinghaemoglobinintomethaemoglobin(metHb). MetHbreducesthetotal oxygen-carryingcapacityoftheblood[16]. Nitriteexposureresultedinareductioninhaemoglobin andhaematocritintilapia(Oreochromisniloticus)withmildmethaemoglobinaemiafollowingexposure to0.50and1.38mg·L−1 NO −-Nfor48-hstatictests[17]. Nitriteexposureintherangeof0.50and 2 1.38mg·L−1NO −-Ncausedanincreaseinmethaemoglobinlevels. Methaemoglobinconcentrations 2 in excess of 50% are considered threatening to fish [18]. The physiological disturbances may be primarily rooted in the hypoxia caused by methaemoglobin accumulation. Thus, it is predictable thattheoxygenstarvationinduceshyperventilation. Becausethegillsaredirectlyincontactwiththe aquatichabitat,themorphologicalandphysiologicalalterationsinthegilltissueareofmajorconcern. Svobodovaetal.[19]reportedthathyperplasia,vacuolisationandelevatednumbersofchloridecells werethemainhistologicallesionsthatoccurredinthegillsofnitrite-treatedcarp(Cyprinuscarpio). Nitritecanreachhighconcentrationsinrecirculatingaquaculturesystemsinwhichhighdensitiesof fisharekept. Scaledfishspeciesaregenerallymoretoleranttohighnitriteconcentrationsthanspecies suchascatfish,whichareverysensitivetonitrite[12]. Lowconcentrationsofdissolvedoxygenaffect thetoxicityofnitrite. Becausenitriteaffectstheabilityofbloodtotransportoxygen,areductionin ambientwaterDOconcentrationsincreasestheeffectoftoxicity. Althoughtherearemanystudies aboutacuteandsublethaleffectsofnitriteonfishintheliterature[14,16,20–22],comprehensivestudies onthechroniceffectsofnitriteondifferentfishspeciesunderaquaponicconditionswillbenecessary consideringtheinteractionofplantrootsandtheefficiencyofrelatedbacteriainthesystem. Inbrief, therelatedbacteriathatmaybeinvolvedinaquaponicsystemsarethefollowing: ammonia-oxidizing bacteria(AOB),includingbacteriaofthegeneraNitrosomonas,Nitrosococcus,Nitrosospira,Nitrosolobus, andNitrosovibrio,andnitrite-oxidizingbacteria(NOB),includingbacteriaofthegeneraNitrobacter, Nitrococcus,Nitrospira,andNitrospina[23]. In general, information on chronic nitrate toxicity in cultured fish species across various life stages is limited. Nitrate, the end product of nitrification, is relatively non-toxic except at very highconcentrations(over300ppm[12]). However, Davidsonetal.[24]reportedthatcaseswhere Water2017,9,13 5of17 recirculatingaquaculturesystems(RAS)wereoperatedwithverylowwaterexchangenitratecaused chronictoxicitytovariousfishspecies.Thus,thestudyofDavidsonetal.[24]underlineshowrelatively lownitratelevels(80–100mg·L−1NO -N)wererelatedtochronichealthissuesinandwelfareimpacts 3 tojuvenilerainbowtroutunderRASconditions. Changesinswimmingbehaviour,slightlydecreased survivalandreducedtotalbiomasswerethemainfindingsofimpairedwelfareconditionsinaRAS system with rainbow trout. Nevertheless, in the case of aquaponics, nitrogen compounds should alwaysbeevaluatedwiththevegetationfactor. Nitrateandammoniumarethemostcommonformsof nitrogentakenupbytheplants. Theremovalofnutrientsisaffectedbytheplantspeciesandcropping method,asreportedbyBuzbyandLin[25]. Thepotentialadverseeffectsofammoniumornitrateon thefishwell-beingareexpectedtoberelievedwiththeremovalofthesecompoundsviaplantuptake intheaquaponicsystem. However,thedesigningofaquaponicsystemsandthetechniquesusedare thefactorsaffectingnitrogencompoundsconcentrationsinthesystemandtheirpossiblestresseffects onfishaswellasstresstype. A disruption of the balance between fish, filters and plants at any time may also result in ammonia or nitrite that could be fatal to the fish and certainly reduce performance and increase thesusceptibilitytodiseases. Suchdisruptionsmayarisefromasignificantdecreaseinplantorfish biomass,asignificantincreaseinfeedinput,adecreaseinfiltercapacityasaresultofsloughingof accumulatedbacteria/organicmatter,acleaningofthesystem,orasuddenchangeinpH.Temperature isavitallyimportantphysicalpropertyofthewaterinaquaponicsystems. Theamountofdissolved oxygenisdirectlylinkedwithwatertemperature. Watertemperatureaffectstherateofdecomposition andphotosynthesis,whichwillaffecttheoxygendemandinsystemsandtheionisationofammonia[7]. Optimal temperatures for growth and spawning have been examined for many species that are important to aquaponics. Increasing the temperature has been found to increase the growth and infectiousnessofmanyfishpathogens[4]aswellasthetoxicityofmanydissolvedcontaminants[9]. Allofthesefactorshavethecapacitytocompromisethehealthoffishunderaquaponicconditions. Modelstudiesonwatertemperaturetomaintainthewell-beingoffisharenecessarytoachieveoptimal plantgrowthinaquaponicsystems. ThemanagementofpHisalsonecessaryinaquaponicsystemsbecausepHwillsteadilydecline asaresultofthenitrificationprocess,whichincreasesH+ andNO − ionsinthesystem. Acrucial 3 iteminaquaponicsystemsispHstabilizationbecauseitiscriticaltoalllivingorganismswithina cyclingsystemthatincludesfish,plantsandbacteria. MostplantsrequireapHvaluebetween5.5 and 6.5 to enhance the uptake of nutrients. However, the optimal pH of three major bacteria has beenstatedas(1)Nitrobacter: 7.5;(2)Nitrosomonas: 7.0–7.5;and(3)Nitrospira: 8.0–8.3[26]. However, intermsofthetoleranceoffishtopHchangesbasedonfishspeciesandsize,therecommendedpH foraquacultureis6.5–8.5[27]. InintegratingthehydroponicsystemswithaquaculturethepHvalue seemstobethedrasticfactorinordertoconcurrentmaintenanceofnutrientuptakebytheplantand optimalpHvalueforfishandthebacteriainbiofilter. pHvalueshigherthan7.0causesthereduced micronutrient and phosphorus solubility and plant uptake of certain nutrients is restricted in the aquaponicenvironment[28]. Ontheotherhand,asacidicwaterisoneofthestressorsinaquaculture environments,lowlevelsofwaterpHinaquaponicsystemshavethepotentialtoaffectnegativelythe welfareoffish. AnothersubjectrelatedwithpHlevelsistheinteractionbetweenpHandphosphorus (P)availabilityandspeciation. CeroziandFitzsimmons[29]reportedthatPavailabilitydecreased withhighpHvalueofaquaponicnutrientsolutionsandinsolublecalciumphosphatespeciesformed. HencehighpHlevelseemstobeapreclusionintheplantuptakeofPinaquaponics. Intermsoffish welfare,Pinaquacultureisnotclassifiedasawaterqualityparameterthathasthepotentialtoimpact onfishhealth/welfare. Itisknownthatphosphoruscanbetoxic,buttoxicityoccursrarelyinnature andisgenerallynotaconcernexceptfortheindirecteffectsofphosphorus. It is always important to consider that sustainable aquaponic production requires balancing nutrient concentrations and pH for the optimal growth of three organisms: plants, fish, and nitrifyingbacteria. Water2017,9,13 6of17 Theprimarysourceofcarbondioxideisfishmetabolisminaquaculture. Itisknownthatfree carbon dioxide is toxic to fish. Fish cannot release endogenous carbon dioxide into water when ambientCO concentrationsarehigh,resultinginCO increasesintheblood,aconditiondescribedas 2 2 hypercarbia. DuetodecreasesinbloodpHalongwithacidosisinhypercarbia,theoxygen-carrying capacity of the blood declines (the Bohr effect). Carbon dioxide toxicity can be characterized by moribundfish, gapingmouthsandbrightredgilllamellae[30]. ThelinkbetweenCO andwater 2 hardness was reported as the cause of nephrocalcinosis in rainbow trout, with the symptoms of the calcifying material manifesting in the ureters and kidney and as impaired food conversion efficiency [31]. Land-based, recirculating aquaculture systems as well as aquaponic systems can exposefishtohigher-than-naturallevelsofaquatichypercarbia. Oxygenisartificiallysuppliedtothese systemstoincreasefishproduction;however,anincreaseinbiomassnormallyleadstoanincreasein CO production. 2 Ingeneral, thetolerablewaterqualityparametersforfisharewithinthesamerangewiththe plantsexceptwatertemperatureandpHintheaquaponicsystem(Table1). Whenconsideringthe well-beingoffishspeciesinaquaponicsystems,fishspecieswithahightolerancetopHandwater temperatureshouldbetakenintoaccount. ItisobviousthatpHandtemperaturearetheparameters thathaveanimpactonoptimizationofaquaponicproductionbothforfishwelfare/healthissuesand forplantneeds. Table1.Generalwaterqualitytolerancesforfish(warmorcoldwater),hydroponicplantsandnitrifying bacteria(fromSomervilleetal.[32]). Temperature Ammonia Nitrite Nitrate DissolvedOxygen OrganismType (◦C) pH (ppm) (ppm) (ppm) (ppm) Warmwaterfishes 22–32 6–8.5 <3 <1 <400 4–6 Coldwaterfishes 10–18 6–8.5 <1 <0.1 <400 6–8 Plants 16–30 5.5–7.5 <30 <1 - >3 Bacteria 14–34 6–8.5 <3 <1 - 4–8 Inaquaponicsystems,specialcareshouldbetakenwhentreatingthefishtoeradicatediseasesor parasites. Somechemicalsinanaquaponicenvironmentwillharmordestroytheplants,anditiswell knownthatmanychemicalsandmetalswillalsobeabsorbedbytheplants[33,34],hinderingtheiruse forconsumption. Theuseofantibioticsfortreatingbacterialinfectionsisoneoption,buttheymay beabsorbedbytheplants[35],thuscausingwithdrawalperiodsandmarketingproblems;thissame problemisalsoseenwiththefish. Inaquaponicsystems,specialcareshouldbetakenwhentreatingthefishtoeradicatediseases, parasites or water mould. For example, formalin is a common chemical used to treat certain fish parasitesandwatermould,anditcanalsobeusedinrecirculationsystemsrelativelysafelywithout compromisingnitrificationinthebiofilter[36]. However,inanaquaponicsystem,formalincanbe expected to cause severe damage to the plants as formalin added into the soil has been shown to drasticallydecreaseplantcoverandshootdryweight[37]. Inanaquaponicsystem, theplantsmayalsoinducesomedirecteffectsonthefish, atleastin theory. Plantsareknowntoproducechemicalsthattheyexcrete,e.g.,throughtheirroots[38],inorder tomaketheirenvironmentmorefavourabletothemselves. Thisphenomenoniscalledallelopathy, whichveryoftenreferstothedetrimentaleffectsofplantsinthesurroundingenvironment. However, theeffectscouldbepositiveaswelldependingontheinteractingorganismsandtheconcentrationof thechemicalinquestion[39,40]. Allelopathicplants,i.e.,plantsthatreleaseallelochemicals,havebeen discoveredinseveralphyla[33]. Theconcentrationofallelochemicalsreleasedbyaplantcanalso varywidelydependingonthesurroundingplantspecies[38],andthiscouldpotentiallycausefish welfareproblemsinanaquaponicsystemiftheplantspeciesusedproducechemicalstofighteach Water2017,9,13 7of17 other. However,tothebestofourknowledge,negativeeffectsofpotentialallelochemicalsexcretedby aquaponicallygrownplantsonfishhavenotbeenreported. Ontheotherhand,conditionsinhydroponicsystems,andnaturallyinaquaponicsystemsas well,areoftenperfectforthegrowthofdifferentkindsofalgae[41]. Itisknownthatalsoalgaecan releaseallelochemicalswhichcanbeharmfulnotonlyforthefishbutalsoforthemicrobiotaandthe plants[42],e.g.,cyanobacteria(blue-greenalgae)canexcretecyanotoxins,whichcandirectlyplace fishhealthatrisk,orthephysicalpresenceofthesealgaecanharmthegills[43]. Inaddition,thealgal spikesofdiatoms(e.g.,Chaetocerossp.) havebeenreportedtodamagethegillsataconcentrationof fiveorganismspermlwiththeconsequenceofexcessproductionofmucusandinhibitionofoxygen uptake[44]. Despitethepotentialadverseeffectsofalgaeonfishwehavenotfoundreportedevidence ofsuchincidencesinaquaponicsystems. Measures to reduce the risks of the introduction or spread of infection and to reduce the conditionsenhancingsusceptibilitytoinfectionsarecalledbiosecurity[45].Thesemeasuresshouldbe ofutmostimportanceineveryaquaponicoperation. Themethodsforincreasingbiosecurityinclude considerationssuchasthewatersource,sourcesoffishandeggs,preventativedisinfectionpractices forstaffandvisitorsandthequarantineofnewarrivalsasreportedbyTimmonsandEbeling[45]. 3. FeedsandMicronutrients Thedietanditsuseforthefishrepresentthehighestimpactonthecarryingcapacityofaquaponic systems[46].Currently,verylittleisknownaboutspecificfishdietsforaquaponicculture;thus,current dietsforaquaculture,mainlythoseforRAScultureconditions,arewidelyusedforbothpurposes. Apartfromanadequatenitrogen/energybalanceandacorrectcombinationoffeedingredientsand particlesize,thedietformulationforaquaponicsshouldcontainadequateimmuno-ingredientsor additivesthatpromotethebestwelfareconditionstothefishduringthegrowingcycle,thusavoiding anyextratreatmentsintothesystem. Moreover,theeffectsofspecificfeedsonwaterqualitythrough diet digestibility, faeces particle size and settling ratio are also important aspects. Water quality modificationsfromspecificdietsandselectedfeedingstrategieshavebeenrelatedtofishbehavioural changes [40], which are essential for fish nutritionists to interpret dietary effects on the system. Food-anticipatoryactivitycanbeagoodwelfareindicator[47],whichmaybeusedinformulafeed studies. Animportantfactortostudyunderaquaponiccultureconditionswouldbetherelationship betweenthewholefishexcretaandtheplantnutrientrequirements. Aquaponicstudiesmayimplicate interdisciplinaryresearchareastoachievemoreadequatefishfeedformulationsandfeedingstrategies, notonlyfocusingonfishgrowthandwell-being,butalsopromotingthebestplantgrowthandquality fortheconsumers. Although the running of an aquaponic system could be improved through optimal fish and plantspeciesselection[46],andthecorrectfishfeedregime[48],mostofthereportedresearchshows extra nutrient inputs needed for the plants, which should be added to the growing medium or as a foliar spray to improve plant growth [49,50]. Although from literature N, Mg and some other plantnutrientsappeartobeadequatefromfishexcreta,thisisnotthecaseforP,K,Cu,Fe,Mn,Zn andS[51,52],whicharenormallyincludedinthegrowingbedtobeabsorbedfortheplants. Inthis senseitisimportanttonotethatnoinformationhasbeenreportedregardingthepossibleimpactof thesurroundingwaternutrientsonfishwellbeingorwelfare. Itiswellknownthatfishexpendenergy torespondtothechangesinsurroundingmediumosmolalitybyregulatingtheirbodyfluidvolume andsoluteconcentrationthroughendocrinecontrol,withmarineandfreshwateranimalsexhibiting differentstrategiestomaintaintheirhomeostasis(ionicandosmoticgradientsbetweenthebodyfluids andsurroundingseawater)[53]. Nutritionandfeedinginfluencefishgrowth,welfareandhealthandtheirresponsetophysiological andenvironmentalstressorsandpathogens. ThemicronutrientsP,K,Cu,Fe,Mn,ZnandSrepresent a very small percentage in fish feed, and information related to the requirements and effects of thesemicronutrientsonfishaquacultureisrelativelyscarce. Frompublishedpapers,micronutrient Water2017,9,13 8of17 deficienciesaremoreextensivelyreportedcomparedwithstudieswhereexcessamountshavebeen tested, i.e., possible toxicity effects. During last years, the effects of dietary Cu, Mn, Fe and Zn, importantmicronutrientsinfishmetabolism,haveattractedinterestduetotheirlimitedavailabilityin plantproteinformulatedfeedsrespecttothehigherfishmealdiets. Copper (Cu) is an essential metal involved in several Cu-dependent enzymes, which mostly intervene in the defence against oxidation reactions and include the Cu/Zn superoxide dismutase (CuZnSOD), but Cu also participates in the production of energy at the cellular level, inneurotransmission,collagensynthesisandmelaninproduction[54]. LowCulevelsmaygenerate a reduction in feed efficiency and growth [55], while Cu toxicity produces gill damage and liver andkidneynecrosis[54,56]. Iron(Fe)isinvolvedinelectrontransport,oxygentransferandcellular respiration,withaspecialimportanceinhaemoglobin[56,57]. Fecanbepartiallyabsorbedviathe gills;however,themajorityisabsorbedintheintestine. Fedeficiencycausesanaemia,lowhaematocrit andreducedFeinplasma,whereasexcessuptakeofFecausesreducedgrowth,poorfeedutilization, mortalityanddiarrhoea[54,56]. Manganese(Mn)isatransitionmetalessentialforlife,actingasa cofactorforessentialmetalloenzymesinvolvedinthedevelopmentoftheorganicmatrixofbone[58]. Mnsuperoxidedismutase(MnSOD)intervenesinpreventingtheinitiationoftheradicalchainreaction whenanoxidationreactionoccurs. MndeficiencyreducesMnSODactivityinfishtissuesandthelevel ofMn,CaandNainthevertebrae[59]. ExcessMnmayaffecttheintegrityofintestinalimmunity[60], whichisessentialmostlyinmarinefishtomaintaincorrectionregulation. Zinc(Zn)isanessential cofactorforseveralmetabolicprocessesinfishandformspartofupto20metalloenzymesimplicated inlipid,carbohydrateandproteinmetabolism. Znisessentialforstructuralcomponentssuchasbone, skinandscales;playsanimportantroleinregulatingoxidativestressandimmunity;andintervenesin reproductiveprocesses. Znisinvolvedinboneformationandmineralizationbyactivatingosteoblastic cellsandinhibitingosteoclasticboneresorption[61]. Thus,Zndeficiencyinfishcausesslowergrowth rates, cataracts, skin and fin erosion, and dwarfism [56]. Zinc can be absorbed via the gills and gut [62–64]. However, the presence of chelators or competitive substances may interact with zinc absorption. Calcium,phosphates,highwatersalinityandacidicpHaresomeofthefactorsthatcan alterzincavailability. Zincdeficiencymaythusreduceproductionoverthewholelifecycle[54,56,65]. However, zinc toxicity has scarcely been studied, and most trials only reflect data concerning the survivalinfreshwaterspeciesexposedtohighlevelsofwaterbornezinc. Probablythemostimportant toxiceffectofzincisrelatedtotheinhibitionofcalciumabsorption. Calciumandzincsharetransport channels,andathighlevelsofzinc,calciumuptakeisseverelyreduced[66–69]. As a summary, it is important to note that in aquaculture, fish mineral requirements are still poorlyreported,withaverylowamountofinformationwithrespecttodietarymineralunbalanceand excessonfishwelfare. Asfishmayobtainmineralsbothfromsurroundingwateranddiets,research effortsshouldbemadetounderstandthesharedwaterbornemicronutrientcompatibilityandmutual benefitsbetweenplantsandfish,andalsotostudytheeffectsofhigherdietarylevelsofthetarget plantmineralsinthewholeaquaponicproductioncycle,fish,andplants. 4. WastesandFaeces Allmaterialswhichhavebeenusedbutarenotremovedfromtheaquaculturalsystemduring harvestingcanberegardedaswaste[70]. Thecompoundscontainedinthefeedaredigested,absorbed andutilizedinthemetabolicprocessesandretainedindifferentmeasuresinthebodyoffish. Onepart ofthosecompoundsisexcretedthroughthegillsorasfaeces. Onlyapproximately1/3ofthenutrients inthefeedareremovedintheharvestofthefishand2/3voidedbyfishduringgrowth[71]. Uneaten feed, excreta, chemicals and therapeutics are retained in the waste produced by aquaculture.Wasteoriginatingfromthefeedincludesdissolvedcomponents(suchasphosphorus-and nitrogen-basednutrients)andsuspendedsolids[72]. Fishfoodandfaecesareknowntobethemain solidwasteinintensiveaquaculture. Thefaecalwastecanbecalculatedbytheproximatecomposition (reportedonfeedbaglabels)andbytheassociatedvaluesofdigestibility;indeed,theoverallfraction Water2017,9,13 9of17 offaecesproducedperunitoffeedconsumedisobtainedbysummingtheamountofallindigestible dietarycomponents. Theproductionoffeedwastessuchasdustanduneatenfoodhasbeenestimatedtobe20%[73], whereasotherauthors[74,75]haveproposedarangeof10%to30%ofwasterepresentedbyuneaten foodalonefromintensiveaquaculture. Throughameta-analysisofpublisheddatafromcommercial producersinBrazilonexpectedfeedintake,feedefficiencyandotheranimalproductionindicesand thebodycompositionoftilapia(O.niloticus),NetoandOstrensky[76]estimatedthat18%ofthefeed given to the animals is not consumed and is lost in the aquatic environment and accumulated in thesludge. According to Reid et al. [77], in the case of a common salmon feed, approximately 15% of consumedfeedbecomesdryfaecalmatter,whileButzandVens-Cappell[78]affirmedthatthefaecal inputis260gperkgoffoodonadryweightbasis. Themainphosphoruslossinfishisthroughfaeces. Highphosphoruslossthroughfaeceswasalso foundbyPettersson[79]inrainbowtroutandbyJohnsenetal.[80]inAtlanticsalmon(Salmosalar). Hakanson et al. [81] calculated that of the total phosphorus and nitrogen fed to fish, 70% of the phosphorus and 15% of the nitrogen is lost through faeces, whereas Kristiansen and Hessen [82] reported loss values of 4.0% for phosphorus and 2.3% for nitrogen in Atlantic salmon, and 3.5% for phosphorus and 4.1% for nitrogen in noble crayfish (Astacus astacus) faeces. In a recent paper, NetoandOstrensky[76]proposedthat17%ofthefeedinputfornitrogenand37%forphosphorus is lost as nutrients from the faeces in Nile tilapia reared in cages. Although the data of Neto and Ostrensky[76]werebasedoncagebreedingsystems, recentlyGoddeketal.[26]observedsimilar valuesinRAS.Certainly,thespeciesaffectstheentityoftheselosses,whichareaffectedalsobythe physiological stage within the species. Neto and Ostrensky [76] also found relevant variations in feedinglossesinrelationtotheageoftilapia—30.9%forfry,17.0%forjuveniles,17.6%forthegrowing phaseand16.7%attheslaughterstage. Over the last several years, the progress in fish nutrition research and in feed manufacturing for the most important aquacultured species has contributed to a significant reduction of waste. Theimprovedbio-availabilityofphosphorusandproteinsinthedietshassignificantlyreducedthe faecalsolidsproducedandimprovedthefeedefficiency[70]. Theadditionofdigestibilityenhancers inthefeed,suchasphytase,hasimprovedusabilityofphosphorusfromplantproteinsforfishandhas helpedtoreducethelossofnutrientsaswaste[83]. Thelabileformofphosphorusinthefaeces,aformreadilyavailabletoplantsfortheirgrowth[78], rangesfrom15%to54%[79,84]. ThequantityofPreleasedbysolidwastesislargelydependenton temperature(25◦C>20◦C)andpH(higherathigherpHvalues)[84]. Forthereductionofsolidwaste,theimportanceoffeedprocessingandproductionshouldnotbe underestimated. Feedmanufacturingprocessesaimtoimprovethenutritionalqualityofthedietsbut alsotoimprovethestabilityandintegrityofpellets,consequentlyreducingthepelletbreakdownin waterbeforeconsumptionbythefish. Throughthisdoubleapproach(dietformulationandfeedmanufacturing),feedingmanagement practiceshavemaximizedthefeedutilizationbyfishand,atthesametime,minimizedtheuneaten quantity of feed, achieving a more economical process because the economy and efficiency of the productionprocessarestrictlyconnected[85,86]. Theparticlesizeaffectstheratioofsettleabletosuspendedsolids[77]. Largerparticlesareless numerousbutoccupyalargervolume,whereassmallerparticlesaremorenumerousbutoccupyless volumeoverall. Buryniuketal.[87]foundastrictcorrelationbetweenfishsizeandthefaecalsize classes: faecesfrom1kgAtlanticsalmonwerenotcapturedonmeshopeningsover4mm,whilesome 10%–20%offaecesfrom5kgsalmoncouldbecapturedona25mmmesh. Variabilityinfaecalparticle sizesispositivelycorrelatedwithfishsize[87,88]. Magilletal.[89]foundthemeansizeofparticles ofseabream(Pagrusmajor)andseabass(Dicentrarchuslabrax)fedthesamediettorangefrom0.3 to2.5mm(1.4mmmean)andfrom0.3to6.2mm(1.12mmmean),respectively. Fishsizeandspecies
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