[AAFCO(Associationof American Feed Control Officials)(2014). Dog and cat nutrient profiles. Official Publication of the Association of American Feed Control Officials Incorporated. Oxford.]Search in Google Scholar
[Ai H., Wang F., Zhang N., Zhang L., Lei C.(2013). Antiviral, immunomodulatory, and free radical scavenging activities of a protein-enriched fraction from the larvae of the housefly, Musca domestica. J. Insect Sci., 13: 1–16.]Search in Google Scholar
[AOAC(2006). Official Methods of Analysis, 17th ed. Association of Official Analytical Chemists. Arlington, VA.]Search in Google Scholar
[Awoniyi T.A.M., Adebayo I.A., Aletor V.A.(2004). A study of some erythrocyte indices and bacteriological analysis of broiler-chickens raised on maggot-meal based diets. Int. J. Poultry Sci., 3: 386–390.]Search in Google Scholar
[Baltacloglu E., Akalln F.A., Alver A., Deger O., Karabulut E.(2008). Protein carbonyl levels in serum and gingival crevicular fluid in patients with chronic periodontitis. Arch. Oral. Biol., 53: 716–722.]Search in Google Scholar
[Bosch G., Zhang S., Oonincx D.G., Hendriks W.H.(2014). Protein quality of insects as potential ingredients for dog and cat foods. J. Nutr. Sci., 3: 1–4.]Search in Google Scholar
[Bosch G., Vervoort J.J.M., Hendriks W.H.(2016). In vitro digestibility and fermentability of selected insects for dog foods. Anim. Feed Sci. T., 221: 174–184.]Search in Google Scholar
[Buddington R.K., Elnif J., Malo C., Donahoo J.B.(2003). Activities of gastric, pancreatic, and intestinal brush-border membrane enzymes during postnatal development of dogs. Am. J. Vet. Res., 64: 627–634.]Search in Google Scholar
[Callewaert L., Michiels C.W.(2010). Lysozymes in the animal kingdom. J. Biosci., 35: 127–160.]Search in Google Scholar
[Chen L., Zhang J., Sun H.(2015). Immunological adjuvant effect of the peptide fraction from the larvae of Musca domestica. BMC Complem. Altern. M., 15: 426–427.]Search in Google Scholar
[Cho S.H., Lee S.M.(2012). Onion powder in the diet of the olive flounder, Paralichthys olivaceus: effects on the growth, body composition, and lysozyme activity. J. World Aquacult. Soc., 43: 30–38.]Search in Google Scholar
[Chu F.J., Jin X.B., Xu Y.Y., Ma Y., Li X.B., Lu X.M., Zhu J.Y.(2013). Inflammatory regulation effect and action mechanism of anti-inflammatory effective parts of housefly (Musca domestica) larvae on atherosclerosis. Evid-Based Compl. Alt., 2013: 1–10.]Search in Google Scholar
[Dobenecker B., Endres V., Kienzle E.(2013). Energy requirements of puppies of two different breeds for ideal growth from weaning to 28 weeks of age. J. Anim. Physiol. An. N., 97: 190–196.]Search in Google Scholar
[Dong G.F., Yang Y.O., Song X.M., Yu L., Zhao T.T., Huang G.L., Hu Z.J., Zhang J.L.(2013). Comparative effects of dietary supplementation with maggot meal and soybean meal in gibel carp (Carassius auratus gibelio) and darkbarbel catfish (Pelteobagrus vachelli): growth performance and antioxidant responses. Aquacult. Nutr., 19: 543–554.]Search in Google Scholar
[Duwa H., Saleh B., Igwebuike J.U.(2014). The replacement of fish meal with maggot meal on the performance, carcass characteristic, hematological and serum biochemical indices of growing rabbits. J. Bio-Sci. Biotechnol., 3: 215–220.]Search in Google Scholar
[Esteban M.B., Garcia A.J., Ramos P., Marquez M.C.(2007). Evaluation of fruit-vegetable and fish wastes as alternative feedstuffs in pig diets. Waste Manage, 27: 193–200.]Search in Google Scholar
[Fasakin E.A., Balogun A.M., Ajayi O.O.(2003). Evaluation of full-fat and defatted maggot meals in the feeding of clariid catfish Clarias gariepinus fingerlings. Aquac. Res., 34: 733–738.]Search in Google Scholar
[Feng Y., Zhao M., He Z., Chen Z., Sun L.(2009). Research and utilization of medicinal insects in China. Entomol. Res., 39: 313–316.]Search in Google Scholar
[Gasco L., Finke M., Van Huis A.(2018). Can diets containing insects promote animal health? J. Insect Food Feed, 4: 1–4.]Search in Google Scholar
[Gessert C.F., Phillips P.H.(1956). Protein in the nutrition of the growing dog. J. Nutr., 58: 415–421.]Search in Google Scholar
[Ghosh J., Das J., Manna P., Sil P.C.(2008). Cytoprotective effect of arjunolic acid in response to sodium fluoride mediated oxidative stress and cell death via necrotic pathway. Toxicol. In Vitro, 22: 1918–1926.]Search in Google Scholar
[Gu L.J., Wu J.W., Su X.Q., Sung C.K.(2006). Isolation and purification of novel anti-fungal peptides from hemolymph of immunized larvae of housefly, Musca domestica. J. Life Sci., 16: 387–395.]Search in Google Scholar
[Hawthorne A.J., Booles D., Nugent P.A., Gettinby G., Wilkinson J.(2004). Bodyweight changes during growth in puppies of different breeds. J. Nutr., 134: 2027S–2030S.]Search in Google Scholar
[Hou L., Shi Y., Zhai P., Le G.(2007). Antibacterial activity and in vitro anti-tumor activity of the extract of the larvae of the housefly (Musca domestica). J. Ethnopharmacol., 111: 227–231.]Search in Google Scholar
[Hughes J., Macdonald D.W.(2013). A review of the interactions between free-roaming domestic dogs and wildlife. Biol. Conserv., 157: 341–351.]Search in Google Scholar
[Hussein M., Pillai V.V., Goddard J.M., Park H.G., Kothapalli K.S., Ross D.A., Ketterings Q.M., Brenna J.T., Milstein M.B., Marquis H., Johnson P.A., Nyrop J.P., Selvaraj V.(2017). Sustainable production of housefly (Musca domestica) larvae as a proteinrich feed ingredient by utilizing cattle manure. PloS One, 12: 171–178.]Search in Google Scholar
[Hwangbo J., Hong E.C., Jang A., Kang H.K., Oh J.S., Kim B.W., Park B.S.(2009). Utilization of house fly-maggots, a feed supplement in the production of broiler chickens. J. Environ. Biol., 30: 609–614.]Search in Google Scholar
[Ido A., Iwai T., Ito K., Ohta T., Mizushige T., Kishida T., Miura T.(2015). Dietary effects of housefly (Musca domestica) (Diptera: Muscidae) pupae on the growth performance and the resistance against bacterial pathogen in red sea bream (Pagrus major) (Perciformes: Sparidae). Appl. Entomol. Zool., 50: 213–221.]Search in Google Scholar
[Iheukwumere F., Ndubuisi E., Kalajaye M.(2009). Erythrocyte indices and serum biochemical constituents of broiler chicken fed maggot meal diets. Int. J. Nat. Appl. Sci., 5: 107–115.]Search in Google Scholar
[Jiang S.J.(1999). Chinese pharmaceutical insects (in Chinese). Chinese Forestry Publishing House. Beijing, China, pp. 266–268.]Search in Google Scholar
[Kerr K.R., Beloshapka A.N., Morris C.L., Parsons C.M., Bureke S.L., Utterback P.L., Swanson K.S.(2013). Evaluation of four raw meat diets using domestic cats, captive exotic felids, and cecetomized roosters. J. Anim. Sci., 91: 225–237.]Search in Google Scholar
[Khan S., Khan R.U., Sultan A., Khan M., Hayat S.U., Shahid M.S.(2016). Evaluating the suitability of maggot meal as a partial substitute of soybean on the productive traits, digestibility indices and organoleptic properties of broiler meat. J. Anim. Physiol. Anim. Nutr. (Berl.), 100: 649–656.]Search in Google Scholar
[Khoo C., Cunnick J., Friesen K., Gross K.L., Wedekind K., Jewell D.E.(2005). The role of supplementary dietary antioxidants on immune response in puppies. Vet. Ther., 6: 43–56.]Search in Google Scholar
[Kierończyk B., Rawski M., Pawełczyk P., Rozynska J., Golusik J., Mikolajczak Z., Jozefiak D.(2018). Do insects smell attractive to dogs? A comparison of dog reactions to insects and commercial feed aromas – a preliminary study. Ann. Anim. Sci., 18: 795–800.]Search in Google Scholar
[Lei X.J., Kim T.H., Park J.H., Kim I.H.(2019). Evaluation of supplementation of defatted black soldier fly (Hermetia illucens) larvae meal in beagle dogs. Ann. Anim. Sci., 19: 767–777.]Search in Google Scholar
[Li H., Inoue A., Taniguchi S., Yukutake T., Suyama K., Nose T., Maeda I.(2017). Multifunctional biological activities of water extract of housefly larvae (Musca domestica). Pharma Nutr., 5: 119–126.]Search in Google Scholar
[Li X., Rahimnejad S., Wang L., Lu K., Song K., Zhang C.(2019). Substituting fish meal with housefly (Musca domestica) maggot meal in diets for bullfrog Rana (Lithobates) catesbeiana: Effects on growth, digestive enzymes activity, antioxidant capacity and gut health. Aquaculture, 499: 295–305.]Search in Google Scholar
[Lin Y.H., Mui J.J.(2017). Evaluation of dietary inclusion of housefly maggot (Musca domestica) meal on growth, fillet composition and physiological responses for barramundi, Lates calcarifer. Aquac. Res., 48: 2478–2485.]Search in Google Scholar
[Lisenko K., Godoy M., Oliveira M., Silva T., Fontes T., Costa D., Saad F.(2018). PSXIII-26 Compositional analysis and effects of dietary supplementation of insect meals on nutrient digestibility and gut health of adult dogs. J. Anim. Sci., 96:158–159.]Search in Google Scholar
[Marcel B.K.G., AndréK.B., Augustin A.K., Gaboued K.K., Seraphin K.(2011). Incorporation of a dried maggots’ meal in growing rats diets: pathological risks? Int. J. Biosci., 1: 65–70.]Search in Google Scholar
[Mbiba H.F., Etchu K.A., Ndamukong K.(2019). Carcass characteristics, haematology, serum chemistry and enzymes in broiler chickens fed maggot meal as a protein substitute for fishmeal. Global J. Medic. Res., 19: 1–8.]Search in Google Scholar
[NRC(1985). The Nutrient Requirements of the Dogs. Natl. Acad. Press. USA, pp. 2–41.]Search in Google Scholar
[NRC(2006). The Nutrient Requirements of the Dogs. Natl. Acad. Press. USA, pp. 329–335.]Search in Google Scholar
[Odesanya B.O., Ajayi S.O., Agbaogun B.K.O., Okuneye B.(2011). Comparative evaluation of nutritive value of maggots. Int. J. Eng. Res. Gen. Sci., 2: 1–5.]Search in Google Scholar
[Ogunji J.O., Nimptsch J., Wiegand C., Schulz C.(2007). Evaluation of the influence of housefly maggot meal (magmeal) diets on catalase, glutathione S-transferase and glycogen concentration in the liver of Oreochromis niloticus fingerling. Comp. Biochem. Phys. A., 147: 942–947.]Search in Google Scholar
[Ogunji J.O., Kloas W., Wirth M., Neumann N., Pietsch C.(2008). Effect of housefly maggot meal (magmeal) diets on the performance, concentration of plasma glucose, cortisol and blood characteristics of Oreochromis niloticus fingerlings. J. Anim. Physiol. Anim. Nutr. (Berl.), 92: 511–518.]Search in Google Scholar
[Okore O.O.(2016). Growth and haematological studies of African catfish (Clarias gariepinus) juveniles fed with housefly larva (Musca dometica) as feed supplement. Inter. J. Agric. Earth Sci., 2: 21–30.]Search in Google Scholar
[Pei M.T., Yang C., Yang D.Q., Yi T.L.(2019). Effects of housefly maggot meal and earthworms on growth and immunity of the Asian swamp eel Monopterus albus. Israeli J. Aquacult. Bamidgeh, 71: 1–8.]Search in Google Scholar
[Ratcliffe N.A., Mello C.B., Garcia E.S., Butt T.M., Azambuja P.(2011). Insect natural products and processes: new treatments for human disease. Insect Biochem. Mol. Biol., 41: 747–769.]Search in Google Scholar
[Rørtveit R., Sævik B.K., Eggertsdóttir A.V., Skancke E., Lingaas F., Thoresen S.I., Jansen J.H.(2015). Age-related changes in hematologic and serum biochemical variables in dogs aged 16–60 days. Vet. Clin. Path., 44: 47–57.]Search in Google Scholar
[Saleh H.H.E., Allam S.M., Abou-Zied R.M., Mohammed R.A., Aljilany S.S.A.(2016). Effect of diet type and stocking density on growth performance and blood parameters of the Egyptian sole (Solea aegyptiaca Chabanaud, 1927). Abbassa. Int. J. Aqua., 9: 84–134.]Search in Google Scholar
[Sánchez-Muros M.J., Barroso F.G., Manzano-Agugliaro F.(2014). Insect meal as renewable source of food for animal feeding: a review. J. Clean Prod., 65: 16–27.]Search in Google Scholar
[Satyaraj E., Reynolds A., Pelker R., Labuda J., Zhang P.F., Sun P.C.(2013). Supplementation of diets with bovine colostrum influences immune function in dogs. Brit. J. Nutr., 110: 2216–2221.]Search in Google Scholar
[Storz G., Imlayt J.A.(1999). Oxidative stress. Curr. Opin. Microbiol., 2: 188–194.]Search in Google Scholar
[Teotia J.S., Miller B.F.(1973). Fly pupae as a dietary ingredient for starting chicks. Poultry Sci., 52: 1830–1835.]Search in Google Scholar
[Wang F., Ai H., Lei C.(2013). In vitro anti-influenza activity of a protein-enriched fraction from larvae of the housefly (Musca domestica). Pharm. Biol., 51: 405–410.]Search in Google Scholar
[Wang L., Li J., Jin J.N., Zhu F., Roffeis M., Zhang X.Z.(2017). A comprehensive evaluation of replacing fishmeal with housefly (Musca domestica) maggot meal in the diet of Nile tilapia (Oreochromis niloticus): growth performance, flesh quality, innate immunity and water environment. Aquacult. Nutr., 23: 983–993.]Search in Google Scholar
[Xiang J., Qin L., Zhao D., Xiong F., Wang G., Zou H., Wu S.(2019). Growth performance, immunity and intestinal microbiota of swamp eel (Monopterus albus) fed a diet supplemented with house fly larvae (Musca domestica). Aquacult. Nutr., https://doi.org/10.1111/anu.1302910.1111/anu.13029]Search in Google Scholar
[Zhang H., Wang P., Zhang A.J., Li X., Zhang J.H., Qin Q.L., Wu Y.J.(2016). Antioxidant activities of protein hydrolysates obtained from the housefly larvae. Acta. Biol. Hung., 67: 236–246.]Search in Google Scholar
[Zhang X.D., Zhu Y.F., Cai L.S., Wu T.X.(2008). Effects of fasting on the meat quality and antioxidant defenses of market-size farmed large yellow croaker (Pseudosciaena crocea). Aquaculture, 280: 136–139.]Search in Google Scholar
