Comparison of the Growth Curve Models on Live Weights in Terms of Different Environmental Factors in Awassi Lambs
الموضوعات :
H. Hızlı
1
(Eastern Mediterranean Agricultural Research Institute, Yüreğir, Adana, Turkey)
E. Yazgan
2
(Eastern Mediterranean Agricultural Research Institute, Yüreğir, Adana, Turkey)
الکلمات المفتاحية: body weight, growth curve, nonlinear model, Awassi, Gompertz model Logistic model,
ملخص المقالة :
In this study, it was aimed to model the growth curves of Awassi lambs in terms of live weight-age relationships and macro environmental factors such as sex, birth type, year, month, and dam age, as well as to determine a nonlinear model that explains the growth curves better. For this purpose, Gompertz and Logistics were used. The data set of the study comprised of the 3523 Awassi lambs’ live weights obtained at 10, 20, 30, 50, 60, 90, and 120th days of age. In order to compare both models, the coefficient of adjusted determination (R2adj) and the mean squared error (MSE) were used as the goodness of fit criteria. For the Gompertz and Logistics models, Gompertz model has the lowest MSE in all of macro environmental factors. While the estimated mean and standard errors of the asymptotic weight (A), the constant of integration (B), and growth rate (k) parameters were found respectively as 54.13 ± 0.59, 2.56 ± 0.008, and 0.01 ± 0.0001 for the Gompertz model, they were found respectively as 37.47 ± 0.18, 7.30 ± 0.03 and 0.03 ± 0.0001 for the Logistic model. For the Gompertz and Logistic models, age at inflection point (AIP), weight at inflection point (WIP) and maximal increment (MI) were found to be 5.55, 19.92, 51.00 and 66.26, 18.74, 68.40, respectively. In addition, correlations between model parameters (rAB, rAk, rBk) were found as 0.86, -0.98, -0.75 and 0.45, -0.91, -0.08 respectively for the Gompertz and Logistics models.The model that better described the growth of Awassi lambs in terms of MSE, AIP, WIP, MI and rAB, rAk, rBk values were found as the Gompertz growth model.
Akbaş Y. (1995). Büyüme eğrisi modellerinin karşılaştırılması. Hay. Ür. Der. 36, 73-80.
Akbaş Y. (1996). Büyüme eğrisi parametreleri ve ıslah kriteri olarak kullanımı olanakları. Ege Üniv. Ziraat Fak. Derg. 33(1), 241-248.
Akbaş Y., Taşkın T. and Demirören E. (1999). Farklı modellerin Kıvırcık ve Dağlıç erkek kuzularının büyüme eğrilerine uyumunun karşılaştırılması. Turkish J. Vet. Anim. Sci. 23(3), 537-544.
Aktaş A.H. and Doğan Ş. (2014). Effect of live weight and age of Akkaraman ewesat mating on multiple birth rate, growth traits, and survival rate of lambs. Turkish J. Vet. Anim. Sci. 38, 176-182.
Aytekin R.G. and Zulkadir U. (2013). Malya koyunlarında sütten kesim ile ergin yaş arası dönemde büyüme eğrisi modellerinin belirlenmesi. Tar. Bil. Derg. 19, 71-78.
Aytekin R.G., Zulkadir U., Keskin İ. and Boztepe S. (2011). Fitting of different mathematic models to the growth curves of female malya lambs weaned at two different live weights, trends. Anim. Vet. Sci. J. 1(2), 19-23.
Balafrej M. (2019). Determination of a new characterization point for nonlinear mathematical models applied to sheep. Int. J. Syst. Sci. Appl. Math. 4(3), 38-46.
Bayram B. and Akbulut Ö. (2009). Esmer ve siyah alaca sığırlarda büyüme eğrilerinin doğrusal ve doğrusal olmayan modellerle analizi. Hayvan. Üret. 50(2), 33-40.
Bhadula S.K. and Bhat P.N. (1980). Note on growth curves in sheep growth curves in sheep. Indian J. Anim. Sci. 50(11), 1001-1003.
Bilgin Ö.C. and Esenbuğa N. (2003). Doğrusal-olmayan büyüme modellerinde parametre tahmini. Hayvan. Üret. 44(2), 81-90.
Bilgin Ö.C., Esenbuğa N., Macit M. and Karaoğlu M. (2004a). Growth curve characteristics in Awassi and Morkaraman sheep, part I: Comparison of nonlinear functions. Wool Technol. Sheep Breed. 52 (1), 1-7.
Bilgin Ö.C., Emsen E. and Davis M.E. (2004b). Comprasion of non-linear models for describing the growth of scrotal circumferance in Awassi male lambs. Small Rumin. Res. 52, 155-160.
Bilgin Ö.C., Esenbuğa N., Macit M. and Karaoğlu M. (2004c). Growth curve characteristics in Awassi and Morkaraman sheep: II. Genetic and environment aspect. J. Appl. Anim. Res. 26, 7-12.
Brown J.E., Fitzhugh H.A. and Cartwright T.C. (1976). A comparison of nonlinear models for describing weight-age relationships in cattle. J. Anim. Sci. 42(4), 810-818.
Çelikoğlu K. and Tekerli M. (2014). Pırlak kuzularda farklı büyüme eğrisi modellerinin vücut ölçülerine uyumunun karşılaştırılması. Lalahan Hay. Araşt. Enst. Derg. 54(2), 63-69.
Efe E. (1990). Büyüme eğrileri. Ph D. Çukurova Üniversitesi Fen Bilimleri Enstitüsü, Adana, Turkey.
Esenbuğa N., Bilgin Ö.C., Macit M. and Karaoğlu M. (2000). Awassi, Morkaraman ve Tuj kuzularında büyüme eğrileri. Atatürk Ü. Zir. Fak. Derg. 31, 37-41.
Fatten A.M. (2015). Comparison of three nonlinear functions for describing chicken growth curves. Sci. Agric. 9(3), 120-123.
Fekedulegn D., Mac Siurtain M.P. and Colbert J.J. (1999). Parameter estimation of nonlinear growth models in forestry. Silva Fenn. 33(4), 327-336.
Gamasaee V.A., Hafezian S.A., Ahmadi A., Baneh H., Farhadi A. and Mohamadi A. (2010). Estimation of genetic paramaters for body weight and different ages in Mehraban sheep. African J. Biotechnol. 9(32), 5218-5223.
Genç S. and Soysal M.I. (2018). Parametric and nonparametric post hoc tests. BSJ Eng Sci. 1(1), 18-27.
Ghaderi-Zefrehei M., Rafeie F., Bahreini-Behzadi M.Z., Nazarı S., Muhaghegh-Dolatabady M., Samadian F., Maxwell T.M.R. and Amirpour Najafabadi H. (2018). Simple hierarchical and general nonlinear growth modeling in sheep. Turkish J. Vet. Anim. Sci. 42, 326-334.
Guatam L., Kumar V.., Waiz H.A. and Nagda R.K. (2018). Estimation of growth curve parameters using non-linear growth curve models in sonadi sheep. Int. J. Livest. Res. 8, 104-113.
Hojjati F. and Hossein G.Z.N. (2018). Comparison of non-linear growth models to describe the growth curve of Mehraban sheep. J. Appl. Anim. Res. 46(1), 499-504.
Hyankova L., Knizetova H., Dedkova L. and Hort J. (2001). Divergent selection for shape of growth curve in Japanese quail. 1. Responses in growth parameters and food conversion. British Poult. Sci. 42(5), 583-589.
IBM Corp. (2011). Released IBM SPSS Statistics for Windows. Version 20.0. Armonk, New York.
Keskin I. and Dag B. (2006). Comparison of the linear and quadratic models for describing the growth of live weight and body measurements in anatolian merino male lambs in fattening period. J. Anim. Vet. Adv. 5(1), 81-84.
Koncagül S., Vural M.E., Karataş A., Akça N. and Bingöl M. (2013). Reproductive performance of ewes and growth characteristics of lambs in Zom sheep reared in Karacadağ District. Kafkas Univ. Vet. Fak. Derg. 19, 63-68.
Kshirsagar A.M. and Smith W.B. (1995). Growth Curves. Marcel Dekker, New York.
Kutluca K.M. and Emsen E. (2016). Growth and reproductive traits of purebred and crossbred Romanov lambs in Eastern Anatolia. Anim. Reprod. 13(1), 3-6.
Kuzu E. and Eliçin A. (2002). Kilis keçisi oğlaklarında değişik vücut ölçüleri bakımından büyüme eğrileri. Ankara Üniv. Ziraat Fak. Derg. 8(3), 242-247.
Lalit Malik Z.S., Dalal D.S., Dahiya S.P., Patil C.S. and Dahiya R. (2016). Genetic analysis of growth traits in Harnali sheep. Vet. World. 9(2), 128-132.
Mignon-Grasteau S., Piles M., Varona L., Rochambeau H., Poıvey J.P., Blasco A. and Beaumont C. (2000). Genetic analysis of growth curve parameters for male and female chickens resulting from selection on shape of growht curve. J. Anim. Sci. 78, 2515-2524.
Mohammadi Y., Mokhtari M.S., Saghi D.A. and Shahdadi A.R. (2019). Modeling the growth curve in Kordi sheep: The comparison of non-linear models and estimation of genetic parameters for the growth curve traits. Small Rumin. Res. 177, 117-123.
Oda V., Korkmaz M. and Özkurt E. (2016). Büyüme eğrilerinin tahmininde kullanılan bazı sigmoidal modeller ve elde edilen biyolojik parametreler: Bertalanffy modeli örneği. Ordu Üniv. Bil. Tek. Derg. 6(1), 54-66.
Owens F.N., Dubeski P. and Hanson C.F. (1993). Factors that alter growth and development of ruminants. J. Anim. Sci. 71(11), 3138-3150.
Paz C.P., Venturini G.C., Contini E., Costa R.L.D., Lameirinha L.P. and Quirino C.R. (2018). Nonlinear models of Brazilian sheep in adjustment of growth curves. Czech J. Anim. Sci. 63, 331-338.
Perotto D., Cue R.I. and Lee A.J. (1992). Comparison of nonlinear functions for describing the growth curve of three genotypes of dairy cattle. Canadian J. Anim. Sci. 72, 773-782.
Pham H. (2019). A New Criterion for Model Selection, Mathematics. Mathematics. 7(12), 1215-1225.
Ratkowsky D.A. (1983). Nonlinear Regression Modelling. Marcel Dekker. New York.
Richards F.J. (1959). A flexible growth function for empirical use. J. Exp. Bot. 10, 290-301.
Saghi D.A., Khadivi H., Navidzadeh M. and Nikbakhti M. (2007). Study on influence of environmental effect on birth weight, weaning weight and daily growth of Baluchi sheep. Pakistan J. Nutr. 6, 436-437.
Şahin A., Ulutaş Z., Karadavut U., Yıldırım A. and Arslan S. (2014). Anadolu mandası malaklarında büyüme eğrisinin çeşitli doğrusal olmayan modeller kullanılarak karşılaştırılması. Kafkas Univ. Vet. Fak. Derg. 20(3), 357-362.
Sariyel V., Aygun A. and Keskin I. (2017). Comparison of growth curve models in partridge. Poult Sci. 96(6), 1635-1640.
Sengul T. and Kiraz S. (2005). Non-linear models for growth curves in large white turkeys. Turkish J. Vet. Anim. Sci. 29, 331-337.
Soysal M.I., Uğur F., Gürcan K. and Bağcı H. (2001). Siyah alaca sığırlarda canlı ağırlık ve çeşitli vücut ölçüleri ile yaş ilişkisinin bazı doğrusal ve doğrusal olmayan denklemlerinin açıklanması üzerine bir araştırma. Trakya Üniv. Ziraat Fak. Derg. 1(1), 33-39.
Tahtali Y., Sahin M. and Bayyurt L. (2020). Comparison of different growth curve models in Romanov lambs. Kafkas Univ. Vet. Fak. Derg. 26(5), 609-615.
Tekel N., Şireli H.D., Eliçin M. and Eliçin A. (2005). Comparison of growth curve models on Awassi lambs. Indian Vet. J. 82, 179-182.
Thieme O., Karazeybek M., Azman M.A. and Ugurlu A. (1999). Performance of village sheep flocks in Central Anatolia. I. Growth of lambs. Turkish J. Vet. Anim. Sci. 23, 467-474.
Topal M., Özdemir M., Aksakal V., Yıldız N. and Doğru U. (2004). Determination of the best nonlinear function in order to estimate growth in Morkaraman and Awassi lambs. Small Rumin. Res. 55, 229-232.
Trenkle A. and Marple D.N. (1983). Growth and development of meat animals. J. Anim. Sci. 57(2), 273-282.
Van der Merwe D.A., Brand T.S. and Hoffman L.C. (2019). Application of growth models to different sheep breed types in South Africa. Small Rumin. Res. 178, 70-78.
Wilson R.T., Peacock C. and Sayers A.R. (1982). Livestock production on Masai group Ranches. 2. Growth and liveweight in goats and sheep at Elangata Wuas and the factors influencing them. J. Agric. Rural Dev. Trop. 21, 191-198.
Yakupoğlu Ç. and Atıl H. (2001). Comparison of growth curve models on broilers. II. Comparison of models. J. Biological. Sci. 1(7), 682-684.
Yıldız G., Soysal M.I. and Gürcan E.K. (2009). Tekirdağ ilinde yetiştirilen Karacabey Merinosu × Kıvırcık melezi kuzularda büyüme eğrisinin farklı modellerle belirlenmesi. Tekirdağ Ziraat Fak. Derg. 6(1), 11-19.
Yılmaz A., Karakus F., Bingöl M., Kaki B. and Ser G. (2017). Effects of some factors on growth of lambs and the determination of growth curve models. Indian J. Anim. Res. 52(9), 1257-1262.
Zimmermann M.J., Kuehn L.A., Spangler M.L., Thallman R.M., Snelling W.M. and Lewis R.M. (2019). Comparison of different functions to describe growth from weaning to maturity in crossbred beef cattle. J. Anim. Sci. 97(4), 1523-1533.
