Period of incubation and posthatching holding time influence on broiler performance

Almeida, JG; Vieira, SL; Gallo, BB; Conde, ORA; Olmos, AR

doi:10.1590/S1516-635X2006000300003

Abstract

The present study had the objective of investigating the performance of broilers housed immediately after hatching or after a 12 or 24 hour of post-hatching holding time. One thousand and six hundred male Ross 308 broiler chicks with an initial body weight of 46 grams were used. These chicks were distributed in a completely randomized experimental design with 5 treatments and 8 replications of 35 birds in each treatment. The treatments in this study consisted of the removal of chicks from the hatchery in three different times: after 480, 492 and 504 hours of incubation. In each one of these times, 280 chicks were removed from the hatchery and immediately housed. Another group of an identical number of chicks of each time remained in the hatchery to be housed at 504 hours after hatching. The chick group corresponding to those hatched at 480 and 492 hours performed better until 7 days. However, no differences in body weight or body weight gain were observed at the end of the study. Feed efficiency, however was worse for the birds hatched and placed at 480 hours. There were no differences among treatments for mortality.

Post-hatch period; broiler performance; incubation period; hatchability

Period of incubation and posthatching holding time influence on broiler performance

Almeida JG; Vieira SL; Gallo BB; Conde ORA; Olmos AR

Department of Animal Science - Universidade Federal do Rio Grande do Sul

^{Mail Address} Mail Address: Jair Godoy de Almeida Av. Borges de Medeiros, 708/504; Centro 90.020-024. Porto Alegre, RS, Brasil Phone: 51 3225 25 27 Email: jair.godoy@ufrgs.br

ABSTRACT

The present study had the objective of investigating the performance of broilers housed immediately after hatching or after a 12 or 24 hour of post-hatching holding time. One thousand and six hundred male Ross 308 broiler chicks with an initial body weight of 46 grams were used. These chicks were distributed in a completely randomized experimental design with 5 treatments and 8 replications of 35 birds in each treatment. The treatments in this study consisted of the removal of chicks from the hatchery in three different times: after 480, 492 and 504 hours of incubation. In each one of these times, 280 chicks were removed from the hatchery and immediately housed. Another group of an identical number of chicks of each time remained in the hatchery to be housed at 504 hours after hatching. The chick group corresponding to those hatched at 480 and 492 hours performed better until 7 days. However, no differences in body weight or body weight gain were observed at the end of the study. Feed efficiency, however was worse for the birds hatched and placed at 480 hours. There were no differences among treatments for mortality.

Keywords: Post-hatch period, broiler performance, incubation period, hatchability.

INTRODUCTION

Broiler chicks hatch during a time interval of 480 to 510 hours (Vieira & Pophal, 2000). Therefore, a group of "day-old chicks" usually include birds with different ages. Factors, such as breeder age, time and temperature of fertile egg storage, incubation temperature, egg weight, season, and type of bird, influence total incubation time (Wilson, 1991).

Commercial hatcheries used incubation times of approximately 504 hours, which are considered optimal for the complete hatching of the incubated eggs. In this context, birds that hatch early remain for several hours without food or water before they are removed from the hatcher. However, this practice takes into consideration mainly the convenience of procedures inside commercial hatcheries. Halevy et al. (2000) showed that post-hatching fasting impairs weight gain and breast muscle deposition capacity. Also, the longer chicks remain in the hatcher after hatching, the worse is their performance (Fanguy et al., 1980). In this sense, Wyatt et al. (1985) observed that chicks that remained in hatching trays between 14 to 32 hours weighed 5 to 32% less as compared up to 7 hours, in average, after hatching. Nir & Levanon (1993) and Sklan et al. (2000) found lower losses, between 5 and 15%, and body weight reduction continued up to slaughter.

Hager & Beane (1983) and Baião & Cançado (1998) carried out experiments to evaluate the effects of maintaining chicks in the hatching chambers. Birds were removed from the hatcher after incubation periods between 486 and 522 hours. The first authors observed negative effects on the performance only in birds removed from the hatcher at 522 hours, and the latter did not find statistical differences on the live performance of broilers. On the other hand, Castell et al. (1994) found that the permanence of chicks in the hatcher for 24 hours after hatching improved weight gain at 21 days of age, but did not affect performance at 43 days. Contradictory results were found by Noy & Sklan (1999), who compared the performance of birds fed immediately after hatching with the performance of birds fed 34 hours later. These authors verified better performance for birds fed immediately after hatching; however, this better performance was only observed until birds were 21 days old. According to Newey et al. (1970), fasting after hatching lowers the capacity of the intestine to absorb amino acids and other nutrients when feed is supplied.

The period immediately after hatching is critical for the development of the immune and and gastrointestinal systems. During the first days of the bird's life, the small intestine grows five times faster than the body, and microvilli of the small intestine grow significantly faster in birds supplied with water and feed immediately after hatching (Dibner et al., 1998).

Bird performance during the first week of life has high correlation with its performance at market age (Nitsan, 1995). Therefore, all factors causing lower initial weight also tend to affect weight at market age.

This study aimed at evaluating the live performance of broiler chicks housed immediately after hatching at 480, 492, and 504 hours of incubation or after 504 hours in the hatcher.

MATERIAL AND METHODS

The present experiment was carried out at the Experimental Station of the Federal University of Rio Grande do Sul, located in Eldorado do Sul, RS, Brazil. A total number of 1,600 male Ross 308 broiler chicks, derived from 45-week-old breeders, were used. Chicks were weighed and distributed in pens in an experimental poultry house, using wood shavings as litter. The eggs, from which the broilers used in this experiment derived, were obtained in the same farm, and were laid on the same day. Eggs were incubated in a commercial hatchery in multiple-stage incubator.

Times for the removal of chicks from the hatcher were established to house the chicks at 480, 492, and 504 h. Therefore, chicks that completely hatched at 480 h were removed, than those that hatched between 480 and 492 h, and between 492 and 504 h. AT each removal time, chicks were immediately housed in the experimental facilities, and a second group consisting of birds hatched at the same time remained in the hatcher to be removed together with those housed at 504 h. the treatments consisted, therefore, of bords hatched and housed as follows: T1: (480-480) removed from the hatcher and housed at 480 h; T2: (492-492) removed from the hatcher and housed at 492 h; T3: (504-504) - removed from the hatcher and housed at 504 h; T4: (480-504) hatched at 480 h and removed for housing at 504 h; T5: (492-504) hatched at 492 h and removed for housing at 504 h.

Birds included in each hatching period were those which accumulated hatching until that determined number of hours of incubation. For statistical analysis purposes, "say one" was considered as the day of treatments "housed at 504 h of incubation. During the period of 1 to 41 days of age, birds were submitted to the traditional broiler management, and were fed with the same diets based on corn and soybean meal commonly used in this sector. Light regime was continuous, that is, 24 hours of continuous light. Water was supplied ad libitum since the birds were housed in the experimental farm. Birds were weighed at housing, and at 7, 14, 21, 28, 35, and 41 days of age, when feed intake, average weight gain, feed conversion ratio, and mortality rate. A completely randomized experimental design was used, consisting of five treatments with 8 replicates of 35 birds each.

Results were submitted to analysis of variance, and differences among means were submitted to the test of Tukey (p < 0.05).

RESULTS AND DISCUSSION

Performance results are presented in Tables 1, 2, 3, 4, and ⁵ . Table 1 showed that birds that remained for periods of 24 and 12 hours in the hatcher after hatching (480-504 and 492-504) lost 12.4 and 8.33 % of body weight as compared to those removed at the same moment or immediately housed (480-480 and 492-492). According to Pinchasov (1991), it is expected that birds loose weight during the first 24 hours after hatching, even if having free access to feed and water. This loss is associated to negative effects on subsequent performance (Hager & Beane, 1983, Halevy et at. 2000). The first week of the chick's life present a series of peculiarities that indicate that it is critical for its future performance.

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Due to the continuous pressure of genetic selection on muscle mass gain, the expected slaughter age has increasingly been reduced, and consequently the first days of the chick's life represent a increasing proportion of the total production time (Vieira & Moran, 1999). This evolution resulted in an increase in the proportion of the first week from 8 to 17% in the broiler's life (Gyles, 1989). During this stage, broilers present different digestive system anatomy and physiology, limiting nutritional requirements due to the difficulty to digest and to absorb nutrients, fast potential growth, and difficulty in ensuring survival in cold environments, as they require very hot environments to properly develop their potential (Penz & Vieira, 1998).

The results of the present study show better performance in terms of live weight and average and weight gain at 7 days of age for chicks removed from the hatcher at 480 and 492 h (Tables 1 and 2). These birds had higher weight gain, which negatively influenced feed conversion ratio (Tables 3 and 4). This negative performance continued for the complete experimental period only for birds housed at 480 hours.

The worse feed efficiency found in birds house early (480 hours) is not supported by literature. Published studies report higher intake for these birds, as well as higher weight gain, therefore, with no effect on feed conversion ratio, as well as no difference in these parameters.

Studies considering hatching day as "day one" usually report increasing feed intake as the interval between hatching and housing decrease. This is due to the fact that these birds, as they were housed earlier, had higher intake time as compared to birds housed after 24, 48, or more hours after hatching. This higher feed intake usually continues throughout the bird's life, not affecting feed conversion ratio as this increase is accompanied by higher weight gain (Wyatt et al., 1985; Pinchasov & Noy, 1993; Corless & Sell, 1999; Almeida, 2002; Gonzales et al., 2003; Pedroso et al., 2005). Other authors, such as Nir & Levanon (1993), Baião et al. (1998), and Vieira & Moran (1999), did not find feed intake and feed conversion ratio differences during any stage of the broiler's life.

As to live weight and average weight gain, responses decreased after the first week of life until no differences were found for the total experimental period. These results are intriguing and difficult to explain, as they are opposite to a physiological profile of the birds that presented better performance during the first week. Noy & Sklan (1999) found better performance in birds fed immediately after hatching as compared to those fed 34 hours later. Wyatt et al. (1986) observed superior performance during the entire experimental period for birds with a 12-hour interval between hatching and housing. According to Dibner (1998), one of the causes of this is an increase in the gastrointestinal surface area stimulated by early feeding. However, literature presents conflicting results as to this matter. Castell et al. (1994) and Cançado (1999) verified that the permanence of chicks for 24 hours in the hatcher after hatching was beneficial to performance up to 21 days of age.

Apparently, the conflict among these results may be related to the methodologies used to evaluate the results. Some studies consider the day the chicks are housed in the farm as their first day of life, regardless the interval between hatching and housing. Other studies, effective hatching time is considered as the first day of life. Chicks that have early access to water and feed have a competitive advantage as compared to birds that hatched later or took longer to be housed. In the present study, birds in treatment 1 (480-480) hatched and were housed 24 hours before birds in treatment 3 (504-504) and 12 hours before birds in treatment 2 (492-492). This longer period of intake is indubitably a competitive advantage. Therefore, at the time of first weighing, chicks had effectively 8 and 7.5 days of age, whereas treatment 3 birds had 7 days of age. This advantage was subject of interest in the present study as this could be translated in better performance.

It was also possible to observe that performance decreased as birds remained longer in the hatcher after hatching. These results were observed already at housing, with birds that remained for 12 and 24 hours in the hatcher for later housing (492-504 and 480-504) presently statistically worse performance as compared to the other treatments. This continued up to 21 days; however, no significant differences were found at 41 days.

The supply of feed and water immediately after hatching is beneficial for the development of the gastrointestinal tract (Nir, 1998). The gastrointestinal tract is immature at hatching, and feed intake is needed before intestine relative size and pancreatic enzyme production limit growth rates (Nir, 1998). It is during this phase that the relative growth rate is highest (Bjornhag, 1979), with an approximate four-fold increase of the housing weight at the end of the first week. After hatching, the gastrointestinal tract presents preferential growth relative to body muscle, and this growth occurs regardless the presence of feed or not, as yolk sac reserves are used for this purpose. The composition of the yolk sac is more favorable to cell membrane synthesis and maintenance of passive immunity than to the energy requirements. Therefore, it should be preserved for that purpose (Dibner et al. 1998).

In the present study, the estimated worse performance for birds fasted for 12 and 24 hours in hatcher was not confirmed. According to Handy et al. (1991), birds that remained for more than 12 h inside the hatcher after hatching are already subjected to stressing processes, due to the higher heat production and the excessive temperature in the hatcher. The birds respond with higher physiological release of corticosterone, which is already high in birds due to the normal hatching process. The permanence of high levels of this hormone reduced yolk sac absorption rate, leading to yolk sac malabsorption conditions. Under these circumstances, there is also high secretion of the hormone ACTH, which reduces bursal and spleen weights and blood protein levels, and increasing glycemia. These lead to decreased immunity and lower lung expansion post-hatch due to a lower production of surfactants. The result of all this can be observed from the second and third day of age, causing culling (Gustin, 2003).

Mortality data can be observed in ^{Table 5} . There was no statistical difference among treatments. These results are not consistent with the data of Vieira & Moran (1999), who showed that 24-hour delays in housing increased total mortality. However, it must be noted that this fasting period was measured in chicks that were outside the hatcher. Our findings on mortality agree with Almeida (2002), who did not find mortality differences at 21 days in birds housed after 48 hours fasting after removal from the hatcher.

CONCLUSIONS

1. Birds removed from the hatcher at 480 and 492 hours of incubation and immediately housed were heavier at 1 and 7 days of age. However, this superior performance was not after these ages;

2. Birds removed from the hatcher at 480 hours of incubation presented higher feed intake, which was not accompanied by higher weight gain, resulting in worse feed conversion ratio for the complete experimental period;

3. No differences in mortality were observed among treatments.

4. The results of the present study suggest that there is no advantage, in terms of performance, in removing birds from the hatcher for subsequent housing.

Arrived: April / 2005

Approved: May / 2006

Study received financial support of FAPERGS.

Almeida JG. Efeito do intervalo de tempo entre o nascimento e o alojamento no desempenho, características de carcaça e vísceras de frangos de corte provenientes de matrizes de diferentes idades [Dissertação]. Jaboticabal (SP): Universidade Estadual Paulista; 2002.
Baião NC, Cançado SV. Efeito do intervalo entre o nascimento e o alojamento de pintos sobre o desempenho dos frangos. Arquivos Brasileiro de Medicina Veterinária and Zootecnia, 1998; 50:191-194.
Baião NC, Rodriguez MF, Lúcio CG, Cançado SV. Efeito do período de jejum entre o nascimento e o alojamento de pintos sobre o desempenho do frango e a digestibilidade da ração. Arquivo Brasileiro de Medicina Veterinária and Zootecnia 1998; 50:321-327.
Bjornhag G. Growth in newly hatched birds. Swedish Journal of Agricultural Research 1979; 9:121-125.
Cançado SV. Efeito do intervalo de tempo entre o nascimento e o alojamento de pintos de corte sobre o desempenho, digestibilidade da ração, desenvolvimento do trato gastrointestinal e atividade da lipase [tese]. Belo Horizonte (MG): Universidade Federal de Minas Gerais; 1999.
Castell ET, Wilson JL, Buhr RJ. The influence of extended posthatch holding time and placement density on broiler performance. Poultry Science 1994; 73:1679-1684.
Corless AB, Sell JL. The effects of delayed access to feed and water on the physical and functional development of the digestive system of young turkeys. Poultry Science 1999; 78:1158-1169.
Dibner JJ, Knight CD, Kitchell ML, Atwell CA, Downs AC, Ivey FJ. Early feeding and the development of the immune system. Journal of Applied Poultry Research 1998; 7:425-436.
Fanguy RC, Misra LK, Vo KV. Effect of delayed placement on growth performance of commercial broilers. Poultry Science 1980; 59:1215-1220.
Gyles NR. Poultry, people and progress. Poultry Science 1989; 68:1-8.
Gonzales AND, Kondo N, Saldanha ESPB, Loddy MM, Careghi C, Decuypere AND. Performance and physiological parameters of broilers chickens subjected to fasting on the neonatal period. Poultry Science 2003; 82:1250-1256.
Gustin PC. Manejo do pinto no incubatório, expedição, transporte e alojamento na granja. In: Macari M, Gonzales E, editores. Manejo da incubação. Campinas: FACTA; 2003. p. 200-266.
Handy AMM, Henken AM, Vander Hel W. Effects of incubation humidity and hatching time on heat tolerance of neonatal chicks: Growth performance after heat exposure. Poultry Science 1991; 70:1507-1515.
Hager JE, Beane WL. Posthatch icubation time on early growth of broiler chicks. Poultry Science 1983; 62:247-254.
Halevy O, Geyra A, Barak M, Uni Z, Sklan D. Early posthatch starvation decreases satellite cell proliferation and skeletal muscle growth in chicks. Journal of Nutrition 2000; 82:858-864.
Newey H, Sanford PA, Smith DH. Effects of fasting on intestinal transfer of sugars and amino acids in vitro. Journal of Physiology 1970; 280:705-724.
Nir I. Mecanismos de digestão e absorção de nutrientes durante a primeira semana In: Conferência Apinco de Ciência e Tecnologia Avícolas; 1998; Campinas: FACTA; 1998. p.81-89.
Nir I, Levanon M. Effect of posthatch holding time performance and residual yolk and liver composition. Poultry Science 1993; 72: 1994-1997.
Nitsan Z. The development of digestive tract in posthached chicks. In: Proceedings of the 10^th European Symposium on Poultry Nutrition; 1995; Antalya: WPSA; 1995. p.21-28.
Noy Y, Sklan D. Energy utilization in newly hatched chicks. Poultry Science 1999; 78:1750-1756.
Pedroso AA, Stringhini JH, Leandro NSM, Xavier AS, Lima FG, Barbosa CE. Desempenho e biometria de órgãos digestórios de frangos provenientes de matrizes jovens após diferentes intervalos de alojamento. Revista Brasileira de Ciência Avícola 2005; 7 (3 supplemento 5).
Penz Jr AM, Vieira SL. Nutrição na primeira semana. Conferência Apinco de Ciência e Tecnologia Avícolas; 1998; Campinas: FACTA; 1998. p.121-139.
Pinchasov Y. Relationship between the weight of hatching eggs and subsequent early performance of broiler chicks. British Poultry Science 1991; 32:109-111.
Pinchasov Y, Noy Y. Comparison of post-hatch holding time and subsequent early performance of broiler chicks and turkey poults. British Poultry Science 1993; 34:110-120.
SAS. SAS user's guide: statistics. Cary: SAS Institute; 1998.
Vieira SL, Moran ET. Effects of delayed placement and used litter on broiler yields. Journal of Applied Poultry Research 1999; 8:75-81.
Vieira SL, Pophal S. Nutrição e pós-eclosão em frangos de corte. Revista Brasileira de Ciência Avícola 2000; 2:189-286.
Wilson HR. Interrelationships of egg size, chick size, posthatching growth and hatchability.World's Poultry Science Journal 1991; 47:5-20,1991.
Wyatt CL, Weaver WD, Beane WL. Influence of egg size, egg shell quality, and posthatch holding time on broiler performance. Poultry Science 1985; 64:2049-2055.
Wyatt CL, Weaver WD, Beane WL, Denbow DM, Gross WB. Influence of hatcher holding times on several physiological parameters associated with immune system of chickens. Poultry Science 1986; 65:2156-2164.

Mail Address:

Jair Godoy de Almeida

Av. Borges de Medeiros, 708/504; Centro

90.020-024. Porto Alegre, RS, Brasil

Phone: 51 3225 25 27

Email:

jair.godoy@ufrgs.br

Publication Dates

Publication in this collection
05 Mar 2007
Date of issue
Sept 2006

History

Received
Apr 2005
Accepted
May 2006

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] Almeida JG. Efeito do intervalo de tempo entre o nascimento e o alojamento no desempenho, características de carcaça e vísceras de frangos de corte provenientes de matrizes de diferentes idades [Dissertação]. Jaboticabal (SP): Universidade Estadual Paulista; 2002.

[2] Baião NC, Cançado SV. Efeito do intervalo entre o nascimento e o alojamento de pintos sobre o desempenho dos frangos. Arquivos Brasileiro de Medicina Veterinária and Zootecnia, 1998; 50:191-194.

[3] Baião NC, Rodriguez MF, Lúcio CG, Cançado SV. Efeito do período de jejum entre o nascimento e o alojamento de pintos sobre o desempenho do frango e a digestibilidade da ração. Arquivo Brasileiro de Medicina Veterinária and Zootecnia 1998; 50:321-327.

[4] Bjornhag G. Growth in newly hatched birds. Swedish Journal of Agricultural Research 1979; 9:121-125.

[5] Cançado SV. Efeito do intervalo de tempo entre o nascimento e o alojamento de pintos de corte sobre o desempenho, digestibilidade da ração, desenvolvimento do trato gastrointestinal e atividade da lipase [tese]. Belo Horizonte (MG): Universidade Federal de Minas Gerais; 1999.

[6] Castell ET, Wilson JL, Buhr RJ. The influence of extended posthatch holding time and placement density on broiler performance. Poultry Science 1994; 73:1679-1684.

[7] Corless AB, Sell JL. The effects of delayed access to feed and water on the physical and functional development of the digestive system of young turkeys. Poultry Science 1999; 78:1158-1169.

[8] Dibner JJ, Knight CD, Kitchell ML, Atwell CA, Downs AC, Ivey FJ. Early feeding and the development of the immune system. Journal of Applied Poultry Research 1998; 7:425-436.

[9] Fanguy RC, Misra LK, Vo KV. Effect of delayed placement on growth performance of commercial broilers. Poultry Science 1980; 59:1215-1220.

[10] Gyles NR. Poultry, people and progress. Poultry Science 1989; 68:1-8.

[11] Gonzales AND, Kondo N, Saldanha ESPB, Loddy MM, Careghi C, Decuypere AND. Performance and physiological parameters of broilers chickens subjected to fasting on the neonatal period. Poultry Science 2003; 82:1250-1256.

[12] Gustin PC. Manejo do pinto no incubatório, expedição, transporte e alojamento na granja. In: Macari M, Gonzales E, editores. Manejo da incubação. Campinas: FACTA; 2003. p. 200-266.

[13] Handy AMM, Henken AM, Vander Hel W. Effects of incubation humidity and hatching time on heat tolerance of neonatal chicks: Growth performance after heat exposure. Poultry Science 1991; 70:1507-1515.

[14] Hager JE, Beane WL. Posthatch icubation time on early growth of broiler chicks. Poultry Science 1983; 62:247-254.

[15] Halevy O, Geyra A, Barak M, Uni Z, Sklan D. Early posthatch starvation decreases satellite cell proliferation and skeletal muscle growth in chicks. Journal of Nutrition 2000; 82:858-864.

[16] Newey H, Sanford PA, Smith DH. Effects of fasting on intestinal transfer of sugars and amino acids in vitro. Journal of Physiology 1970; 280:705-724.

[17] Nir I. Mecanismos de digestão e absorção de nutrientes durante a primeira semana In: Conferência Apinco de Ciência e Tecnologia Avícolas; 1998; Campinas: FACTA; 1998. p.81-89.

[18] Nir I, Levanon M. Effect of posthatch holding time performance and residual yolk and liver composition. Poultry Science 1993; 72: 1994-1997.

[19] Nitsan Z. The development of digestive tract in posthached chicks. In: Proceedings of the 10^th European Symposium on Poultry Nutrition; 1995; Antalya: WPSA; 1995. p.21-28.

[20] Noy Y, Sklan D. Energy utilization in newly hatched chicks. Poultry Science 1999; 78:1750-1756.

[21] Pedroso AA, Stringhini JH, Leandro NSM, Xavier AS, Lima FG, Barbosa CE. Desempenho e biometria de órgãos digestórios de frangos provenientes de matrizes jovens após diferentes intervalos de alojamento. Revista Brasileira de Ciência Avícola 2005; 7 (3 supplemento 5).

[22] Penz Jr AM, Vieira SL. Nutrição na primeira semana. Conferência Apinco de Ciência e Tecnologia Avícolas; 1998; Campinas: FACTA; 1998. p.121-139.

[23] Pinchasov Y. Relationship between the weight of hatching eggs and subsequent early performance of broiler chicks. British Poultry Science 1991; 32:109-111.

[24] Pinchasov Y, Noy Y. Comparison of post-hatch holding time and subsequent early performance of broiler chicks and turkey poults. British Poultry Science 1993; 34:110-120.

[25] SAS. SAS user's guide: statistics. Cary: SAS Institute; 1998.

[26] Vieira SL, Moran ET. Effects of delayed placement and used litter on broiler yields. Journal of Applied Poultry Research 1999; 8:75-81.

[27] Vieira SL, Pophal S. Nutrição e pós-eclosão em frangos de corte. Revista Brasileira de Ciência Avícola 2000; 2:189-286.

[28] Wilson HR. Interrelationships of egg size, chick size, posthatching growth and hatchability.World's Poultry Science Journal 1991; 47:5-20,1991.

[29] Wyatt CL, Weaver WD, Beane WL. Influence of egg size, egg shell quality, and posthatch holding time on broiler performance. Poultry Science 1985; 64:2049-2055.

[30] Wyatt CL, Weaver WD, Beane WL, Denbow DM, Gross WB. Influence of hatcher holding times on several physiological parameters associated with immune system of chickens. Poultry Science 1986; 65:2156-2164.