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Effects of calcium levels and limestone particle size on the egg quality of semi-heavy layers in their second production cycle

Abstract

A 112-day trial was carried out to evaluate the effect of dietary calcium level and limestone particle size on the egg quality of 288 Hy-Line Brown semi-heavy layers, with 83 weeks of age at the beginning of the experiment. A completely randomized experimental design was applied in a 2x3 factorial arrangement, with two dietary calcium levels (3.5 and 4.0%) e three limestone particle size compositions (100% fine limestone (FL), with 0.185mm; 30% coarse limestone (CL), with 2.83mm, + 70% FL, with 0.185mm; and 50% CL, with 2.83mm, + 50% FL, with 0.185mm), with six replicates of eight birds each. Mean geometric diameter and in-vitro solubility of the limestone sources were, respectively, 0.185mm and 18.7% for the fine limestone, and 2.83mm and 10.5% for the coarse limestone. At the end of each 28-day period, 72 eggs per treatment were used to determine egg specific gravity, yolk percentage, albumen percentage, eggshell percentage, yolk index, Haugh units, eggshell thickness, and eggshell breaking strength. There was no influence of the treatments on the evaluated parameters. It was concluded that feeding the level of 3.5% calcium usually recommended for layers in their first laying cycle, and the substitution of up to 50% fine limestone by coarse limestone in the feed of semi-heavy commercial Hy-Line Brown layers in their second laying cycle can be applied with no impairment of egg quality.

Eggs; eggshell quality; layers; levels; minerals


Effects of calcium levels and limestone particle size on the egg quality of semi-heavy layers in their second production cycle

Pizzolante CC; Saldanha ESPB; Laganá C; Kakimoto SK; Togashi CK

Pesquisadores Científicos da Agência Paulista de Tecnologia dos Agronegócios Regional (APTA) da Secretaria de Agricultura e Abastecimento do Estado de São Paulo (SAA)

Mail Address Mail Address: Agência Paulista de Tecnologia dos Agronegócios Regional (APTA) Caixa Postal 09 17.380-000. Brotas, SP, Brasil. E-mail: ccp@apta.sp.gov.br

ABSTRACT

A 112-day trial was carried out to evaluate the effect of dietary calcium level and limestone particle size on the egg quality of 288 Hy-Line Brown semi-heavy layers, with 83 weeks of age at the beginning of the experiment. A completely randomized experimental design was applied in a 2x3 factorial arrangement, with two dietary calcium levels (3.5 and 4.0%) e three limestone particle size compositions (100% fine limestone (FL), with 0.185mm; 30% coarse limestone (CL), with 2.83mm, + 70% FL, with 0.185mm; and 50% CL, with 2.83mm, + 50% FL, with 0.185mm), with six replicates of eight birds each. Mean geometric diameter and in-vitro solubility of the limestone sources were, respectively, 0.185mm and 18.7% for the fine limestone, and 2.83mm and 10.5% for the coarse limestone. At the end of each 28-day period, 72 eggs per treatment were used to determine egg specific gravity, yolk percentage, albumen percentage, eggshell percentage, yolk index, Haugh units, eggshell thickness, and eggshell breaking strength. There was no influence of the treatments on the evaluated parameters. It was concluded that feeding the level of 3.5% calcium usually recommended for layers in their first laying cycle, and the substitution of up to 50% fine limestone by coarse limestone in the feed of semi-heavy commercial Hy-Line Brown layers in their second laying cycle can be applied with no impairment of egg quality.

Keywords: Eggs, eggshell quality, layers, levels, minerals.

INTRODUCTION

From the commercial perspective, the main function of the eggshell is of a package to protect the noble content of the egg (yolk and albumen) against losses and environmental aggression. The eggshell must be strong enough to resist the processes of lay, collection, grading, and transport, reaching the final consumer intact (Kussakawa et al., 1998).

Egg formation is a dynamic biological process that takes 24 to 36 hours, out of which 20 are required to form the eggshell after the egg reaches the eggshell gland (Swenson & Reece, 1996). Eggshell defects include cracks, deformities, and irregular calcium deposition, in addition to invisible microbial contamination, resulting in economic losses.

Modern layer breeds have high egg production and low body weight in the first laying cycle. Second-cycle layers produce large and extra-large eggs, and present a higher percentage of thin eggshells due to disorders associated to calcium and vitamin D3 metabolism (Elaroussi et al., 1994).

Swanson & Johnson (1973) reported that the larger the egg, the higher the probability of breaking, and that, as layers age, they lay larger eggs with lower eggshell calcium deposition, which decreases eggshell quality.

Mazzuco & Hester (2005) explained that, with aging, hormones that are essential for reproduction, such estrogens, and their receptors decline, resulting in lower calcium absorption capacity by the gastrointestinal tract and renal tubules, as well as lower calcium transference from the uterus for eggshell formation. Thinner eggshells and simultaneous increase tibial mineralization are also observed, indicating failure in the mechanisms in calcium mobilization by layers at the end of lay.

Laying birds have high calcium requirements for bone maintenance and eggshell deposition, which are supplied by adequate and available calcium dietary sources. The knowledge calcium requirements for eggshell formation is essential, and the levels required after molting recommended in literature are still controversial (Rodrigues, 1995). Excessive dietary calcium interferes with the availability of other minerals, such as phosphorus, magnesium, manganese, and zinc (Borges, 1999). Studies on optimal calcium levels in layer diets are economically important, contributing to minimize broken eggshell percentage, production costs, and environmental impacts (Oliveira et al., 2002).

Several studies have been carried out to evaluate calcium sources, particle size, and solubility (Bertechini & Fassani, 2001, Ito, 2002, Jardim Filho et al., 2005a, Geraldo et al., 2006). The results indicate that calcium must be supplemented with sources that have larger particles sizes and are less dusty as compared to standard limestone, particularly during the final stage of the laying cycle, to improve eggshell quality and the skeleton of modern layers.

Roland (1986), quoted by Faria et al. (2000), published a review on this subject, comparing 44 studies published between 1921 and 1985. That author verified that most results show that replacement of fine particles of calcium carbonate by coarse particles (oyster shell meal or limestone) improve eggshell quality. Coarser particles are efficient when layer are fed inadequate calcium levels or are exposed to factors that reduce its utilization. Therefore, coarser particles can be recommended under field conditions, provided their solubility is taken into account.

Rao & Roland (1990) fed layers with 3.0, 4.5, and 6.0% limestone with two different particle sizes (fine limestone between 0.5 and 0.8 mm, and coarse limestone between 2 and 4 mm), and observed lower calcium solubility and retention when calcium levels increased. Layers fed coarse limestone presented higher calcium retention, showing that particle size and calcium level influence calcium solubility in the digestive tract.

Roland (1984), Leeson & Summers (1997), Miles (2000), and Bertechini (2006) showed that oyster shell in coarse particles improved eggshell quality due to its lower solubility and slow release during the night, when eggshell is formed.

Cheng & Coon (1990a) evaluated different limestone sources, dietary levels, and particle sizes, and concluded that the applied treatments did not affect egg production or weight, but influenced eggshell quality. Those authors suggested mixing limestone with different particle sizes to achieve optimal solubility. Rao et al. (1992) recommended limestone particle diameters larger than 1.0mm. On the other hand, Murata (1995) fed 3.75, 4.15, or 4.55% calcium levels to 57-week-old layers, and did not observe significant differences in egg production, egg loss percentage, egg weight, breaking strength, eggshell percentage and thickness, or apparent egg density when 0, 25, 50, 75, and 100% powdered limestone was replaced by granulated limestone.

Faria et al. (2000) studied feeding systems and oyster shell supplementation in commercial layers, and observed that birds fed predominantly during the night presented worse performance and there was no benefits in terms of eggshell quality.

This study aimed at evaluating the effects of calcium levels and limestone particle size composition (fine, coarse, and combinations) in the diet of Hy-Line Brown commercial layers in their second laying cycle on eggshell quality.

MATERIAL AND METHODS

The experiment was carried out at the facilities of the Research and Development Unit of Brotas, Development Decentralization Department, Agribusiness Technology Agency of São Paulo, Brazil. A total number of 288 Hy-Line Brown commercial layers, with 83 weeks of age at the beginning of the experiment were used. Birds were distributed in 36 cages (1.00m long x 0.45m deep x 0.40m high) with a 0.50m internal partition to allow housing eight birds per cage. Each cage was equipped with a cup drinker and a trough feeder place in front of the cage.

The experimental diets (Table 1) were based on corn and soybean meal, considering the raw material composition established by Rostagno et al. (2000).

Birds were submitted to conventional force molting. First, they were fasted for 14 days until they lost 25-28% of their live weight. Water was supplied ad libitum, and feed offer was gradually increased to 30, 60, and 90g feed/bird/day on the first, second, and third week, respectively. Birds were then fed every other day for five days, and then received a production feed for two days and were fasted for five days, completing 31 days of the molting period. Average bird weight at the beginning and the end of molting was 1740g and 1270g, respectively, with 27.01% live weight loss.

After forced molting, were submitted to equal management and feeding conditions until the peak of production, when they were standardized according to body weight and egg production.

The experiment started 60 days after the beginning of molting, when birds had reached 50% of production. Layers were 83 weeks of age at the beginning of the experiment and 111 weeks of age at the end.

Limestone particle size was analyzed according to the method described by Zanotto & Bellaver (1996). A duly identified sample consisting of approximately 1kg of each limestone source was used to determine particle size using a vibrator with ABNT sieves numbers 5, 10, 16, 30, 50, 100, and bottom, corresponding to the following mesh openings (mm): 4, 2, 1.20, 0.60, 0.30, 0.15 and bottom.

Particle size was characterized according to treatment and particle geometric standard deviation, expressed as mean geometric diameter (MGD).

In-vitro solubility was determined according to the method described by Cheng & Coon (1990b) of the University of Minnesota (weight loss percentage method). A 400mL beaker, containing 100mL of a HCl solution at 0.1M (8.35mL HCl/L water), was heated for 15 minutes in an oven at 42ºC, with shaking at 60rpm. Two grams of limestone were placed in the beaker, and allowed to react for 10 minutes. The beaker content was then filtered through a "Whatman 42" paper filter, which was previously dried in an oven and weighed, and then the beaker and the limestone residues were washed with deionized water. Filters and samples were dried at 55ºC for 12 hours, and weighed. The percentage of solubilized limestone was calculated as the difference between initial and final weight, and expressed as in-vitro limestone solubility percentage. The different limestone sources were submitted to calcium chemical composition analysis using EDTA chelatometric method (Brasil, 1988).

Layers were distributed in a completely randomized experimental design in a 2x3 factorial arrangement with six treatments: two dietary calcium levels (3.5% or 4.0%) and three limestone particle size compositions, as follows: 100% fine limestone (0.185mm), 30% coarse limestone (2.83mm) + 70% fine limestone (0.185mm), or 50% coarse limestone (2.83mm)+ 50% fine limestone (0.185mm). There were six replicates per treatment of eight birds each, totaling 288 birds in 36 experimental cages.

The following treatments were applied: 3.5% calcium with 100% fine particle limestone (T1), 3.5% calcium with 70% fine particle limestone and 30% coarse particle limestone (T2); 3.5% calcium with 50% fine particle limestone and 50% coarse particle limestone (T3); 4.0% calcium with 100% fine particle limestone (T4), 4.0% calcium with 70% fine particle limestone and 30% coarse particle limestone (T5); 4.0% calcium with 50% fine particle limestone and 50% coarse particle limestone (T6).

Eggs from each experimental unit were daily collected and counted to determine egg production. Eggs and feed residues were weekly weighed for performance evaluation. The following parameters were evaluated: egg weight (g), egg production (%), egg mass (%),feed intake (g), feed conversion ratio (kg/dz and kg/kg), and mortality. An experimental period of 112 days was considered.

Egg quality was measured at the end of four 28-day periods, collecting four eggs from each init for three consecutive days, totaling 72 eggs per treatment. Eggs were identified per treatment and individually weighed in a digital scale with 0.001g precision. Eggs were then submitted to the laboratory to determine specific gravity; yolk, albumen, and eggshell percentages, yolk index (YI), Haugh units (HU), eggshell thickness (ET), and eggshell breaking strength (BS).

Specific gravity was determined by immersing eggs in saline solutions with densities between 1,065 and 1,100g/cm3, in 0.005 gradients.

Eggs were then broken, and eggshell, albumen, and yolk were separated and weighed.

Eggshells were rinsed running water and dried in a force-ventilation oven at 60°C for 12h, to determine eggshell thickness (including the membrane) in three points of the egg equatorial region using a Mitutoyo caliper with a 0.01mm precision. Eggshells were weighed using a 0.001g precision scale.

Albumen quality was evaluated in Haugh units. Using egg weight (g) and albumen height (mm) data, Haugh units were determined according to the formula suggested by Standelman & Cotterill (1986): HU= 100 log (H + 7.57 - 1.7W0.37), where: HU = Haugh unit; H= albumen height (mm), and W= egg weight (g).

Yolk quality was expressed in yolk index. Yolk height and diameter were measured, and their ratio determined yolk index, according to the formula: YI = YH/YD, where YI = yolk index, YH = yolk height (mm), and YD = yolk diameter (mm).

Eggshell breaking strength was evaluated in intact whole eggs using a specific cell coupled to a Texture Analyser TA. XT plus apparatus with a Cyl Stainless 2mm probe, code P/2, pre-test velocity of 2mm/sec, test velocity of 1.0mm/sec, and post-test velocity of 40mm/sec, recording the strength required to break the eggshell, expressed in kgf.

Data were submitted to analysis of variance, and treatment means were compared by the test of Tukey at 5% significance using SISVAR software package (Ferreira, 2000).

RESULTS AND DISCUSSION

Average minimum and maximum temperatures recorded during the experimental period were 18 and 29°C, with average temperature of 22.3°C.

The results of the analyses to determine limestone particle size, in-vitro solubility and calcium content are shown in Table 2.

The analysis of variance did not detect significant treatment effects on any of the evaluated performance parameters. There were no statistical differences between calcium levels or among limestone particle size compositions, as well as no interactions among these two factors. The following means were determined: egg weight = 68.88g (CV = 2.15%); egg production = 85.91% (CV = 4.99%); egg mass = 59.14g (CV = 5.02%); average daily feed intake = 111.08 g (CV = 2.69%); feed conversion ratio per dozen eggs = 1.56 (CV = 4.09%), feed conversion ratio per kg eggs = 1.90 (CV = 3.97%), mortality = 2.99% (CV = 175.94%), and egg loss = 0.74 (CV = 34.14%).

These results are consistent with the findings of Zhang & Coon (1992), Murata (1995), Oliveira et al. (1995), and Scheideler (1998) for feed intake and egg weight. Cheng & Coon (1990c) and Café et al. (1999) evaluated the effect of limestone source and particle size and did find any significant differences on feed conversion ratio.

We expected that eggs from layers fed coarse limestone presented lower egg loss percentage as compared to those fed fine limestone due to its lower solubility. Despite the lack of significant results, coarse limestone produced less cracked eggs, in absolute values, for the total experimental period. However, the lack of statistical difference may be due to the observed coefficients of variation.

Costa et al. (2008) did not observe significant influence of dietary calcium levels (3.0, 3.4, 3.8, 4.2, 4.6, and 5.0%) fed to semi-heavy layers after the peak of lay on any of the evaluated performance parameters.

Mean egg quality results, as a function of calcium levels and limestone particle size, are shown in Table 3.

The analysis of variance did not detect any effect (p >0.05) of the treatments on any of the evaluated parameters.

Mean egg specific gravity values obtained in the present study was 1.088, which is consisted with the expected values higher than 1.074 (Junqueira, 1993) and between 1.080 and 1.088 (Mendonça Jr., 1993). The thinner the eggshell, the lower the specific gravity, and therefore, the higher the probability of cracked and broken eggs (Miles, 1993). As layers age, egg size increases, eggshell thickness decreases, and consequently specific gravity is reduced, indicating a direct relation between eggshell thickness and the remaining egg components (Mendonça Jr., 1993).

The results of the present study are consistent with those obtained by Keshavarz & Nakajima (1993), who worked with different dietary calcium levels and did not find egg specific gravity differences when calcium level was increased from 3.5% to 4.0%. Kussakawa et al. (1998) also did not detect any influence on egg specific gravity of 0.25-0.50mm fine limestone or 1.00-2.38mm coarse limestone.

There were no qualitative losses in terms of eggshell percentage or thickness. It was expected that the tested calcium levels and the supplied coarse limestone provided more calcium available for eggshell formation due to the longer retention of limestone in the gizzard, as suggested by Rao & Roland (1990) and Miles (2000). However, the results show that the treatments used provided sufficient calcium for efficient eggshell deposit, independent of calcium levels and limestone particle size. Murata (1995), evaluating calcium levels (3.75, 4.15, and 4.55%) and different rates (0, 25, 50, 75, and 100%) of powdered limestone replacement by granulated limestone in the feed of 57-week-old layers, also did not detect any influence of the treatments on egg production, egg loss percentage, egg weight, eggshell breaking strength, percentage and thickness, as well as egg apparent density. In the study of Kussakawa et al. (1998), there was no significant influence on eggshell weight when fine limestone (particle size of 0.25-0.50mm) or coarse limestone (particle size of 1.00-2.38mm) were fed. Scheideler (1998), quoted by Jardim Filho et al. (2005b) reported that layers are able to solubilized calcium consumed in large particles as compared to low particles, consequently retaining more calcium. Therefore, at the time of eggshell formation, blood calcium concentration is higher, and the body uses less bone deposits, allowing higher calcium use for eggshell formation.

Bertechini (2006) explained that after calcium is ingested, it is absorbed to the blood, where it is present as free calcium or bound to the calcium-transporting protein, calmodulin. This complex functions as plasmatic storage, and it is highly available to be ionized as free calcium is used for eggshell formation. The surplus of ingested calcium is deposited in structural or medullar bones, which consist of less labile storage sites, but not less important, particularly as eggshell formation occurs during the dark period, when birds do not consume feed.

Rodrigues et al. (2005) supplied 2.0 and 3.5% calcium to light commercial layers in their second laying cycle, and observed better external egg quality results with the higher calcium level. This is consistent with the present experiment, where 3.5% calcium supplied by fine limestone, as typically recommended for white layers in their first laying cycle, maintained egg quality during the second laying cycle.

Roland & Bryant (1994) reported a linear increase in egg specific weight when dietary calcium levels were increased from 2.5 to 4.5%, which was different from the present study, which did not detect any influence of calcium levels.

Costa et al. (2008) supplied different calcium levels (3.0, 3.4, 3.8, 4.2, 4.6, 5.0%) to semi-heavy layers after the peak of lay and found that increasing dietary calcium levels increased albumen and eggshell percentages relative to the other egg components. Those authors recommend a level of 4.3% calcium for semi-heavy layers after the peak of lay.

Geraldo et al. (2006) did not observe any effect of limestone particle size on egg specific weight, whereas Hamilton et al. (1985), Cheng & Coon (1990c), and Ito et al. (2006) showed that coarse limestone increased egg specific weight as compared fine limestone.

Jardim Filho et al. (2005a) observed better eggshell quality in layers fed limestone as grit (MGD range of 2.0-5.0 mm) as compared to those fed fine (MGD<1.0 mm) and medium (MGD range of <1.0-1.0 mm) limestone. Guinotte & Nys (1991) found higher eggshell strength, egg weight, and eggshell weight when feeding large-particle calcium sources. The authors attributed the results to higher calcium retention in the crop and gizzard.

Roland et al. (1978) worked with calcium-deficient diets, and concluded that the decline in eggshell quality in older layers are not due to a reduction in their capacity to efficiently absorb or utilize skeletal calcium, but rather because calcium retention remains constant, and their eggs are larger as compared to those of younger layers.

Large particles may be beneficial in situations that cause reduction in calcium intake or availability (Rao et al., 1992). The partial substitution of fine limestone by coarse limestone in the present study may not have promoted any improvement in eggshell quality because layers were offered ad libitum water and feed containing correct nutritional levels, were free of diseases, and submitted to a lighting program that probably promoted bird welfare and absence of stress.

Our results are also consistent with those obtained by Rodrigues (1995), who observed that internal egg quality of second-cycle layers, as evaluated by Haugh units, specific weight, and average eggshell thickness, was not influenced by dietary calcium levels (3.8 vs. 4.5%), independent of production stage. However, in a previous study, Rodrigues et al. (1994) applied two calcium levels (3.8 and 4.2%), and observed better Haugh units in the second laying cycle when the highest calcium level was fed.

CONCLUSIONS

Under the conditions of the present experiment, we concluded that neither dietary calcium level or limestone particle size had any influence on egg quality of second-laying cycle layers.

The 3.5% calcium level recommended for first-laying cycle light layers can be fed to commercial Hy-Line Brown semi-heavy layers in second laying cycle.

Limestone in fine particle size can be substituted in up to 50% by limestone in coarse particle size with no detrimental effect on egg quality.

Arrived: June/2006

Approved: June/2009

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    Caixa Postal 09
    17.380-000. Brotas, SP, Brasil.
    E-mail:
  • Publication Dates

    • Publication in this collection
      24 Aug 2009
    • Date of issue
      June 2009

    History

    • Received
      June 2006
    • Accepted
      June 2009
    Fundação de Apoio à Ciência e Tecnologia Avicolas Rua Barão de Paranapanema, 146 - Sala 72, Bloco A, Bosque., CEP: 13026-010. , Tel.: +55 (19) 3255-8500 - Campinas - SP - Brazil
    E-mail: revista@facta.org.br