A total of 251 growing-finishing Iberian (IB) pigs, 32 of which were suckling piglets, were used in 5 separate sets of trials. The comparative slaughter procedure was used to determine nutrient and energy retention at several stages of growth from birth to 150 kg BW. A factorial arrangement was used within each set of trials, involving several concentrations of ideal protein in the diets as 1 factor and 2 or 3 levels of feed intake as the other. The main objective of these studies was to derive the optimal protein-to-energy ratio in the diet to allow for the expression of maximum protein deposition rates. The effect of feed restriction on growth performance, protein deposition, and fat deposition was also assessed. According to allometric equations, empty BW (EBW) was related to whole body components or total chemical constituents of empty body mass (P < 0.001). For pigs receiving solid feed, highly statistically significant multiple regression equations were constructed, which derived nutrient (g/kg) or energy (MJ/kg) composition as a function of EBW, dietary protein-to-energy ratio, and level of feeding (P < 0.001). In pigs offered adequate protein-to-energy diets, ADG at each stage of production was predicted as a function of the average BW and feeding level (P < 0.001). It was observed that the estimates of ME required for maintenance and net efficiency of utilization of ME for growth change were within rather narrow ranges throughout the growth stages studied. Preferred values (413 kJ/kg BW(0.75) × d(-1) and 0.593 for ME(m) and k(g), respectively) were obtained by regressing total energy retention (kJ/kg BW(0.75) × d(-1)) against ME intake (kJ/kg BW(0.75) × d(-1)). A multiple-regression approach revealed that in the IB pig, ME costs for protein deposition and fat deposition reach 60 and 62 kJ/g, which is considerably greater than in conventional or lean pig genotypes. In the IB pig, the maximum daily rate of protein deposition (PD(max), g) seemed to follow a linear-plateau shape with a breaking point at 32.5 kg BW, beyond which PD(max) remained at an average rate of 75 g × d(-1). The marginal efficiency of body protein deposition was estimated at each growth stage. In pigs fed on optimal or suboptimal protein-to-energy diets, the relationship between PD and ME intake declined, following a curvilinear pattern with increasing BW; thus, implying relative increases in lipid gain as BW increased.
A total of 211 growing-finishing Iberian (IB) pigs from 4 separate and independent sets of trials were slaughtered at several stages of growth from 10 to 150 kg BW to determine growth and development of chemical and physical components of the cold eviscerated carcass (CC; without head, feet, and tail). Within each set of trials, a factorial arrangement of treatments, involving several concentrations of ideal protein in the diets as 1 factor and 2 or 3 levels of feed intake as the other, was used. The main objective of the present study was to provide information on the relative growth of physical and chemical components of the CC of IB pigs, which differed because of the dietary treatment imposed, involving a wide range of protein-to-energy ratios and feeding levels. Allometric relationships (P < 0.001) were established between the weight of a chemical component in the CC and empty BW or CC weight. Irrespective of the adequacy of the dietary protein-to-energy ratio, the growth coefficient for CC weight relative to empty BW was >1 (P < 0.001), whereas those for protein, water, and ash relative to empty BW or CC weight were <1 (P < 0.001). In contrast, relative growth coefficients >1 (P < 0.001) were obtained for fat mass and total energy, reflecting the increase in fat relative content that occurs with increasing weight. Multiple-regression equations (P < 0.001) were developed using a stepwise procedure, which estimates the chemical (g/kg) or energy (MJ/kg) composition of CC as a function of empty BW, dietary protein-to-energy ratio, and feeding level, expressed as a multiple of the ME required for maintenance. It is concluded that even if the pattern of developmental growth for the IB pig may show some similarities (increased fat content or decreased proportional weight of some primal cuts with BW or age) with that observed for pigs of different genetic background, relevant differences were detected. They are related to a much smaller relative size of the IB pig lean tissues and cuts, their slower rates of growth, and the increased total body fat, with marked changes in its distribution among depots. Consequently, relationships obtained for lean or conventional genotypes are not applicable to the IB pig.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.