L. K. Rakes

Effects of dietary magnesium and duration of refrigerated storage on the quality of vacuum-packaged, boneless pork loins.

Quality data were initially collected on 78 pork loins from crossbred pigs fed diets containing 0, 1.25 or 2.5% magnesium mica (MM). Loins were then vacuum-packaged, and randomly assigned to either 4 or 8 weeks of storage at 2°C. Dietary MM had no (P > 0.05) effect on moisture loss/retention or subjective and objective color measurements. Purge volume increased (P<0.05) and drip loss decreased (P<0.05) as storage time increased. Moreover, longissimus thoracis et lumborum (LM) chops became lighter (P<0.05), redder (P<0.05), and more yellow (P<0.05) during 8 weeks of storage. Although TBARS values increased linearly (P<0.001) during extended storage, LM chops from pigs fed 2.5% MM tended to have lower (P<0.07) TBARS values after 4 weeks of storage than chops from pigs fed 0 and 1.25% MM. After 8 weeks of storage, however, there was a tendency for TBARS values of chops from pigs fed 1.25% MM to be lower (P<0.07) than chops from pigs fed 2.5% MM. Even though feeding swine diets containing MM did not affect color and water-holding capacity of pork loins during storage, the data indicated inclusion of MM in swine diets may retard onset of oxidative rancidity in vacuum-packaged pork loins.

Interactive effect of ractopamine and dietary fat source on pork quality characteristics of fresh pork chops during simulated retail display

Crossbred pigs (n = 216) were used to test the interactive effect, if any, of ractopamine (RAC) and dietary fat source on the performance of finishing pigs, pork carcass characteristics, and quality of LM chops during 5 d of simulated retail display (2.6 degrees C and 1,600 lx warm-white fluorescent lighting). Pigs were blocked by BW and allotted randomly to pens (6 pigs/pen), and, after receiving a common diet devoid of RAC for 2 wk, pens within blocks were assigned randomly to 1 of 4 diets in a 2 x 2 factorial arrangement, with 5% fat [beef tallow (BT) vs. soybean oil (SBO)] and RAC (0 vs. 10 mg/kg). Diets were formulated to contain 3.1 g of lysine/Mcal of ME and 3.48 Mcal/kg of ME. Across the entire 35-d trial, pigs fed RAC had greater (P < 0.01) ADG and G:F, but RAC did not affect (P = 0.09) ADFI; however, performance was not affected (P >or= 0.07) by dietary fat source. Carcass weight, LM depth, and lean muscle yield were increased (P < 0.01), whereas fat depth was decreased (P = 0.01), in carcasses from RAC-fed pigs; however, carcass composition measures were similar (P >or= 0.27) between fat sources. Feeding 10 mg/kg of RAC reduced (P <or= 0.04) the proportions of SFA and MUFA and increased (P < 0.01) the proportion of PUFA and the iodine value, in pork backfat. Conversely, backfat from carcasses of BT-fed pigs had greater (P < 0.01) percentages of SFA and MUFA, and lower (P < 0.01) percentages of PUFA, than backfat from SBO-fed pigs. Moreover, the PUFA:SFA and iodine value were considerably reduced (P < 0.01) by including BT in swine finishing diets. The LM from pigs fed RAC had greater pH values (P = 0.03) and received greater (P <or= 0.01) American and Japanese color scores during retail display. The LM from RAC-fed pigs had lower (P <or= 0.02) L*, a*, and b* values, whereas the LM of SBO-fed pigs received greater (P < 0.01) subjective color scores and b* values, as well as lower L* values, than the LM of BT-fed pigs. Across the 5-d display period, oxidative rancidity was not affected by dietary RAC (P = 0.58) or fat source (P = 0.47). Neither RAC nor fat source altered LM cooking losses and shear force values. Feeding 10 mg/kg of RAC will improve rate and efficiency of gain, carcass composition, and LM quality. And, even though fatty acid composition of backfat samples was altered by dietary fat source, performance and carcass composition, as well as quality during 5 d of retail display, were similar when pigs were fed diets formulated with BT or SBO.

Effects of dietary magnesium and halothane genotype on performance and carcass traits of growing-finishing swine

Halothane-negative (NN) and halothane-carrier (Nn) pigs were assigned randomly to one of three dietary treatments: (1) control corn–soybean meal diets; (2) control diets supplemented with 1.25% magnesium mica (MM); or (3) control diets supplemented with 2.5% MM. When the lightest block averaged 108.8 kg, pigs were harvested at a commercial pork slaughter plant, and bone-in pork loins were captured, vacuum-packaged and transported back for measurement of pork quality traits. The NN pigs had greater average daily gain (ADG) during the grower (P 0.10) on ADG, pigs fed 1.25% MM had a higher (P<0.05) gain-to-feed ratio (G:F) during the grower phase than pigs fed 2.5% MM; whereas, pigs fed control diets had an intermediate G:F. Carcasses from Nn pigs were leaner (P<0.05) and heavier (P<0.05) muscled than carcasses from NN pigs. In contrast, a greater (P<0.05) percentage of carcasses from Nn pigs received color scores characteristic of the pale, soft and exudative (PSE) condition. Although there were distinct genotype effects on performance and carcass traits, long-term supplementation of diets with MM had no beneficial, or deleterious, effects on pork quality or carcass yield.

Influence of dietary inclusion level of manganese on pork quality during retail display

Boneless pork loins (n=112) were used to test the influence of dietary manganese (Mn) inclusion level on pork quality traits during retail display. Crossbred barrows and gilts were fed diets formulated with 0, 20, 40, 80, 160, or 320ppm Mn from Availa(®)Mn (AvMn; a Mn-amino acid complex) from 23.8 to 106.8kg live weight. At approximately 48h postmortem, boneless pork loins were fabricated into longissimus thoracis et lumborum (LM) chops, which were subsequently placed in open-topped, coffin-chest display cases (2.6°C) under continuous warm-white, fluorescent lighting (1600lx) for 7days. Dietary Mn level had no effect on LM pH (P=0.47), purge volume (P=0.60) and loss (P=0.53), or moisture loss (P=0.95) during retail display. Chops from pigs fed 80ppm Mn received higher (P<0.05) American and Japanese color scores than pigs fed 0 and 40ppm Mn. Even though the LM from pigs fed 80, 160, and 320ppm Mn tended to be darker (lower L(∗) values; P=0.07) than chops from pigs fed 40ppm Mn, a(∗) (redness) and b(∗) (yellowness) values, as well as hue angle and chroma, were not (P⩾0.19) affected by dietary Mn. On days 0 and 1, the reflectance ratio of 630nm/580nm was similar (P>0.05) among dietary Mn supplementation levels; yet, by day 4 of retail display, chops from pigs fed 80ppm Mn had higher (P<0.05) reflectance ratios than chops from pigs fed 0, 20, 40, and 160ppm, whereas LM chops from pigs fed 40ppm Mn had lower (P<0.05) reflectance ratios than all other dietary treatments on day 7 (Mn supplementation level×display day; P=0.04). Although TBARS were greater (P<0.001) on day 7 than 0 of retail display, TBARS values did not (P=0.43) differ among dietary Mn levels. Results indicate that supplementing swine diets with 80ppm Mn may improve pork color during retail display without increasing the likelihood of lipid oxidation.

Comparison of different magnesium sources on lamb muscle quality.

Wether lambs (n=20) were used to compare the effect of dietary magnesium oxide (MgO), unweathered Magnesium Mica® (UMM) and weathered Magnesium Mica® (WMM) on muscle quality. Lambs were fed a corn-based, control diet (Ctrl), or the Ctrl supplemented with either MgO, UMM, or WMM for 95 days before harvest. Following a 24-h chill, carcasses were fabricated, and L*, a* and b* values were determined on the triceps brachii (TB), longissimus thoracis (LT), semimembranosus (SM), and semitendinosus (ST) muscles. Supplemental magnesium had no (P > 0.10) effect on live and carcass weights, fat thickness, loin eye area, and USDA yield grade. Carcasses from lambs supplemented with MgO had higher (P < 0.10) flank streaking scores and USDA quality grades than those from lambs fed diets containing UMM. Although magnesium-supplementation had no (P > 0.10) effect on marbling scores, the LT from Ctrl-fed lambs had more (P < 0.05) intramuscular lipid than lambs fed diets containing UMM or WMM. Lambs supplemented with UMM had greater (P < 0.05) LT shear force values than lambs fed MgO or WMM. Magnesium-supplementation had no (P > 0.10) effect on muscle color; however, supplementing finishing diets with UMM may result in less palatable lamb.