Feeding encapsulated ground full-fat soybeans to increase polyunsaturated fat concentrations and effects on flavor volatiles in fresh lamb.

This research assessed the potential of increasing PUFA concentrations and the effect on flavor volatiles in red meat by feeding ground, full-fat soybean supplemented in casein complex. Supplements consisted of untreated ground, full-fat soybean (CO) or ground, full-fat soybeans treated with acetaldehyde (AC) or diacetyl (DA) to form gels. On a DM basis, the control (CO), AC, and DA supplements contained 48.6, 50.0, and 49.1% CP and 17.3, 17.3, and 17.4% fat, respectively. Weaned feeder lambs (n = 18) were divided into three treatment groups with two pens of three lambs per group. One of three supplements (200 g of DM) plus 1 kg DM of a ground corn basal diet and 0.36 kg DM of grass hay was fed daily to each of six lambs in a group for 9 wk. Samples of the intramuscular (LM), intermuscular, subcutaneous, and kidney fat were obtained from each lamb carcass for determination of total lipid contents and fatty acid profiles. Flavor volatiles of broiled LM were also analyzed. Total fat content of the LM was 3.7, 4.6, and 2.6% for lambs consuming diets supplemented with CO, AC, and DA, respectively. Compared with lambs fed the untreated supplement (CO), lambs supplemented with AC or DA had 1) higher (P < 0.05) concentrations of linoleic (4.80 vs. 6.37 or 6.80%) and linolenic (0.28 vs. 0.43 or 0.45%) acids in the LM nonpolar lipids; 2) a higher (P < 0.05) concentration of linoleic acid (22.1 vs. 27.1 or 25.6%), but a lower (P < 0.05) concentration of oleic acid (17.2 vs. 13.0 or 13.1%), in the LM polar lipids; 3) a higher (P < 0.05) concentration of linoleic acid (3.77 vs. 6.13 or 6.06%) in subcutaneous fat; and 4) higher (P < 0.05) concentrations of linoleic (4.46 vs. 7.65 or 7.13%), linolenic (0.50 vs. 0.85 or 0.80%), and stearic (24.9 vs. 27.2 or 26.9%) acids, but a lower (P < 0.05) concentration of oleic acid (39.1 vs. 35.4 or 36.3%), in kidney fat. In broiled LM chops, 21 volatiles were identified, including seven alkanals, seven 2-alkenals, two 2,4-alkadienals, and five other compounds, but most differences in the volatile concentrations among lambs fed the different supplements did not correspond to concentration differences in their precursor fatty acids. Results indicated that compared with the untreated supplement (CO), AC and DA supplements protected linoleic (C 18:2n6) and linolenic (C18:3n3) acids in soybean oil from degradation in the rumen of the lambs, resulting in increased deposition in the muscle and adipose tissues of lamb.

Ultrasound evaluation of the magnitude of pneumothorax: a new concept.

Pneumothorax is commonly seen in trauma patients; the diagnosis is confirmed by radiography. The use of ultrasound where radiographic capabilities are absent, is being investigated by the National Aeronautics and Space Administration. We investigated the ability of ultrasound to assess the magnitude of pneumothorax in a porcine model. Sonography was performed on anesthetized pigs in both ground-based laboratory (n = 5) and microgravity conditions (0 x g) aboard the KC-135 aircraft during parabolic flight (n = 4). Aliquots of air (50-100 cm3) were introduced into the chest to simulate pneumothorax. Results were videorecorded and digitized for later interpretation. Several distinct sonographic patterns of partial lung sliding were noted including the combination of a sliding zone with a still zone and a "segmented" sliding zone. These "partial lung sliding" patterns exclude massive pneumothorax manifested by a complete separation of the lung from the parietal pleura. In 0 x g, the sonographic picture is more diverse; one x g differences between posterior and anterior aspects are diminished. Modest pneumothorax can be inferred by the ultrasound sign of "partial lung sliding." This finding, which increases the negative predictive value of thoracic ultrasound, may be attributed to intermittent pleural contact, small air spaces, or alterations in pleural lubricant. Further studies of these phenomena are warranted.

The effects of n-3 fatty acid supplementation on bleeding time, plasma fatty acid composition, and in vitro platelet aggregation in cats.

Dietary supplementation with fish and fish oils rich in the n-3 fatty acids eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) has been shown to alter eicosanoid metabolism and impair platelet function in several species. As an initial step in evaluating the antithrombotic effect of these n-3 fatty acids in cats, purified EPA and DHA were administered daily to 8 clinically normal cats for 2 months. Platelet function was evaluated biweekly by determining mucosal bleeding time and in vitro platelet aggregation parameters. Plasma fatty acid profiles were obtained before fish oil supplementation and at the termination of the study. In spite of significant increases (P < .0001) in the plasma concentrations of EPA and DHA after n-3 fatty acid supplementation, there were no significant changes in platelet aggregation or bleeding times. Although it is tempting, based on extrapolation of data from other species, to recommend dietary supplementation with fish oil for cats prone to arterial thromboembolism, these results indicate that administration of large doses of purified EPA and DHA once daily does not inhibit platelet function in normal cats and is unlikely to prevent thrombosis in cats with cardiovascular disease. Additional studies are recommended to ascertain whether more frequent administration of these purified n-3 fatty acids or continual feeding of diets high in n-3 fatty acid content will impair platelet function.

Effects of feeds on flavor of red meat: a review.

The effects of diet ingredients on red meat flavor are dependent on the type of diet, and, to a large extent, on the species: pork, mutton or lamb and beef. Sensory analysis of meat flavor has been used in most of the studies on the effects of feeds on meat flavor. In general, high-energy grain diets produced a more acceptable or a more intense flavor in red meats than low-energy forage or grass diets. Feeding pigs unsaturated fats increases the unsaturation in pork fat but results in only minor changes in pork flavor. Sheep must be fed protected, unsaturated fats in order to increase the unsaturation in their fat to be similar to pork fat. This increased unsaturation results in a greater flavor change in lamb or beef than in pork. Several dietary ingredients such as fish products, raw soybeans, canola oil and meal, and pasture grasses cause undesirable flavors in red meat. Analyses of lamb and beef produced on different diets have shown that type of feed affects the concentration of many flavor volatile compounds. However, only a few studies have quantified the volatiles of beef and lamb produced on different diets, and no reports of studies were found in which the volatiles of pork produced on different diets had been investigated. Hence, the importance of these changes in volatile concentration to meat flavor has not been determined.