Wet corn gluten feed (WCGF), a byproduct of the wet-milling industry, is commonly substituted in lactating dairy rations for both forages and concentrates. Previous research has shown that increasing WCGF in the diet decreased ruminal pH, likely due in part to decreasing particle size as forage inclusion rate decreased. The objective of this study was to maintain at least 10% of ration particles >19 mm in length across diets while increasing WCGF inclusion in the diet. We hypothesized that as WCGF increased in this scenario, dry matter intake (DMI) and milk yield would increase and ruminal pH would be maintained. Seven ruminally cannulated, lactating Holstein cows (4 multiparous and 3 primiparous) were used in an incomplete 4×4 Latin square design. Treatments included 0, 12.4, 24.5, or 35.1% WCGF and used alfalfa hay to maintain particle size. Across treatments, crude protein and neutral detergent fiber concentrations were held relatively constant. Four 21-d periods were used with 17d of adaptation and 4d of sample collection. Indwelling ruminal pH probes were used during sampling periods and recorded pH every 5 min. Particle size of total mixed rations and orts were analyzed using a Penn State Particle Separator (The Pennsylvania State University, University Park). Results were analyzed with mixed models to test the fixed effect of treatment. All diets contained ≥10% of particles >19 mm; however, as WCGF increased, the proportion of particles >19 mm decreased. Interestingly, with increasing WCGF, cows sorted for the particles >19 mm but against particles on the bottom screen and pan. With increasing WCGF, ruminal pH was not affected, but DMI and milk yield increased in a quadratic fashion, with the peak responses for the 24.5% WCGF diet. Milk protein, lactose, and fat concentrations were not affected by treatment; however, milk protein and lactose yields increased with the inclusion of WCGF because of the increased milk yield. Production efficiency was not affected by treatments. Thus, if adequate particle size is maintained when WCGF increases in the diet, DMI and milk yield increase while maintaining production efficiency and ruminal pH.
Active dry yeast (ADY) products are commonly fed in the dairy industry, but research regarding quality control for such products is limited. The objectives of this study were to determine yeast viability in field samples relative to manufacturers' guarantees (experiment 1), measure the effects of high-temperature storage on yeast viability (experiment 1), and determine the effect of vitamin-trace mineral (VTM) premix on yeast viability (experiment 2). Commercially available ADY products were acquired in triplicate through normal distribution channels and stored at 4°C upon receipt. Initial samples were evaluated for colony-forming units and compared with product label guarantees. Only 1 of the 6 products sampled in experiment 1 met product guarantees for all 3 samples. To determine effects of storage temperature and duration on viability, ADY samples were stored in an incubator at 40°C with ambient humidity for 1, 2, and 3 mo. High-temperature storage significantly decreased viability over the 3-mo period; approximately 90% of viable cells were lost each month. Three of the 5 products sampled in experiment 2 met product guarantees. Fresh samples of 4 of these 5 ADY products were mixed in duplicate with ground corn (GC) or a VTM premix to achieve a target concentration of 2.2×10(8) cfu/g. For each product, GC and VTM samples were stored at ambient temperature (22°C) and at an elevated temperature (40°C) for 2 wk. No differences in viable yeast count were observed between GC and VTM samples immediately after mixing or after storage at ambient temperature. Yeast viability in GC and VTM samples decreased during storage at an elevated temperature. There also was a significant interaction of diluent and storage temperature; VTM samples had higher cell viability than GC samples when subjected to high-temperature storage. Results suggest that (1) ADY products failed to consistently meet product guarantees; (2) viability of ADY products was greatly diminished during storage at 40°C for 2 wk; and (3) the loss in viability at elevated temperatures may be attenuated when ADY products are diluted with a premix containing VTM.
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