Effects of canola meal pellet conditioning temperature and time on ruminal and intestinal digestion, hourly effective degradation ratio, and potential nitrogen to energy synchronization in dairy cows.

The increase in bio-oil production in North America has resulted in millions of tonnes of co-products: canola meal and carinata meal. Little research has been conducted to determine the effect of pellet conditioning temperature, time, and their interaction on processing-induced changes in nutrient digestibility in the rumen and intestine (in vitro) of dairy cattle. The objectives of this study were to investigate the effects of conditioning temperature (70, 80, and 90°C), time (50 and 75 s), and their interaction (temperature × time) during the pelleting of canola meal on (1) rumen degradation kinetics and effective rumen degradability of dry matter, crude protein (CP), and neutral detergent fiber; (2) intestinal digestibility of rumen-undegradable protein (RUP); and (3) hourly effective rumen degradation ratio and potential N to energy synchronization in dairy cattle. The results showed that the temperature and duration of pellet conditioning significantly altered the degradation characteristics of nutrients in the rumen. Pelleting increased CP degradation in the rumen, and CP digestion site was shifted to the rumen rather than to the small intestine. When conditioning temperature was set 80°C, the rumen degradation of CP and neutral detergent fiber was highest, but postrumen digestion was lowest. With respect to intestinal digestion, the available CP for intestinal digestion became less because of reduced RUP supply to the small intestine. The pelleting process tended to significantly affect the intestinal digestibility of RUP. However, the total digestible CP content of canola meal was not affected. In conclusion, pelleting induced changes in rumen and intestinal digestion profiles, and altered the potential N to energy synchronization and hourly effective rumen degradation ratio of canola meal in dairy cattle.

Prediction of rumen degradability parameters of a wide range of forages and non-forages by NIRS.

Kinetics of nutrient degradation in the rumen is an important component of feed evaluation systems for ruminants. The in situ technique is commonly used to obtain such dynamic parameters, but it requires cannulated animals and incubations last several days limiting its application in practice. On the other hand, feed industry relies strongly on NIRS to predict chemical composition of feeds and it has been used to predict nutrient degradability parameters. However, most of these studies were feedstuff specific, predicting degradability parameters of a particular feedstuff or category of feedstuffs, mainly forages or compound feeds and not grains and byproducts. Our objective was to evaluate the potential of NIRS to predict degradability parameters and effective degradation utilizing a wide range of feedstuffs commonly used in ruminant nutrition. A database of 809 feedstuffs was created. Feedstuffs were grouped as forages (FF; n=256), non-forages (NF; n=539) and of animal origin (n=14). In situ degradability data for dry matter (DM; n=665), CP (n=682) and NDF (n=100) were collected. Degradability was described in terms of washable fraction (a), slowly degradable fraction (b) and its rate of degradation (c). All samples were scanned from 1100 to 2500 nm using an NIRSystems 5000 scanning in reflectance mode. Calibrations were developed for all samples (ALL), FF and NF. Equations were validated with an external validation set of 20% of total samples. NIRS equations to predict the effective degradability and fractions a and b of DM, CP and NDF could be evaluated from being adequate for screening (r(2)>0.77; ratio of performance to deviation (RPD)=2.0 to 2.9) to suitable for quantitative purposes (r(2)>0.84; RPD=3.1 to 4.7), and some predictions were improved by group separation reducing the standard error of prediction. Similarly, the rate of degradation of CP (CP(c)) and DM (DM(c)) was predicted for screening purposes (RPD⩾2 and 2.5 for CP(c) and DM(c), respectively). However, the rate of degradation of NDF was not predicted accurately (NDF(c) : r(2)<0.75; RDP<2).

Efeitos da adição de propilenoglicol ou monensina à silagem de milho sobre a cinética de degradação dos carboidratos e produção cumulativa de gases in vitro / Effects of adding propylene glycol or monensin to corn silage on the degradation kinetics of carbohydrates and in vitro cumulative gas production

Avaliaram-se os efeitos dos aditivos propilenoglicol e/ou monensina sobre a degradabilidade média e efetiva dos carboidratos totais, pH e produção cumulativa de gases da silagem de milho por meio da técnica in vitro semi-automática de produção de gases. Os tratamentos constituíram-se de silagem de milho (SM); SM associada ao propilenoglicol (SM+PG); SM associada à monensina (SM+MO); SM associada ao propilenoglicol e à monensina (SM+PG+MO) avaliados com duas, quatro, seis, 12, 24, 48 e 96 horas. A adição de monensina ou monensina associada ao propilenoglicol aumentou (P<0,05) a degradabilidade dos carboidratos totais às duas horas. SM+MO apresentou maior degradabilidade efetiva dos carboidratos totais em todas as taxas de passagem. A utilização de monensina reduziu a produção cumulativa de gases das 12 às 96 horas. Entre os tratamentos, SM+MO apresentou o menor potencial de produção de gases (221ml/g carboidratos totais) e o menor tempo de colonização (1,08 horas) em relação aos tratamentos SM e SM+PG (1,58 e 1,49 horas, respectivamente). A produção cumulativa de gases e degradabilidade dos carboidratos totais apresentaram elevada correlação, variando de 94 a 97 por cento (P<0,01). O pH do meio foi inversamente correlacionado à degradabilidade dos carboidratos totais (r= -79 por cento, P<0,01). O uso de monensina pode ser uma boa alternativa para se melhorarem os parâmetros da cinética de degradação da silagem de milho.

The effects of the additives propylene glycol and/or monensin on the degradation of total carbohydrates, pH, and cumulative gas production of corn silage by the semi-automated in vitro gas production technique were evaluated. The treatments were corn silage (CS); CS plus propylene glycol (CS+PG); CS plus monensin (CS+MO), and CS plus propylene glycol and monensin (CS+PG+MO), which were evaluated at two, four, six, 12, 24, 48, and 96 hours. The addition of monensin or monensin plus propylene glycol increased (P<0.05) the degradation of total carbohydrates at 2h. The effective degradations of total carbohydrates for CS+MO treatment (55.2; 42.7; and 36.5 percent) were the highest in all passage rates. The use of monensin reduced cumulative gas production from 12 to 96h. CS+MO treatment had the lowest potential of gas production (221ml/g total carbohydrates), and the lowest Lag phase (1.08h), as compared to CS and CS+PG treatment (1.58 and 1.49h, respectively). Cumulative gas production and degradation of total carbohydrates were highly correlated (94 to 97 percent; P<0.01). The pH was inversely correlated to degradability of total carbohydrates (r= -0.79; P<0.01). Thus, monensin may be used for improving the ruminal degradability of corn silage.