پیوندهای مفید
اخبار و اعلانات
آمار
| تعداد نشریات | 418 |
| تعداد شمارهها | 9,987 |
| تعداد مقالات | 83,495 |
| تعداد مشاهده مقاله | 76,811,368 |
| تعداد دریافت فایل اصل مقاله | 53,907,549 |
Performance, Metabolic Responses of Fresh Cows to Daily or Every Other Day Oral Drenching a Glucogenic Precursor | ||
| Iranian Journal of Applied Animal Science | ||
| مقاله 5، دوره 9، شماره 1، خرداد 2019، صفحه 31-38 اصل مقاله (264.24 K) | ||
| نویسندگان | ||
| M. Kazemi-Bonchenari* 1؛ M. Jahani-Moghadam2؛ A.R. Alizadeh3؛ P. Ghodrati4؛ H. Shahabi4؛ E. Mahjoubi5؛ M. Gorjidooz6 | ||
| 1Department of Animal Science, Faculty of Agriculture and Natural Resources, Arak University, Arak, Iran | ||
| 2Department of Animal Science, Sari Agricultural Sciences and Natural Resources University, Sari, Iran | ||
| 3Department of Embryology, Reproductive Biomedicine Research Center, Royan Institute for Reproductive Biomedicine, Academic Center for Education, Culture and Research (ACECR), Tehran, Iran | ||
| 4Department of Animal Science, Saveh Branch, Islamic Azad University, Saveh, Iran | ||
| 5Department of Animal Science, University of Zanjan, Zanjan, Iran | ||
| 6Department of Clinical Science, Faculty of Veterinary Medicine, Islamic Azad University, Garmsar Branch, Garmsar, Iran | ||
| چکیده | ||
| The delivery method of [continuous (CONT) vs. every other day or intermittent (INT)] a glucogenic precursor (GP) which was contained glycerin (500 g/kg), mono-propylene glycol (250 g/kg), calcium propionate (150 g/kg), niacin (1 g/kg) and sulfate-Co (350 mg/kg) on performance, selected blood metabolites and liver enzymes were evaluated. Twenty-four multiparous Holstein fresh cows were allocated in a completely randomized design (8 animals/each treatment) fed individually for a period of 14 days after calving. The experimental groups were: 1) no GP supplementation (CTR), 2) GP offered as an oral drench once a day (GP-CONT) on days 3, 4, 5, 6, and 7 after calving and 3) GP offered as an oral drench once a day intermittently (GP-INT) on days 3, 5, 7, 9, and 11 after calving. The amount of oral drenched GP was 1 kg/d. Blood samples were obtained on 5 and 14 days in milk. Dry matter intake (DMI) was increased (P=0.05) in GP-INT cows compared to GP-CONT but not control cows. The yield of fat corrected milk was greater in CTR cows than in GP supplemented cows (P=0.01). The milk protein and fat content were greater for GP-CONT and CTR groups, respectively. Milk somatic cell count was decreased in GP supplemented cows than in CTR cows (64.5 vs. 365×103/mL; P=0.02).Plasma total protein concentration was greater in GP-CONT group. Insulin concentration was increased for GP-CON animals on day 5 (P<0.05). Non-esterified fatty acids and β-hydroxy butyrate as well as liver enzymes were unaltered by treatments. However insulin sensitivity index was lower in supplemented treatments with GP rather than control group (P<0.05). In conclusion, the intermittent delivery of glucogenic precursor may be recommendable in fresh cows based on DMI criteria, which warrants further studies. | ||
| کلیدواژهها | ||
| fresh cow؛ glucogenic precursor؛ hepatic oxidation theory؛ liver enzymes | ||
| اصل مقاله | ||
|
INTRODUCTION At the beginning of lactation, animals face a sudden and drastic increase in energy demand (Herdt, 2000). This demand is coupled with a decrease in feed intake, generally started in the dry period, and subsequently will cause to fat mobilization from the body stores in the form of nonesterified fatty acids (NEFA) to meet energy requirements (Gordon et al. 2013). Insulin resistance in combination with low plasma insulin concentration in the peripartum period will result in elevating plasma NEFA concentration and, in turn, severe fat inflow to liver could cause fatty liver and hence ketosis will develop more severely contemporaneously (DeKoster and Opsomer, 2013). The costs associated with ketosis include treatment of the disease, increased risk and treatment of other diseases, decreased milk production, poor reproductive performance, and a higher risk of culling in the first 30 d of lactation (McArt et al. 2012). Different strategies such as management strategies (Amirabadi Farahani et al. 2017), intra-ruminal boluses technique (Compton et al. 2015) and glucogenic precursor’s supplementation (DeFrain et al. 2004; Chagas et al. 2010) have been considered for improving fresh cows metabolic profiles. Different glucogenic precursors (GPs) such as propylene glycol (PG), glycerol or calcium propionate have been recommended as top-dressing or drenching in early lactating dairy cows to prevent ketosis (McArt et al. 2012; Bjerre-Harpøth et al. 2015). Recently Melendez et al. (2018) cleared that the combination of glucose precursors could improve energy status of cows in fresh period. Using different glucogenic precursors (e.g. propylene glycol, glycerol or calcium propionate) caused in an increase in the glucogenic status that was concurrent with a decrease in the plasma concentrations of β-hydroxy butyrate (BHBA) and NEFA (Formigoni et al. 1996; DeFrain et al. 2004). The main effect of propionate in increasing glucose concentration is via changes hepatic PCK1 mRNA activity (Zhang et al. 2015). In contrast some restrictions may have been considered for GP supplementation, because of their potential toxic side effects including ataxia, salivation, hyperventilation and depression and also pulmonary vasoconstriction (Bertram et al. 2009) that this may be due to the dosage level of supplementation strategy. Therefore in addition to supplemented dosage level, different delivery methods of GP also could be an issue regarding the appetite control. As it has been cleared these products mostly increased blood glucose concentration via increased propionate concentration in rumen fluid (Czerkawski and Breckenridge, 1973). The elevated propionate has potential to reduce intake based on hepatic oxidation theory (HOT); (Allen et al. 2009) through its hypophagic effect. Therefore expectedly greater propionate concentration reduce intake in continuous supplementing the GP sources. Moreover, every other day drenching of GPs may mitigate the labour problems and extra stress on fresh cows. Based on the literature mentioned above, we hypothesized that intermittent way of drenching the GP source may reduce hypophagic effect of propionate, as well as reducing the toxic compounds created in daily drenching of GP that consequently may improve intake, blood metabolites and liver function in fresh cows.
MATERIALS AND METHODS Animal, design and treatment diets The study was conducted at Mayan-Nojen dairy farm, Tehran, Iran. Animals were cared for according to the guidelines of the Iranian Council of Animal Care (1995). Multiparous (averaging ~ 3.5 parity) lactating Holstein cows (n=24) with 3 days in milk were assigned to treatments in a completely randomized design (8 cows per treatment). The animals were fed a basal diet formulated to meet nutrient requirements based on NRC (2001) recommendations. The basal diet and chemical compositions are presented in Table 1. The treatments were: 1) no GP supplementation (CTR), 2) GP offered as an oral drench once a day for 5 consecutive days (GP-CONT), and 3) GP offered as an oral drench once a day, 5 times in an every other day schedule (GP-INT). The GP was drenched at 3th, 4th, 5th, 6th, and 7th DIM for GP-CONT and at 3th, 5th, 7th, 9th, and 11th DIM for GP-INT. The GP consisted of glycerin (500 g/kg), mono-propylene glycol (250 g/kg), calcium propionate (150 g/kg), niacin (1 g/kg) and sulfate-Co (350 mg/kg). The trademark of product was Z-Pro and it has been provided by Pajoohesh-Parvar Zayand Company (Isfahan, Iran). The oral drenching was performed one hour after morning feeding. Water was drenched in CTR animals throughout the study. The cows were fed individually with a total mixed ration (TMR) at 07:00 and 15:00 and had free access to water and NaCl white salt block. Orts were collected and weighed once daily at 0700 and the individual feeding rate was adjusted daily to achieve about 5% orts of intake. After finishing the experiment (14 days) cows were moved to the high-group pen and their milk production and milk components were recorded monthly. There were milked three times per day at 03:00, 11:00 and 19:00.
Experimental procedures and chemical analyses The dry matter (DM) was determined for composites of feed and ort by drying at 60 ˚C for 48 h (AOAC, 2002). Dry matter intake was computed based on the 60 ˚C DM determinations for TMR and orts. Feed samples were taken weekly and composited to one sample. After drying, ingredients and TMR were ground through a 1 mm screen. Milk was sampled on days 3, 5, 8, and 11 after the first day of drenching and samples (from three consecutive milking) were analyzed for fat, protein, and somatic cell counts (SCC) (Milkoscan; Foss Electric, Hillerod, Denmark). Blood was taken 4 h after morning feeding (approximately three hours after GP dosage) from the coccygeal vein of each cow at 5th and 14th DIM. Blood samples were heparinized and stored at 2 ˚C for about 6 h; samples were centrifuged (3000×g 4 ˚C, 20 min) and the harvested plasma was stored at –20 ˚C.
Table 1 Ingredients and chemical composition of basal diet 1 RumiFat R100; it contains minimum 99.5% crude fat. Fatty acid composition: 71-73% C16:0, 4-6% C18:0, 16-18% C18:1, 3-5% C18:2. (Malaysia Palm, Co.). 2 Provided per kg of DM: vitamin A: 500000 IU; vitamin D: 100000 of IU; vitamin E: 1000 mg; P: 9000 mg; Ca: 195000 mg; Mn: 2000 mg; Na: 55000 mg; Zn: 2000 mg; Fe: 2000 mg; Cu: 280 mg; Co: 100 mg; Br: 100 mg; Se: 1 mg and Antioxidant: 3000 mg. 3 NEL: net energy for lactation; estimated using the NRC (2001) model.
The plasma then was analysed to determine the concentration of glucose (kit No. 93008), total protein (TP) (kit No. 9304), Blood urea nitrogen (BUN) (kit No. 93013), triglyceride (TG), and cholesterol using Pars Azmoon kits and associated procedures (Pars Azmoon Co., Tehran, Iran) as described previously (Kazemi-Bonchenari et al. 2017). The mentioned commercial laboratory reagents were used for measuring enzymes aspartate aminotransferase (AST), alanine aminotransferase (ALT), alkaline phosphatase (ALP), and gamma-glutamyl transferase (GGT) using ELIS Aanalyzer (Auto Analyzer Hitachi 717, Japan). Other reagents were used to measure NEFA (Cat. No. FA 115, Randox Laboratories Ltd, UK), BHBA (Abbott Diabetes Care Ltd. Rang Road. Witney, Oxin, OX29 OYL., UK) and insulin (Cat. No. 2425-300A, MonobindInc, Lake Forest, CA, USA) using ELISA analyzer as mentioned above. Insulin sensitivity index was estimate by calculating RQUICKI (revise quantitative insulin sensitivity check index) using data from glucose, NEFA and insulin concentrations based on Holtenius and Holtenius, (2007) with the following equation (1/[log glucose + log insulin + log NEFA]).
Statistical analysis Data were analyzed using Proc. Mixed in SAS (SAS, 2001). The following model was used for variables which were repeated measurements over time: Yijk= μ + Ti + Zk + ZTik + εijk Where: Yijk: dependent variable. μ: overall mean. Ti: effect of treatment i. Zk: effect of time k (sampling dates). ZTik: interaction between time k and treatment i. εijk: residual error. Differences between least squares means were considered significant at P < 0.05, and differences were considered to indicate a trend toward significance at 0.05 < P < 0.10. Contrasts were used to evaluate control vs. GP and continuous vs. intermittent GP drenching.
RESULTS AND DISCUSSION Animal performance Although there was no significant effect of supplementing GP compared to un-supplemented treatment on DMI (P=0.12), but intake was increased with intermittent administration of GP compared to continuously GP feeding (P<0.05; Table 2). Fat-corrected, but not raw, milk was greater (P<0.02; Table 2) in CTR cows compared GP supplemented cows. The milk protein and fat content were greater for GP-CONT and CTR groups (P<0.05) (Table 2). Accordingly, CTR yielded more milk fat (P<0.03). Milk somatic cell count was decreased in GP supplemented cows than in CTR cows (P<0.02). The SCC was significantly decreased in the intermittent delivery of GP (P<0.05). There was no carry-over effect of treatments on productive variables such as milk production and components during month 1-3 after calving (Table 2).
Blood metabolites and insulin concentrations The data for blood metabolites in the current study are presented in Table 3. The concentrations of NEFA, BHBA, TG, BUN, and albumin were not affected by treatments (P>0.05). Direct contrasts showed that blood glucose concentration was the greatest in GP-CONT delivery method (P<0.05) only on d 5 and thoroughout the experiment. Blood TP concentration was increased for GP-CONT delivery and cholesterol concentration was increased for GP-INT delivery method, respectively (P<0.05). The clearest response on insulin was revealed on d 5 and its concentration was increased by drenching GP in both kinds of deliveries compared to control (P<0.004; Table 4), and through the experiment GP-CON was more effective than GP-INT in increasing insulin. Among the measured enzymes GGT, ALT, ALP and AST did not show any significant difference among treatments (P>0.05) (Table 4). The insulin sensitivity index was reduced by GP supplementation compared with control group (P<0.05) (Table 5). This study provides compelling evidence on effective use of glucogenic precursor within optimum choices of time schedule in early lactation. The rate of increase in feed intake postpartum lags behind the demands of lactation, leading to a period of negative energy balance (Gordon et al. 2013). Early lactating dairy cows must accommodate a tremendous increase in energy demand by the mammary gland for milk production with increasing DMI (Nielsen and Ingvartsen, 2004). Therefore, cows should be encouraged to maximize their intake during early lactation. In the present study, DM was increased with an intermittent drenching of GP but not with the continuous delivery method. To perceive and possibly prevent hypophagia, we need to be able to quantify the linkages between mechanisms of intake regulation, metabolism, and the immune system in the dairy cow (Ingvartsen, and Andersen, 2000). The basal diet was similar in the present study and the only variable factor was offering GP method which was continues versus intermittent. Although the volatile fatty acids(VFAs) have not been measured in the present studies, as it has been previously cleared, the main glucogenic precursor product in the rumen is probably propionate when glycerol (Wang et al. 2009) or when PG has been offered (Czerkawski and Breckenridge, 1973). Based on the HOT, among the fuels metabolized by the ruminant liver, propionate is likely a primary satiety signal because its flux to the liver increases greatly during meals (Allen et al. 2009). From the other hand, propionate may changing the hepatic PCK1 mRNA activity that subsequently could positively affect glucose concentration (Zhang et al. 2015). This contradictory effect of propionate may be a function of its concentration in rumen fluid of fresh dairy cows. Because the greatest glucose concentration was observed in GP-CONT delivery method, probably the greatest propionate has been expected to be produced in this treatment. Moreover, the greater observed insulin in GP-CONT treatment may be a factor in lower DMI. Leury et al. (2003) showed that hyper insulinemic-euglycemic clamps increased plasma insulin concentration and decreased DMI 33% in fresh cows. However, it is not likely the reason why DMI increased in GP-INT, because the insulin concentration was similar between CTR and GP-INT groups. Allen et al. (2005) illustrated when glucose demand is high (e.g., early lactation), providing the liver with propionate results in increased gluconeogenesis, in turn enhancing hepatocyte ATP consumption and increasing DMI. Accumulation of tricarboxylic acid cycle intermediates from a reduction of gluconeogenesis from propionate will likely increase oxidation of acetyl CoA, suppressing DMI despite the reduction in plasma NEFA. Accordingly, considering the similar concentrations of NEFA and BHBA across treatments, it appears that continuous delivery of GP has been caused the tricarboxylic acid cycle intermediates to increase, in turn, resulted in lower DMI compared to GP-INT group. Because the second blood sample had been taken at 14th DIM (3 d after last GP drench), we are not able to see how and why DMI was lower for CTR and GP-CONT group based on blood metabolites, which warrants more experiments. Different results for milk yield and composition were achieved when the GP was used in dairy cows. The milk was increased in some studies which the GP has been used in dairy cows (Pickett et al. 2003), but in some others had a tendency towards unchanged or decreased milk yields when PG was allocated (Dhiman et al. 1993; Shingfield et al. 2002).
Table 2 Effect of continuous or intermittent glucogenic precursor (GP) delivery on performance of dairy cows in first two weeks and first three months of lactation
CTR: no GP supplementation; GP-CONT: GP offered as an oral drench once a day on days 3, 4, 5, 6, and 7 after calving and GP-INT: GP offered as an oral drench once a day and every other days on days 3, 5, 7, 9, and 11 after calving. SEM: standard error of the means.
Saleem et al. (2018) concluded that glycerol supplementation could improve dairy buffaloes through improving nutrients digestibility then consequently could affect milk yield and composition. Piantoni and Allen (2015), reported that glucose may be more limiting than protein for milk production during the period immediately after calving; glucose infusion, however, lasted 12 days in that study which is far from our study. In addition, glucose concentration on d 14 was not influenced by treatments which explains why a milk response was not observed in this experiment. The greater fat-corrected milk (FCM) yields from cows fed the control diet were in agreement with DeFrain et al. (2004) and Fisher et al. (1973). Effects of treatments on yields of milk fat had been attributed to the decrease in the ruminal acetate to propionate ratio in DeFrain’s experiment. Griinari and Bauman (2006) stated that a decrease in milk fat yield reduces the energy demand and thus has the potential to provide the cow in early lactation with more latitude to adapt and accommodate metabolic demands. Therefore, such strategies could be carried out as a tool to prevent ketosis and milk fat reduction, which warrants more research. Moreover, the mode of action through improvement of nutrients digestion caused by glucogenic precursor might be a reason for improvement in animal productivity after freshening (Saleem et al. 2018). Considering the blood metabolites, the NEFA concentration was not affected by treatments. It has been shown NEFA and plasma insulin concentrations are inversely related to days (Allen, 2014), but we did not find the similar relationship in this study. The BHBA as well as NEFA, are indicators of energy balance in early lactating dairy cows. It has been shown that the effect of glucogenic precursors on energy balance indices in blood is different, probably due to the physiological status of animal, dosage amount of source, and time of blood sampling after dosing (Nielsen and Ingvartsen, 2004). Cholesterol concentration in blood was increased in GP-INT treatment. Formigoni et al. (1996) reported the higher total cholesterol levels in the plasma of PG treated cows after parturition. Increased gluconeogenesis precursors in the liver could promote cholesterol synthesis and/or release by the hepatocytes (Formigoni et al. 1996). In addition to the positive effects of GP administration in both delivery methods, greater cholesterol level in intermittent compared to continuously offered cows was probably due to greater intake and then greater energy available for the animal. In addition to the mechanisms discussed above, Saleem et al. (2018) postulated that glycerol which is a glucose precursor in fresh buffaloes improved some nutrients digestibility and hence could improve animal productivity. Insulin was increased by offering GP in the present study. Studer et al. (1993) reported that mean plasma insulin concentrations were significantly increased by PG offering in dairy cows. Volatile fatty acids appear to be more potent than glucose with respect to stimulating insulin secretion (Manns et al. 1967; Brockman, 1978). The concentration of VFA is greater in dairy cows offered different glucogenic precursors compared to untreated ones (Czerkawski and Breckenridge, 1973).
Table 3 Effect of continuous or intermittent glucogenic precursor (GP) delivery on blood metabolites of dairy cows at 5 and 14 dry matter intake (DIM) CTR: no GP supplementation; GP-CONT: GP offered as an oral drench once a day on days 3, 4, 5, 6, and 7 after calving and GP-INT: GP offered as an oral drench once a day and every other days on days 3, 5, 7, 9, and 11 after calving. SEM: standard error of the means.
Table 4 Effect of continuous or intermittent glucogenic precursor (GP) delivery on liver enzymes of dairy cows at 5 and 14 dry matter intake (DIM) CTR: no GP supplementation; GP-CONT: GP offered as an oral drench once a day on days 3, 4, 5, 6, and 7 after calving and GP-INT: GP offered as an oral drench once a day and every other days on days 3, 5, 7, 9, and 11 after calving. SEM: standard error of the means.
Table 5 Effect of continuous or intermittent glucogenic precursor (GP) delivery on insulin sensitivity index (RQUICKI) 1 RQUICKI; revised quantitative insulin sensitivity check index; was estimated based on (Holtenius and Holtenius, 2007). CTR: no GP supplementation; GP-CONT: GP offered as an oral drench once a day on days 3, 4, 5, 6, and 7 after calving; GP-INT: GP offered as an oral drench once a day and every other days on days 3, 5, 7, 9, and 11 after calving and DIM: dry matter intake. SEM: standard error of the means.
Therefore, the greater total VFA concentration in the rumen and especially greater propionate ratio (Manns et al. 1967) may have caused to greater insulin concentration. The results show that, regardless of the delivery method of GP, oral drenching of GP increased insulin concentration which between the methods, continuous delivery caused to the greater value. The insulin sensitivity index was reduced by GP supplementation in comparison with control group. However this parameter did not influence with the method of drenching. Based on Holtenius and Holtenius (2007) three different factors contributed to estimation the insulin sensitivity index (i.e. glucose, NEFA and insulin concentration). Looking in to results obtained in the present study, although NEFA concentration was constant among treatments, different insulin as well as glucose concentrations in blood caused to achieve different insulin sensitivity index. The results of the present study clear that GP supplementation could modify insulin sensitivity in fresh dairy cows which granted to do more works. Among different enzymes measured in the present study, none of the enzymes did differ among treatments. This shows that liver did not respond to continuous or intermittent drenching of supplement.
CONCLUSION Compared to intermittent administration of GP into fresh dairy cows, continuous administration increased blood glucose concentration, however reduced DMI. Milk protein positively was affected by continuous dosing as well. The intermittent administration of glucogenic precursor in postpartum dairy cows caused to greater daily feed intake compared to daily administering. In conclusion, intermittent administration of glucogenic precursor may be recommendable in fresh cows to prevent severe negative energy balance by improving intake and temporary reducing FCM production. Further researches are granted to evaluate these two delivery methods for different glucogenic precursors in this critical period of time in dairy cows.
ACKNOWLEDGEMENT The data in this study was developed as part of a research project between Arak University (Arak, Iran) and Danesh-BahavarShaya Company. Special thanks to Dr A. Fazlali, deputy of research in Arak University to facilitate carrying out the present study. The authors express their appreciation to the management board and staff of Mayan-Nojen dairy farm to help in conducting the present study. | ||
| مراجع | ||
|
Allen M.S. (2014). Drives and limits to feed intake in ruminants. Anim. Prod. Sci. 54, 1513-1524.
Allen M.S., Bradford B.J. and Harvatine K.J. (2005). The cow as a model to study food intake regulation. Ann. Rev. Nutr. 25, 523-547.
Allen M.S., Bradford B.J. and Oba M. (2009). Board-invited review: The hepatic oxidation theory of the control of feed intake and its application to ruminants. J. Anim. Sci. 87, 3317-3334.
Amirabadi Farahani T., Amanlou H. and Kazemi-Bonchenari M. (2017). Effects of shortening the close-up period length coupled with increased supply of metabolizable protein on performance and metabolic status of multiparous Holstein cows. J. Dairy Sci. 100, 6199-6217.
AOAC. (2002). Official Methods of Analysis. 17th Ed. Association of Official Analytical Chemists, Arlington, Washington, DC., USA.
Bertram H.C., Petersen B.O., Duss J.Ø., Larsen M., Raun B.M.L. and Kristensen N.B. (2009). Proton nuclear magnetic resonance spectroscopy based investigation on propylene glycol toxicosis in a Holstein cow. Acta Vet. Scandinavica. 51, 25-33.
Bjerre-Harpøth V., Storm A.C., Eslamizad M., Kuhla B. and Larsen M. (2015). Effect of propylene glycol on adipose tissue mobilization in postpartum over-conditioned Holstein cows. J. Dairy Sci. 98, 8581-8596.
Brockman R.P. (1978). Roles of glucagon and insulin in the regulation of metabolism in ruminants. A review. Canadian Vet. J. 19, 55-62.
Chagas L.M., Tunon G.E., Taufa V.K., Burke C.R. and Wahhorn G.C. (2010). Reproductive performance of pasture-fed dairy cows supplemented with monopropylene glycol. New Zealand Vet. J. 58, 17-22.
Compton C.W.R., Young L. and McDougall S. (2015). Efficacy of controlled-release capsules containing monensin for the prevention of subclinical ketosis in pasture-fed dairy cows. New Zealand Vet. J. 63, 249-253.
Czerkawski J.W. and Breckenridge G. (1973). Dissimilation of 1, 2-propanediol by rumen microorganisms. Br. J. Nutr. 29, 317-330.
DeFrain J.M., Hippen A.R., Kalscheur K.F. and Jardon P.W. (2004). Feeding glycerol to transition dairy cows: Effects on blood metabolites and lactation performance. J. Dairy Sci. 87, 4195-4206.
De Koster J.D. and Opsomer G. (2013). Insulin resistance in dairy cows. Vet. Clin. North America: Food Anim. Pract. 29, 299-322.
Dhiman T.R., Cadorniga C. and Satter L.D. (1993). Protein and energy supplementation of high alfalfa silage diets during early lactation. J. Dairy Sci. 76, 1945-1959.
Fisher L.J., Erfle J.D., Lodge G.A. and Sauer F.D. (1973). Effects of propylene glycol or glycerol supplementation of the diet of dairy cows on feed intake, milk yield and composition, and incidence of ketosis. Canadian J. Anim. Sci. 53, 289-296.
Formigoni A., Cornil M.C., Prandi A., Mordenti A., Portetelle D. and Renaville R. (1996). Effect of propylene glycol supplementation around parturition on milk yield, reproduction performance and some hormonal and metabolic characteristics in dairy cows. J. Dairy Res. 63, 11-24.
Gordon J.L., LeBlanc S.T. and Duffield T.F. (2013). Ketosis treatment in lactating dairy cattle. Vet. Clin. North America: Food Anim. Pract. 29, 433-445.
Griinari J.M. and Bauman D.E. (2006). Milk fat depression: Concepts, mechanisms and management applications. Pp. 389-417 in Ruminant Physiology: Digestion, Metabolism and Impact of Nutrition on Gene Expression, Immunologyand Stress. K. Sejrsen, T. Hvelplund and M.O. Nielsen, Eds., Academic Press, Wageningen, Netherlands:.
Herdt T.H. (2000). Ruminant adaptation to negative energy balance. Vet. Clin. North America: Food Anim. Pract. 16, 215-230.
Holtenius P. and Holtenius K. (2007). A model to estimate insulin sensitivity in dairy cows. Acta Vet. Scandinavica. 49, 29-31.
Ingvartsen K.L. and Andersen J.B. (2000). Integration of metabolism and intake regulation: A review focusing on periparturient animals. J. Dairy Sci. 83, 1573-1597.
Iranian Council of Animal Care. (1995). Guide to the Care and Use of Experimental Animals, vol. 1. Isfahan University of Technology, Isfahan, Iran.
Kazemi-Bonchenari M., Salem A.Z.M. and Lopez S. (2017). Influence of barley grain particle and treatment with acetic acid on digestibility, ruminal fermentation and microbial protein synthesis in Holstein calves. Animal. 11, 1295-1302.
Leury B.J., Baumgard L.H., Block S.S., Segoale N., Ehrhardt R.A., Rhoads R.P., Bauman D.E., Bell A.W. and Boisclair, Y.R. (2003). Effect of insulin and growth hormone on plasma leptin in periparturient dairy cows. Am. J. Physiol. Regul. Integr. Comp. Physiol. 285, 1107-1115.
Manns J.G., Bode J.M. and Willis R.F. (1967). Probable role of propionate and butyrate in control of insulin secretion in sheep. Am. J. Physiol. 212, 756-764.
McArt J.A., Nydam D.V. and Oetzel G.R. (2012). A field trial on the effect of propylene glycol on displaced abomasum, removal from herd, and reproduction in fresh cows diagnosed with subclinical ketosis. J. Dairy Sci. 95, 2505-2512.
Melendez P., Severino K., Paz Marin M. and Duchens M. (2018). The effect of a product with three gluconeogenic precursors during the transition period on blood metabolites and milk yield in Chilean Holstein cattle. J. Appl. Anim. Res. 46, 613-617.
Nielsen N. and Ingvartsen K.L. (2004). Propylene glycol for dairy cows. A review of the metabolism of propylene glycol and its effects on physiological parameters, feed intake, milk production and risk of ketosis. Anim. Feed Sci. Technol. 115, 191-213.
NRC. (2001). Nutrient Requirements of Dairy Cattle. 7th Ed. National Academy Press, Washington, DC, USA.
Piantoni P. and Allen M.S. (2015). Evaluation of propylene glycol and glycerol infusions as treatments for ketosis in dairy cows. J. Dairy Sci. 98, 5429-5439.
Pickett M.M., Piepenbrink M.S. and Overton T.R. (2003). Effects of propylene glycol or fat drench on plasma metabolites, liver composition and production of dairy cows during the periparturient period. J. Dairy Sci. 86, 2113-2121.
Saleem A.M., Zanouny A.I. and Singar A.M. (2018). Effect of glycerol supplementation during early lactation on milk yield, milk composition, nutrients digestibility and blood metabolites of dairy buffaloes. Animal. 12, 757-763.
SAS Institute. (2001). SAS®/STAT Software, Release 9.1. SAS Institute, Inc., Cary, NC. USA.
Shingfield K.J., Jaakkola S. and Huhtanen P. (2000). Effect of forage conservation method, concentrate level and propylene glycol on intake, feeding behaviour and milk production of dairy cows. J. Anim. Sci. 74, 383-397.
Studer V.A., Drummer R.R., Bertics S.J. and Reynolds C.K. (1993). Effect of prepartum propylene glycol administration on periparturient fatty liver in dairy cows. J. Dairy Sci. 76, 2931-2939.
Wang C., Liu Q., Huo W.J., Yang W.Z., Dong K.H., Huang Y.X. and Guo G. (2009). Effects of glycerol on rumen fermentation, urinary excretion of purine derivatives and feed digestibility in steers. Livest. Sci. 121, 15-20.
Zhang Q., Koser S.L., Bequette B.L. and Donkin S.S. (2015). Effect of propionate on mRNA expression of key genes for gluconeogenesis in liver of dairy cattle. J. Dairy Sci. 98, 8698-8709. | ||
|
آمار تعداد مشاهده مقاله: 599 تعداد دریافت فایل اصل مقاله: 357 |
||
