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Net nutrient absorption and liver metabolism in lactating dairy cows fed supplemental dietary biotin

Published online by Cambridge University Press:  01 March 2007

C. K. Reynolds ,
D. E. Beever ,
W. Steinberg  and
A. J. Packington
C. K. Reynolds*
Affiliation:
School of Agriculture, Policy and Development, The University or Reading, PO Box 237, Earley Gate, Reading, RG6 6AR, UK
D. E. Beever
Affiliation:
School of Agriculture, Policy and Development, The University or Reading, PO Box 237, Earley Gate, Reading, RG6 6AR, UK
W. Steinberg
Affiliation:
DSM Nutritional Products France, NRD/CA, PO Box 170, F-68305, SAINT LOUIS, Cedex, France
A. J. Packington
Affiliation:
DSM Nutritional Products UK Ltd., Deles Road, Heanor Gate, Heanor, Derbyshire, DE75 7SG, UK
*
 E-mail: c.k.reynolds@reading.ac.uk

Abstract

The effect of feeding supplemental biotin on net absorption and metabolism of nutrients by the portal-drained viscera (PDV; the gut, pancreas, spleen and associated fat) and liver of lactating dairy cows was measured. Three cows in early to mid-lactation catheterised for measurements of net nutrient absorption and metabolism by the PDV and liver were fed a total-mixed ration with or without supplemental biotin at 20 mg/day using a switch-back design (ABA v. BAB) with three 2-week periods. There were no effects of feeding biotin on dry matter intake (22.2 kg/day), milk yield (29.5 kg/day) or milk composition. There was also no effect of feeding biotin on net release of glucose by the liver, net liver removal of glucose precursors (propionate, alanine, lactate) or net liver release of β-hydroxybutyrate. Feeding biotin increased net PDV release of ammonia. Reasons for the response are not certain, but a numerical increase in net PDV release of acetate suggests that rumen or hindgut fermentation was altered. Results of the present study do not support the hypothesis that supplemental biotin increases liver glucose production in lactating dairy cows.

Keywords

biotindairy cowslactationliverportal-drained viscera
Type
Research Paper
Information
animal , Volume 1 , Issue 3 , March 2007 , pp. 375 - 380
Copyright
Copyright © The Animal Consortium 2007

Introduction

Biotin is synthesised by rumen micro-organisms and thus has not been considered an essential ingredient in ruminant diets. Textbooks state unequivocally that the ‘evidence indicates that supplementary feeding (of B-complex vitamins) is of little value unless some unusual condition prevails’ (Church, Reference Church1979). This view has now been challenged as regards to the potential benefit of supplemental B-complex vitamins in lactating dairy cows (Girard, Reference Girard1998). It is well documented that long-term biotin supplementation can have positive effects on hoof health in pigs (Webb et al., Reference Webb, Penny and Johnston1984) and horses (Comben et al., Reference Comben, Clark and Sutherland1984). More recently, studies in lactating dairy cows have consistently demonstrated a positive effect of supplemental biotin on hoof growth, integrity, and the incidence of lameness (Midla et al., Reference Midla, Hoblet, Weiss and Moeschberger1998; Fitzgerald et al., Reference Fitzgerald, Norton, Elliott, Podlich and Svendsen2000; Hedges et al., Reference Hedges, Blowey, Packington, O'Callaghan and Green2001; Bergsten et al., Reference Bergsten, Greenough, Gay, Seymour and Gay2003). In some of these studies (Midla et al., Reference Midla, Hoblet, Weiss and Moeschberger1998; Bergsten et al., Reference Bergsten, Greenough, Gay, Seymour and Gay2003) and others (Bonomi et al., Reference Bonomi, Quarantelli, Sabbioni and Superchi1996; Zimmerly and Weiss, Reference Zimmerly and Weiss2001; Majee et al., Reference Majee, Schwabb, Bertics, Seymour and Shaver2003), supplemental biotin also increased milk yield, although the effect was not consistent across all studies (Fitzgerald et al., Reference Fitzgerald, Norton, Elliott, Podlich and Svendsen2000; Rosendo et al., Reference Rosendo, Staples, McDowell, McMahon, Badinga, Martin, Shearer, Seymour and Wilkinson2004). Although improved hoof health would ultimately benefit both dry-matter intake and milk yield, the response in milk yield to supplemental biotin is more rapid than improvements in hoof integrity, and can occur without changes in DMI (Zimmerly and Weiss, Reference Zimmerly and Weiss2001), suggesting a metabolic effect.

Ruminants normally absorb little glucose from the small intestine, thus glucose requirements are met primarily by liver production (Reynolds, Reference Reynolds, Engelhardt, Leonhard-Marek, Breves and Giesecke1995). Biotin is a cofactor for two carboxylase enzymes required for glucose synthesis in the liver, pyruvate carboxylase and propionyl-CoA carboxylase. In nonruminants, biotin deficiency has been associated with an inhibition of gluconeogenesis and reduced blood glucose levels (Bender, Reference Bender1999). The effect of supplemental biotin on milk yield has been attributed to an effect on rumen fermentation and digestion, glucose production in the liver, or metabolic effects on nutrient partitioning and milk synthesis (Zimmerly and Weiss, Reference Zimmerly and Weiss2001). The objective of the present study was to determine the effect of supplemental biotin on net absorption and liver metabolism of glucose, glucose precursors and other products of digestion and gut metabolism.

Material and methods

Animals

Three Holstein ×  Friesian cows in their third, fourth or fifth lactation were used. Cows were 36, 71 or 174 days post partum and 670 ± 9 kg body weight at the beginning of the first experimental period. At the end of the study they averaged 661 ± 9 kg body weight. Cows were surgically prepared with a rumen fistula and catheters for measurement of net absorption and metabolism of nutrients by the portal-drained viscera (PDV: the tissues of the gastrointestinal tract, pancreas, spleen and associated fat) and liver as described by Huntington et al. (Reference Huntington, Reynolds and Stroud1989). Surgeries were conducted from 25 to 31 months prior to the beginning of the present study; therefore, cows had completed two entire lactations and a number of previous studies of nutrient metabolism (Reynolds et al., Reference Reynolds, Humphries, Cammell, Benson, Sutton, Beever, McCracken, Unsworth and Wylie1998, Reference Reynolds, Lupoli, Aikman, Humphries, Crompton, Sutton, France, Beever and MacRae1999 and Reference Reynolds, Lupoli, Aikman, Benson, Humphries, Crompton, France, Beever and MacRae2000; Benson et al., Reference Benson, Reynolds, Aikman, Lupoli and Beever2002) between surgery and the present study. Cows were housed, fed and milked in individual standings employing head halters or neck yokes allowing continuous access to water and trace mineralised salt blocks. Cows were milked twice daily at 0600 and 1700 h, weighed weekly and allowed grazing when not on experiment. All procedures used were licensed under the Animal Scientific Procedures Act (1986) and cows were under the routine care and inspection of a herd veterinarian and a Home Office Veterinary inspector.

Diets

Cows were fed a basal total-mixed ration containing 300, 200, and 500 g per kg dry matter (DM) of dehydrated lucerne, grass silage, and cereal-based concentrates (Table 1), respectively. Based on the measured chemical composition of ingredients (Table 2) the total mixed ration DM fed averaged 178 g crude protein, 158 g starch, 369 g neutral-detergent fibre and 232 g acid-detergent fibre per kg DM. Daily rations were fed as 24 equal meals provided hourly to minimise post-prandial fluctuations in nutrient absorption and metabolism. Refusals were removed at 0730 h and feeding of a day's ration began at 0800 h.

Table 1 Formulation of the total mixed ration fed

1 ‘Hippoluz’, Dengie Crops Ltd., Southminster, UK.

2 Labelled as containing 180 g calcium (as dicalcium phosphate and limestone), 120 g phosphorus (as dicalcium phosphate), 50 g magnesium (as magnesium oxide and magnesium phosphate), 1.5 g copper (as copper sulphate), 0.015 g selenium (as sodium selenite), 380 000 IU vitamin A, 80 000 IU vitamin D3, 550 IU vitamin E per kg.

Table 2 Composition (g/kg dry matter) of the forages and concentrate mixture fed

Not determined.

Treatments

Cows were fed 20 mg supplemental biotin daily in 500 g ground wheat or 500 g ground wheat as a control in a switch-back design with three 2-week periods (ABA v. BAB). Two cows received the control treatment in the first period, and one received the biotin treatment first. The control wheat carrier used was derived from the same batch used as the carrier for the biotin. To reduce the risk of mistakes in feeding supplements the biotin supplement included trace amounts of CrO3 to impart a green colour. Supplements were added to the total mixed ration daily and for the duration of the study basal ration DM offered was held at 97% of ad libitum intake for the week immediately preceding the first period of the study. This was to ensure complete consumption of the biotin supplement and minimise variation in liver and PDV metabolism due to changes in intake.

Measurements

Milk yield and DM intake were measured daily throughout the study. During the last week of each period forage and concentrate samples were obtained daily, analysed for DM content and then composited, dried at 60 °C, ground and analysed for chemical composition by a commercial laboratory (Natural Resources Management, Ltd., Bracknell, UK). Any refusals were weighed and analysed for DM content. Milk samples were obtained over the last 7 days of each period, treated with preservative (1 mg/ml potassium dichromate; Lactabs, Thompson and Capper, Runcorn, UK) and stored at 4 °C until analysed for crude protein, fat and lactose content by infrared spectroscopy (Foss Electric, Ltd, UK).

Measurements of blood flow and net nutrient metabolism by the PDV, liver and total-splanchnic (PDV plus liver) tissues were obtained on the last day of each period using methods described previously (Huntington et al., Reference Huntington, Reynolds and Stroud1989; Reynolds et al., Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Eight simultaneous blood sample sets (20 ml) from the mesenteric artery and portal and hepatic veins were obtained hourly beginning at 0730 hours during continuous mesenteric vein infusion of sterile ρ-aminohippurate (PAH; a marker for blood flow measurements) solution. Anaerobic blood samples (2 ml) were also obtained for immediate analysis of pO2, pCO2 and pH (Reynolds et al., Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Blood samples were immediately placed on ice and kept chilled until processed, analysed or frozen. Plasma concentrations of PAH, glucose, and l-lactate were obtained as soon as possible using assays adapted for use on a discrete analyser (Cobas-MIRA, Roche, Welwyn Garden City, UK) as described (Reynolds et al., Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Fresh blood samples were analysed for packed cell volume by micro-centrifugation and haemoglobin using a colorimetric assay and blood O2 and CO2 content calculated as described by Reynolds et al. (Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Blood sample aliquots were pooled by sample site for each cow observation (n = 9), deproteinised, neutralised, and stored frozen in aliquots at − 85 °C until assayed for concentrations of ammonia, l-alanine, l-glutamate, l-glutamine and ß-OH-butyrate as described by Reynolds et al. (Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Additional pools of blood samples were analysed for volatile fatty acid (VFA) concentrations as described by Reynolds et al. (Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003).

Calculations

Blood and plasma flow for the portal vein and liver and calculations of net PDV, liver and total splanchnic (PDV plus liver) flux of nutrients and blood gasses were calculated as described (Reynolds et al., Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003). Using venous-arterial differences, a negative flux denotes net removal of a metabolite from blood supply, whilst a positive flux denotes net release of a metabolite into venous blood. Net flux rates represent the sum of unidirectional uptake and release and therefore may underestimate unidirectional uptake and release for many metabolites when tissues as heterogenous as the PDV and liver are concerned. Net liver extraction as a percentage of total supply and net PDV release were also calculated (Reynolds et al., Reference Reynolds, Aikman, Lupoli, Humphries and Beever2003).

Statistical analysis

There were no missing blood samples. Averages for each cow-sampling period were statistically analysed using the mixed procedure of Statistical Analysis Systems Institute (2006) and a model testing fixed effects of period and treatment and random effects of cow and the cow by period interaction as described by Templeman (Reference Templeman2004). Data are presented as least squares means with the standard error of the control mean. Because the number of observations is small, P < 0.10 is considered significant.

Results

There was no effect of biotin supplementation on body weight, DMI, milk yield or milk composition (Table 3). Blood and plasma flow and packed cell volume were also unaffected by biotin (Table 4). Similarly, arterial concentrations of most metabolites (Table 4) were not affected by biotin supplementation; however, the arterial concentration of O2 and haemoglobin tended to increase when supplemental biotin was fed (P = 0.11 and P = 0.14, respectively).

Table 3 Body weight, dry-matter intake (DMI) and milk yield, composition and component yield in lactating dairy cows fed a diet without (control) or with supplemental biotin

Fat-corrected (40 g/kg) milk yield.

Table 4 Blood and plasma flows and packed cell volume in lactating dairy cows fed a diet without (control) or with supplemental biotin

Average for arterial and hepatic and portal vein blood.

Supplemental biotin increased (P < 0.10) net PDV release of ammonia (Table 5), but the net flux of other metabolites across the PDV was not affected. Similarly, the net flux of metabolites measured across the liver and total splanchnic tissues, and the fractional removal of lactate, alanine and ammonia by the liver, were not affected by biotin supplementation There was no effect of supplemental biotin on net liver release of glucose, or removal of the glucose precursors alanine and lactate. Arterial concentrations and net fluxes of VFA across the PDV, liver and total splanchnic tissues (Table 6) and the fractional net extraction of VFA by the liver (Table 7) were not affected by supplemental biotin, although there was a numerical increase in net liver removal of i-valerate (P = 0.20) when biotin was added to the diet.

Table 5 Net splanchnic metabolism and liver extraction of nutrients in lactating dairy cows fed a diet without (control) or with supplemental biotin

Table 6 Arterial concentration and net flux of blood volatile fatty acids in lactating dairy cows fed a diet without (control) or with supplemental biotin

Table 7 Net liver extraction of blood VFA as a percentage of net PDV release or total blood supply in lactating dairy cows fed a diet without (control) and with supplemental biotin

Discussion

Milk yield

The present study was designed to determine effects of biotin on nutrient absorption and liver metabolism, and not feed intake and milk production. Therefore, DM offered was restricted to just below ad libitum and not altered over the course of the study to reduce variation in nutrient absorption and metabolism by splanchnic tissues attributable to DMI. In dairy cows fed ad libitum, supplemental biotin has typically increased milk yield (Bonomi et al., Reference Bonomi, Quarantelli, Sabbioni and Superchi1996; Midla et al., Reference Midla, Hoblet, Weiss and Moeschberger1998; Zimmerly and Weiss, Reference Zimmerly and Weiss2001; Bergsten et al., Reference Bergsten, Greenough, Gay, Seymour and Gay2003; Majee et al., Reference Majee, Schwabb, Bertics, Seymour and Shaver2003) but the effect has not been observed in every study reported (Fitzgerald et al., Reference Fitzgerald, Norton, Elliott, Podlich and Svendsen2000; Rosendo et al., Reference Rosendo, Staples, McDowell, McMahon, Badinga, Martin, Shearer, Seymour and Wilkinson2004). In the present study, the lack of a milk yield response to supplemental biotin may have been due to the restricted DMI of the cows, or the length of supplementation (14 days) may have been too short to allow for effects on milk yield. However, in a recent study Ferreira (Reference Ferreira2006) measured an increase in milk yield within 2 days of the start of biotin supplementation in higher yielding (43 kg/day) cows in early lactation, but no effect of biotin on milk yield in lower yielding (23 kg/day) cows in late lactation.

Glucose metabolism

There was no effect of feeding 20 mg/day supplemental biotin for 2 weeks on net liver release or plasma concentrations of glucose in these cows. In the present study there was no effect of supplemental biotin on milk or milk lactose yield, thus no apparent effect on glucose requirement. It is unlikely that in these cows near or well past peak diet intake that the supply of glucose precursors was limiting. Therefore, it is unlikely that liver glucose synthesis was limiting milk production. A positive effect of biotin on glucose synthesis in the liver in non-ruminants may be a consequence of the repletion of a biotin deficiency limiting the activity of gluconeogenic enzymes, rather than a promotion of carboxylase activity per se (Bender, Reference Bender1999).

Reasons for the increase in jugular vein plasma glucose concentration reported by Bonomi et al. (Reference Bonomi, Quarantelli, Sabbioni and Superchi1996) and Rosendo et al. (Reference Rosendo, Staples, McDowell, McMahon, Badinga, Martin, Shearer, Seymour and Wilkinson2004) are not certain. An increased supply of oxaloacetate via a stimulation of carboxylase activity in the liver would only be used for glucose synthesis if the additional oxaloacetate was required (Reynolds, Reference Reynolds, Engelhardt, Leonhard-Marek, Breves and Giesecke1995). The lack of an effect of supplemental biotin on liver lactate, alanine or β-hydroxybutyrate metabolism suggests there was little change in the utilisation of pyruvate, as the net flux of these metabolites across the bovine liver are sensitive indicators of pyruvate and redox status (Reynolds, Reference Reynolds, Engelhardt, Leonhard-Marek, Breves and Giesecke1995).

Nitrogen metabolism

Effects of biotin supplementation on ammonia absorption by the PDV were not expected. The magnitude of the increase was much greater than the amount of nitrogen (N) in biotin fed, and was accompanied by a numerical increase in liver ammonia removal. The increase in ammonia absorption when biotin was fed may be attributable to changes in PDV tissue metabolism, fermentation in the rumen or hindgut, or an increase in the cycling of urea N to the gut lumen (via saliva or direct transfer from blood). Urea transfer to the rumen is influenced by a number of factors including fermentable energy and urease activity. Biotin supplementation may have improved microbial energy supply and growth, but this would be expected to decrease net PDV absorption of ammonia as observed when starch was infused into the rumen or abomasum of lactating dairy cows (Reynolds et al., Reference Reynolds, Humphries, Cammell, Benson, Sutton, Beever, McCracken, Unsworth and Wylie1998).

Volatile fatty acid metabolism

Previous studies in vitro have demonstrated positive effects of biotin on microbial degradation of cellulose, which would cause a relative increase in VFA production (Milligan et al., Reference Milligan, Asplund and Robblee1967; Baldwin and Allison, Reference Baldwin and Allison1983). However, apart from numerical increases in net acetate, i-valerate and total VFA release by the PDV, there was no evidence that feeding biotin altered rumen or post-rumen fermentation. Similarly, there was no effect of feeding biotin on rumen VFA proportions (Zimmerly and Weiss, Reference Zimmerly and Weiss2001) or total tract fibre digestion (Majee et al., Reference Majee, Schwabb, Bertics, Seymour and Shaver2003).

Conclusions

Feeding supplemental biotin for 2 weeks to lactating dairy cows had no measurable effect on milk production, net glucose production by the liver, or circulating glucose concentrations in blood plasma. This indicates that biotin status in these cows did not limit liver pyruvate and proprionyl-CoA carboxylase function, or that the supply of glucose precursors was not limiting liver glucose production. Surprisingly, feeding 20 mg biotin per day increased net absorption of ammonia N by the PDV. Reasons for these responses are not certain, but a numerical increase in acetate absorption suggests an alteration in rumen fermentation occurred. The results of the present study do not support the hypothesis that feeding supplemental biotin to lactating dairy cows increases glucose production by the liver.

Acknowledgements

The laboratory support of Drs. Berit Lupoli and Patricia Aikman are gratefully acknowledged, as are the dedicated support of Dave Humphries and the technical staff of the CEDAR Metabolism Unit in the daily management and care of cows and conduct of this study. The analysis of milk samples by staff of the Faculty Analytical Laboratory is also greatly appreciated.

References

Baldwin, RL and Allison, MJ 1983. Rumen metabolism. Journal of Animal Science 57, (suppl. 2) 461-477.Google Scholar
Bender, DA 1999. Optimum nutrition: thiamin, biotin and pantothenate. Proceedings of the Nutrition Society 58, 427-433.CrossRefGoogle ScholarPubMed
Benson, JA, Reynolds, CK, Aikman, PC, Lupoli, B and Beever, DE 2002. Effects of abomasal long chain fatty acid infusion on splanchnic nutrient metabolism in lactating dairy cows. Journal of Dairy Science 85, 1804-1814.Google Scholar
Bergsten, C, Greenough, PR, Gay, JM, Seymour, WM and Gay, CC 2003. Effects of biotin supplementation on performance and claw lesions on a commercial dairy farm. Journal of Dairy Science 86, 3953-3962.Google Scholar
Bonomi, A, Quarantelli, A, Sabbioni, A and Superchi, P 1996. L'intergrazione della razioni per le bovine da latte con biotina in forma rumino-protetta. Effetti sull'efficienza produttiva e riproduttiva. La Rivista di Scienza dell'Alimentazione 25, 49-68.Google Scholar
Church, DC 1979. Digestive physiology and nutrition of ruminants, vol. 2 – nutrition. O & B Books, Inc., Corvallis, OR, USA.Google Scholar
Comben, N, Clark, RJ and Sutherland, DJB 1984. Clinical observations on the response of equine hoof defects to dietary supplementation with biotin. Veterinary Record 115, 642-645.Google Scholar
Ferreira, G 2006. Effect of biotin supplementation on the metabolism of lactating dairy cows. Ph.D. dissertation, The Ohio State University, Columbus, Ohio.Google Scholar
Fitzgerald, T, Norton, BW, Elliott, R, Podlich, H and Svendsen, OL 2000. The influence of long-term supplementation with biotin on the prevention of lameness in pasture fed dairy cows. Journal of Dairy Science 83, 338-344.CrossRefGoogle ScholarPubMed
Girard, CL 1998. The B-complex vitamins for dairy cows: a new approach. Canadian Journal of Animal Science 78, SS71-90.Google Scholar
Hedges, J, Blowey, RW, Packington, AJ, O'Callaghan, CJ and Green, LE 2001. A longitudinal field trial of the effect of biotin on lameness in dairy cows. Journal of Dairy Science 84, 1969-1975.CrossRefGoogle ScholarPubMed
Huntington, GB, Reynolds, CK and Stroud, B 1989. Techniques for measuring blood flow in splanchnic tissues of cattle. Journal of Dairy Science 72, 1583-1595.Google Scholar
Majee, DN, Schwabb, EC, Bertics, SJ, Seymour, WM and Shaver, RD 2003. Lactation performance by dairy cows fed supplemental biotin and B-vitamin blend. Journal of Dairy Science 86, 2106-2112.Google Scholar
Midla, LT, Hoblet, KH, Weiss, WP and Moeschberger, ML 1998. Supplemental dietary biotin for prevention of lesions associated with aseptic subclinical laminitis (pododermatitis aseptica diffusa) in primiparous cows. American Journal of Veterinary Research 59, 733-738.CrossRefGoogle ScholarPubMed
Milligan, LP, Asplund, JM and Robblee, AR 1967. In vitro studies on the role of biotin in the metabolism of rumen microorganisms. Canadian Journal of Animal Science 47, 57-64.Google Scholar
Reynolds, CK 1995. Quantitative aspects of liver metabolism in ruminants. In Ruminant physiology: digestion, metabolism, growth and reproduction. Proceedings of the eighth international symposium on ruminant physiology (eds Engelhardt, Wv, Leonhard-Marek, S, Breves, G and Giesecke, D), pp. 351-372, Ferdinand Enke Verlag, Stuttgart, Germany.Google Scholar
Reynolds, CK, Aikman, PC, Lupoli, B, Humphries, DJ and Beever, DE 2003. Splanchnic metabolism of dairy cows during the transition from late gestation through early lactation. Journal of Dairy Science 86, 1201-1217.Google Scholar
Reynolds, CK, Humphries, DJ, Cammell, SB, Benson, JA, Sutton, JD and Beever, DE 1998. Effects of abomasal wheat starch infusion on splanchnic metabolism and energy balance of lactating dairy cows. In Energy metabolism of farm animals, proceedings of the 14th symposium on energy metabolism (ed. McCracken, KJ, Unsworth, EF and Wylie, ARG), pp. 39-42, CAB International, Wallingford, UK.Google Scholar
Reynolds, CK, Lupoli, B, Aikman, PC, Benson, JA, Humphries, DJ, Crompton, LA, France, J, Beever, DE and MacRae, JC 2000. Effects of diet protein level and abomasal amino acid infusions on splanchnic metabolism in lactating dairy cows. Journal of Dairy Science 83, (suppl. 1) 299.Google Scholar
Reynolds, CK, Lupoli, B, Aikman, PC, Humphries, DJ, Crompton, LA, Sutton, JD, France, J, Beever, DE and MacRae, JC 1999. Effects of abomasal casein or essential amino acid infusions on splanchnic metabolism in lactating dairy cows. Journal of Animal Science 77, (suppl. 1) 266.Google Scholar
Rosendo, O, Staples, CR, McDowell, LR, McMahon, R, Badinga, L, Martin, FG, Shearer, JF, Seymour, WM and Wilkinson, NS 2004. Effects of biotin supplementation on peripartum performance and metabolites of Holstein cows. Journal of Dairy Science 87, 2535-2545.Google Scholar
Statistical Analysis Systems Institute 2006. Version 9.1.3. SAS Institute Inc., Cary, NC, USA.Google Scholar
Templeman, RJ 2004. Experimental design and statistical methods for classical and bioequivalence hypothesis testing with an application to dairy nutrition studies. Journal of Animal Science 82, (E. suppl.) E162-E172.Google Scholar
Webb, NG, Penny, RHC and Johnston, AM 1984. Effect of dietary supplement of biotin on pig hoof horn strength and hardness. Veterinary Record 114, 185-189.CrossRefGoogle ScholarPubMed
Zimmerly, CA and Weiss, WP 2001. Effects of supplemental dietary biotin on performance of Holstein cows during early lactation. Journal of Dairy Science 84, 498-506.Google Scholar
Figure 0

Table 1 Formulation of the total mixed ration fed

Figure 1

Table 2 Composition (g/kg dry matter) of the forages and concentrate mixture fed

Figure 2

Table 3 Body weight, dry-matter intake (DMI) and milk yield, composition and component yield in lactating dairy cows fed a diet without (control) or with supplemental biotin

Figure 3

Table 4 Blood and plasma flows and packed cell volume in lactating dairy cows fed a diet without (control) or with supplemental biotin

Figure 4

Table 5 Net splanchnic metabolism and liver extraction of nutrients in lactating dairy cows fed a diet without (control) or with supplemental biotin

Figure 5

Table 6 Arterial concentration and net flux of blood volatile fatty acids in lactating dairy cows fed a diet without (control) or with supplemental biotin

Figure 6

Table 7 Net liver extraction of blood VFA as a percentage of net PDV release or total blood supply in lactating dairy cows fed a diet without (control) and with supplemental biotin