Submit Manuscript

International Journal of Dairy Science

Year: 2008 | Volume: 3 | Issue: 2 | Page No.: 93-96
Facebook Twitter Digg Reddit Linkedin StumbleUpon E-mail
Research Article

Evaluation of Nutritional Regime in Small-Scale Dairy Farms in Khartoum State, Sudan

A.M.A. Fadel Elseed, A.G. Mahala and Amel H. El Khaier

ABSTRACT

The objective of this study was to determine whether owners of small-scale dairy farm in Khartoum State feed their animals the required energy and protein. Calculated Crude Protein (CP) and Net Energy for lactation (NEL) requirements of dairy cows in fifty small-scale dairy farms located in Khartoum, Omdurman and Khartoum North were compared with the actual CP and NEL intake during the period of September to November 2006. The experimental design was completely randomized with 3x3 factorial arrangement of treatments. The cows of each locality (Khartoum, Omdurman and Khartoum North) were divided into three groups according to milk yield (low: 0-6 kg day-1; medium: 6-12 kg day-1; high: 12 kg day-1 and more). The average Crude Protein (CP) content of rations was 29.5, 24.66 and 24.05% for Omdurman, Khartoum North and Khartoum, respectively. Both the locality and milk yield had a significant effect (p<0.05) on protein oversupply which was lower for Khartoum (108.4%) than for Omdurman (180%) or Khartoum (141.9%). However, the least protein oversupply was 101.8% for high milk yielding cows. Producers in Omdurman, Khartoum North and Khartoum exceeded the total energy required for lactation by 81.4, 69.7 and 45.1%, respectively. The excess energy reached 100% of the total energy requirement for low milk yielding cows. In conclusion, all producers in small-scale dairy farms in Khartoum State feed their herds excess amounts of CP and energy. Therefore, guidelines need to be developed for optimal production efficiency.
PDF Abstract XML References Citation

INTRODUCTION

There are two major systems of milk production in Sudan, modern and small-scale dairy farms around cities and urban centers, where irrigated forages (forage sorghum, maize, alfalfa and Rhodes grass) and concentrates are used (Habeeb Allah, 1996).

Small-scale dairy farms, where cattle are kept in a courtyard or fenced site and fed purchased fodder plus concentrate, are growing rapidly providing urban centers with most of their needs for milk. Owners of these farms feed their animals undetermined proportions of sorghum grains, wheat bran and oil-seed cakes as main ingredients in group-feeding irrespective of cow productivity.

Productivity of ruminants is influenced primarily by feed intake which in turn is determined by feed digestibility and the capacity of the diet to supply the correct balance of nutrients required by animals in different productive stages (Van Soest, 1994). Therefore, the two major variables that need to be considered are the amounts and balance of nutrients required and the quantitative availability of nutrients from the diet. Feeding crude protein in excess amounts increases energy requirement for the synthesis and excretion of urea from the body and the deficiencies of crude protein reduces digestibility of the diet (Cheek, 2005). Accurate supply of nutrients to cattle can have several positive outcomes. Providing the required nutrients can increase the production potential, reduce feed cost, improve nutrient utilization and reduce nutrient waste and decrease environmental concerns (Kaku et al., 2004). The hypothesis is that the problem behind the weak performance of small-scale dairy farms might be due to the feeding regime adopted in these farms. Therefore, the objective of this study is to quantify feeding practices among small-scale dairy farmers toward using the nutrient requirements.

MATERIALS AND METHODS

Data Collection and Experimental Design
Fifty small-scale dairy farms located in Khartoum (n = 15), Omdurman (n = 17) and Khartoum North (n = 18) with eight cows each, were studied during the period of September to November 2006. Data were collected on each cow by a producer questionnaire: Body weight, parity, milk production, feed consumption, weeks of pregnancy and housing. Diets and milk samples were collected for routine analysis.

The experimental design was completely randomized with 3x3 factorial arrangement of treatments. The cows of each locality (Khartoum, Omdurman and Khartoum North) were divided into three groups according to milk yield (low: 0-6 kg day-1 (n = 140); medium: 6-12 kg day-1 (n = 132); high: 12 kg day-1 and more (n = 128)).

Chemical Analysis
Milk samples were analyzed for milk fat, total protein and urea-N. For feed samples, proximate analysis was carried out according to AOAC (1990).

Metabolizable Energy (ME) for each diet was estimated from the chemical composition according to the following equation:

ME (MJ kg-1) = 0.12CP% + 0.31EE% + 0.05CF% + 0.14 NFE% (MAFF, 1975)

The efficiency of ME used for maintenance and lactation is 0.62 and 0.64, respectively, (Moe and Tyrrell, 1972).

Calculation of Protein and Energy Requirements
NRC (1989, 2001) was used for the prediction of the protein and net energy of lactation (NEL) requirement of dairy cows based upon measurable, or observable, characteristics of dairy cows on test farms.

The calculated protein and NEL requirement is divided into the requirement for milk synthesis, maintenance and body tissue change. The calculated protein and NEL requirements were compared with the actual protein and NEL intake.

Statistical Analysis
Data were statistically analyzed as a 3x3 factorial arrangement in a completely randomized design. The factors were: locality (Khartoum, Omdurman, Khartoum North) and milk yield (low, medium, high). The least significant difference was used to separate the means (Analytical Software, 2000).

The interaction between locality and milk yield was not significant. Therefore, only the differences between the main effects were tested and discussed.

RESULTS AND DISCUSSION

The average crude protein content in the dry matter of the rations was 29.5, 24.66 and 24.05% for Omdurman, Khartoum North and Khartoum, respectively (Table 1). These values are above the critical level (19%) that has been shown to have negative effects on reproduction (Jordan et al., 1983; Elrod and Butler, 1993; Canfield et al., 1990).

Both the locality and milk yield had a significant effect (p<0.05) on protein oversupply (Table 2, 3). The protein oversupply was higher for Omdurman (180.9%) than for Khartoum North (141.9%) and Khartoum (108.4%). However, the protein oversupply was 101.8, 150.6 and 176.8% for high, medium and low milk yielding cows, respectively. Chase (2003) reported that when crude protein intake increases, about 37 to 50% of the N excreted by lactating dairy cows is in the urine. A high proportion of the urinary N is in the form of urea, which can be degraded to ammonia by the urease enzyme in the feces on the barn floor and thus is the primary source of N emissions from a dairy barn and has a negative impact on environment.

Moreover, producers in Omdurman, Khartoum North and Khartoum exceeded the total energy required for lactation by 81.4, 69.7 and 45.1%, respectively. The excess energy reached 100% of the total energy requirement for low milk yielding cows, 53.3% for medium milk yielding and 42.3% for high milk yielding cows. Proper nutritional status is critical for optimal production efficiency in the dairy cow herd, therefore, the increases of CP and NE oversupply may lead to an increment in the diets cost with no benefits gained from this extra cost in addition to the negative impacts on reproduction and environment (Butler, 1998; McCormick et al., 1999; NRC, 2001).

Table 1: Chemical composition (%) and calculated ME (MJ kg-1 DM) of diets used in the evaluated small-scale dairy farms in Khartoum State
Image for - Evaluation of Nutritional Regime in Small-Scale Dairy Farms in Khartoum State, Sudan
OM = Organic Matter, CP = Crude Protein, CF = Crude Fiber, ME = Metabolizable Energy, n = No. of Farms

Table 2:

Effects of locality on protein and energy oversupply (%) in small-scale dairy farms in Khartoum State, Sudan
Image for - Evaluation of Nutritional Regime in Small-Scale Dairy Farms in Khartoum State, Sudan

a-b: Means with different superscript in the same row differ significantly (p<0.05), *: All values are means±SE, n = Number of cows

Table 3: Effects of milk yield on protein and energy oversupply (%) in small-scale dairy farms in Khartoum State, Sudan
Image for - Evaluation of Nutritional Regime in Small-Scale Dairy Farms in Khartoum State, Sudan

a-b: Means with different superscript in the same row differ significantly (p<0.05), *: All values are means±SE, n = Number of cows


In conclusion, producers in small-scale dairy farms in Khartoum State feed their herds` excess amounts of CP and energy following one size fits all approach leading to paying high tax in energy used for urea synthesis and excretion in urine which may have a negative impact on production cost, reproductive performance and environment. Therefore, guidelines need to be developed for better understanding of nutritional needs of the individuals within the cow`s herd for the improvement of economic efficiency for the small-scale dairy farm sector.

REFERENCES

  1. Analytical Software, 2000. Statistics user's manual. Analytical Software. Tallahassee, FL, USA.
  2. Butler, W.R., 1998. Review: Effect of protein nutrition on ovarian and uterine physiology in dairy cattle. J. Dairy Sci., 81: 2533-2539.
    CrossRefDirect Link
  3. Canfield, R.W., C.J. Sniffen and W.R. Butler, 1990. Effects of excess degradable protein on postpartum reproduction and energy balance in dairy cattle. J. Dairy Sci., 73: 2342-2349.
    CrossRefDirect Link
  4. Chase, L.E., 2003. Nitrogen utilization in dairy cows: What are the limits of efficiency? Proceedings of the Cornell Nutrition Conference for Feed Manufactures, October 21-23, 2003, Cornell University, Ithaca, N.Y., USA., pp: 233-245.
  5. Cheek, P.R., 2005. Applied Animal Nutrition Feeds and Feeding. 3rd Edn., Pearson Education, Inc., N.Y., USA.
  6. Elrod, C.C. and W.R. Butler, 1993. Reduction of fertility and alteration of uterine pH in heifers fed excess ruminally degradable protein. J. Anim. Sci., 71: 694-701.
    CrossRefDirect Link
  7. Habeeb Allah, A.M., 1996. Assessment of dairy farming practices in eastern Nile, Khartoum state. M.Sc. Thesis, University of Khartoum, Sudan.
  8. Jordan, E.R., T.E. Chapman, D.W. Holtan and L.V. Swanson, 1983. Relationship of dietary crude protein to composition of uterine secretions and blood in high producing post partum dairy cows. J. Dairy Sci., 66: 1854-1862.
    Direct Link
  9. Kaku, K., A. Ikeguchi, A. Ogino, T. Osada, M. Hojito and K. Shimada, 2004. Achieving a nitrogen balance for Japanese domestic livestock waste: Testing the scenario of planting feed grain in land left fallow. Asian-Aust. J. Anim. Sci., 17: 1026-1032.
    Direct Link
  10. MAFF, 1975. Energy allowance and feeding systems for ruminants. 1st Edn., Technical Bulletin 33, London, UK.
  11. McCormick, M.E., D.D. French, T.F. Brown, G.J. Cuomo and A.M. Chapa et al., 1999. Crude protein and rumen undegradable protein effects on reproduction and lactation performance of Holstein cows. J. Dairy Sci., 82: 2697-2708.
    CrossRefDirect Link
  12. Moe, P.W., W.P. Flatt and H.F. Tyrell, 1972. Net energy value of feeds for lactation. J. Dairy Sci., 55: 945-958.
    CrossRefDirect Link
  13. NRC., 1989. Nutrient Requirements of Dairy Cattle. 6th Edn., National Academy Press, Washington, DC., USA., ISBN: 0309069971.
  14. NRC., 2001. Nutrient Requirements for Dairy Cattle. 7th Edn., National Academy Press, Washington, DC., USA.
  15. Van Soest, P.J., 1994. Nutritional Ecology of the Ruminant Comstock. 1st Edn., Publishing Associates a Division of Cornell University Press. Ithaca and London, pp: 1-373.
  16. AOAC., 1990. Official Methods of Analysis. 15th Edn., Association of Official Analytical Chemists, Washington, DC., USA., Pages: 684.
    Direct Link

Related Articles

Leave a Comment

Your email address will not be published. Required fields are marked *