DETERMINATION OF THE TRUE METABOLIZABLE ENERGY OF SOME NON-CONVENTIONAL AGRO-INDUSTRIAL BY-PRODUCTS

ABSTRACT

An experiment was conducted to determine the metabolizable energy of maize pap waste (MPW) and rice milling waste (RMW) using adult male broiler birds. Eighteen male adult broiler birds were used in the experiment. Eight birds were assigned to each of the feedstuff with two birds left unfed which served as the negative control. Each of the samples was ground, made into slurry and force-fed to sixteen 10-week old finisher broiler birds that had been starved for 30 hours. The droppings were collected quantitatively, dried and the gross energy was determined in a bomb calorimeter. The results show that the gross energy, apparent and true metabolizable energy of MPW (4.01, 2.60 and 3.03kcal/g) were significantly (P<0.05) higher than those of RMW (2.94,

0.8 and 1.09kcal/g), respectively. Prior to the determination of the true metabolizable energy, two experiments were conducted concurrently to evaluate the effects of feeding graded levels of MPW and RMW on the performance of broiler birds. A total of one hundred and forty-four 2-week old broiler birds with average weight of  330g were randomly allocated to four dietary treatments containing 0, 10, 20 and 30% MPW and RMW, respectively. The effect of treatments on the final body weight (FBW), average daily weight gain (DWG), average daily feed intake (DFI), feed conversion ratio (FCR), feed cost per weight gain FC/WG, carcass quality and organ characteristics were determined. Differences in DFI and ADG were not significant (P>0.05). Similarly, the FBW of broilers fed the 0, 10, 20 and 30% MPW (3520g, 3470g and 3500g, respectively) and RMW (3345g, 3329g, 3337g and 3330g, respectively) diets were found to be comparable (P>0.05) within the different groups. However, feed cost per unit weight gain decreased significantly with increasing levels of MPW and RMW in the diets. The lower feed cost per kilogram meat produced on 30% MPW and RMW diets suggest that the wastes are economically viable alternative energy sources. It was concluded that at up to the 30% inclusion level of MPW and RMW in the diets, FBW and FCR were not significantly affected (P>0.05). However, the financial return was positively affected (P<0.05) at this level.

CHAPTER ONE

INTRODUCTION

1.1     Background

Livestock industry in Nigeria is ridden with myriad of problems, which have resulted to a gross shortage of meat and other animal products (Nworgu, 2002). The animal protein intake shortages in Nigeria observed in the early 1970s has progressively worsened till date. The protein intake of an average Nigerian is about

53.8g with only 6.0 – 8.4g per caput per day of animal origin (Egbunike, 1997). CBN (2003) revealed that North America, Western and Eastern European countries consume 66, 39 and 33g of animal protein per head per day respectively; while an average Nigerian consumes 7.5g which is below the recommended level of 27g per caput  per  day.  The  sub-optimal  consumption  of  animal  protein  by  a  large percentage of Nigerian population has challenged not only livestock farmers, but also researchers and policy makers.

Poultry industry is one of the major sources of animal protein and offers the potential for bridging the protein deficiency gap existing in the country. However, the inadequate supply of several grains and protein concentrates for poultry feeding and the keen competition between man and animal for same have become the major obstacle in poultry industry development in Nigeria (PAN, 1985; Ologhobo, 1992). Feed constitute the dominant input in animal production ranging from 65- 75% of the total cost of production. Similarly, feed ingredients account for over

90%  of  compound  feed  industry.  Therefore,  the  relationship  between  feed ingredient and animal product output is both direct and obvious. To depend on alternative sources of ingredients, especially when it encourages a shift to ingredients for which there is less competition, may help if the later is cheap and

sufficiently available (Oluyemi and Roberts, 1979). The future of efficient and profitable poultry production would, therefore, depend on finding cheaper and alternative energy and protein sources to conventional protein and energy feed ingredients.

Recently, much effort is being made to find the possibilities of utilizing agro-industrial by-products in poultry nutrition (Henuk and Dingle, 2003). This could lead to the reduction in the use of conventional feed ingredients such as maize, soybean, sorghum, groundnut, wheat etc (El Boushy and Van der Poel, 2000)  and  help  reduce  pollution  problems,  decrease  feed  cost  and  increase livestock production.

Agro-industrial by-products in Nigeria vary from primary processing of farm produce wastes to wastes from agro-allied industries. Some of these wastes are left unutilized, which often cause environmental pollution and hazard. Those that are utilized do not have their full potentials harnessed. Agro-industrial by-products which can be of tremendous use in the livestock industry for feeding animals include maize pap waste and rice milling waste etc.

Since energy is one of the most expensive segments of a poultry ration, accurate knowledge of the available energy content of feedstuffs is necessary to formulate the most economical least-cost rations and to achieve profitable production.  Supplying  adequate  energy  to  birds  is  one  of  the  most  important aspects of successful management program. It is by knowing and meeting the nutrient  requirements  of  the  bird  that  their  full  genetic  potentialities  can  be realized.

Apparent metabolizable energy (AME) is the most widely used method for evaluating poultry feedstuffs for available energy. However, since Sibbald (1976)

developed a bioassay for true metabolizable energy (TME), a considerable amount of research has been conducted to investigate the assay’s applicability. Sibbald’s method has several advantages over the previous AME assays. It is simple, rapid, and inexpensive. Besides its reported flexibility, reproducibility, and data quality (Sibbald, 1976), the TME assay can be extended to measure bioavailable amino acids (Likuski and Dorrel, 1979; Sibbald, 1979) and lipids (Sibbald and Kramer,

1978) in feedstuffs.

Although  literature  is  replete  of  the  importance  of  energy  in  poultry nutrition, there are two feedstuffs of regional interest that require evaluation for their nutrient composition especially their energy content. For such feedstuffs, knowledge  of  their  available  energy  will  enhance  their  usefulness  in  poultry feeding.

1.2     Statement of the Problem

Most developing countries are facing difficulties in providing sufficient food for their population. The cost of feed is very high and in recent years the price of conventional or basic feeding ingredients has tremendously increased. This has made livestock production very expensive. The growth rate of livestock sector in Nigeria is still below the potentials of the country’s natural and human resources due to high cost of agricultural inputs such as feed and modern equipment.

Ologhobo (1992) highlighted the problems facing animal feed and poultry production in the tropics; amongst which is poor feed quality and escalating prices. It is the need of the time to utilize unconventional feeds like agro-industrial by- products to make a balanced feed especially for poultry production efficiently. Various studies have delved into the area of grain substitution by agro-industrial by-products,  not  directly  used  by  man,  in  animal  diets  (Farrell  et  al.,  1991).

However, information appears minimal on nutritional evaluation of these agro- industrial by-products.

1.3     Objectives of the study

The main objective of this study is to determine the true metabolizable energy of maize pap waste and rice milling waste. The specific objectives of the study include the following:

  To determine the growth response of broiler birds to diets containing graded levels of maize pap waste and rice milling waste

  To  determine  the  effects  of dietary inclusion of maize  pap waste  and  rice milling waste on internal organs and nutrient retention of broiler birds

  To determine the cost effectiveness of feeding broiler starters and finishers with diets containing maize pap waste and rice milling waste.

1.4     Justification

The science of nutrition involves providing a balance of nutrients that best meets the animal’s needs for growth, maintenance and production. For economic reasons, this supply of nutrients should be at least cost, and so we must supply only enough  for  requirements,  without  there  being  any  major  excesses.  It  is  very difficult and very expensive to supply all nutrients at the exact nutrient needs rather we have to oversupply some nutrients in practical situations, in an attempt to meet the limiting nutrients. In poultry diets these limiting nutrients are usually energy and some of the essential amino acids, such as methionine and lysine.

There is an urgent need to increase feed sources of our poultry enterprises because limited feed resource is presently a major problem. The production of

livestock feed in common use such as maize, groundnut, soybean meal etc. have not met the demand for human consumption and so leaves inadequate surplus for large scale poultry production in the tropics.

Agro-industrial by-products and crop residues represent a vast animal feed resource, which are still largely unexploited. Although considerable research have been, and are being carried out on the potentials of these by-products, very little effective practical applications have been achieved. This research work was designed to determine the true metabolizable energy of maize pap waste and rice milling waste. It also investigated the comparative effects of diets containing these agro-industrial by-products on growth performance of broiler birds. Broiler have been chosen for use as experimental animals for this research because of their ability to grow fast and attain slaughter weight within eight weeks can be achieved, then considerable increases in animal production will follow, which will help to reduce the acknowledge animal protein deficit in Nigeria.

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