Livestock Research for Rural Development 18 (2) 2006 Guidelines to authors LRRD News

Citation of this paper

Effect of increasing offer level of water spinach (Ipomoea aquatica) on intake, growth and digestibility coefficients of rabbits

Pok Samkol, T R Preston1 and J Ly2

Center for Livestock and Agriculture Development (CelAgrid-UTA Cambodia), Cambodia
samkolpok@yahoo.com
1UTA (Colombia), Socorro, Santander, Colombia
trpreston@mekarn.org
2 Swine Research Institute, PO Box 1, Punta Brava, Havana City, Cuba
jlyca@yahoo.com  ,   iip@enet.cu

Abstract

Twelve New Zealand White rabbits with an initial live weight of 897 ± 95.2 g were allocated to a randomized block design to study the effect of different levels of water spinach (Ipomoea aquatica) (8, 10, 12, 14, 16 and 18% of live weight in DM). The water spinach was taken from the first and second harvests of plants established in CelAgrid-UTA Cambodia, after 30 days of first growth (or regrowth).

Increasing the offer level of water spinach from 8 to 18% of live weight (DM basis) increased the proportion of leaf consumed, the intake of crude protein and the digestibility of the DM and the crude protein. Digestibility of crude fiber decreased with increase in the proportion of leaves consumed. Live weight gain was depressed with increasing offer level apparently because of a decrease in the crude fiber content of the diet, as with increasing offer level the rabbits selected "low-fiber" leaves rather than "high-fiber" stems.

It is concluded that fresh water spinach as the sole feed of rabbits can support acceptable growth rates of 14 to 20g/day with DM feed conversion between 3.83 and 5.18. The crude fiber level in water spinach appears to be too low to support maximum performance and better results may be achieved by providing supplementary feed sources that are high in fiber.

Keywords: digestibility, feed conversion, feed offer level, rabbits, weight gain, selection, water spinach (Ipomoea aquatica)


Introduction

The demand for human food from animal products (meat, egg and milk) is increasing year by year (Delgado et al 1999) but it is predicted and that there will be a world shortage of cereal grain due to the competing needs of expanding human and livestock populations (Leng 2002). There is therefore a need for research in order to develop systems of animal production based on locally available resources.

Rabbit meat is very nutritious. The meat is rich in protein and low in fat and cholesterol. On the other hand, rabbits have the ability to consume directly forage proteins and convert this to animal protein, while swine and poultry rely mainly on cereal grains to meet their dietary protein needs. Hence, rabbit meat is often referred to as an inexpensive protein source (Lukefahr 1992).

Water spinach is an herbaceous trailing vine that dwells in muddy stream banks, freshwater ponds, and marshes. This perennial aquatic vine is confined to the tropics and subtropics because it is susceptible to frosts and does not grow well when temperatures are below 24 0C. Water spinach can reproduce sexually by producing one to four seeds in fruiting capsules or vegetatively by stem fragmentation (Dressler 1996). Some preliminary researches have been conducted on the use of water spinach as a basal diet for rabbit production (Miech Phalla 2002, unpublished data; Honthong Phimmasan et al 2004; Vo Thi Tuyet Nga 2004; Pok Samkol et al 2006) which indicate the potential of this feed as an alternative to conventional diets, which usually consist of pelleted mixtures of concentrates and forages such as alfalfa (Lebas et al 1997).

The biomass yield of water spinach has been shown to respond dramatically to fertilization with biodigester effluent (Kean Sophea and Preston 2001; Ho Bunyeth 2003; Ly Thi Luyen 2003), with increasing concentration of crude protein in the dry matter.

The aim of this experiment was to measure the response of water spinach to fertilization with biodigester effluent and to study the effect of different offer levels of water spinach on performance traits and digestibility coefficients of rabbits.


Materials and Methods

Location and climate

The present investigation was carried out in the site of the ecological farm of the Center for Livestock and Agriculture Development (CelAgrid-UTA Cambodia), located in Rolous village, Rolous commune, Kandal Stoeung district, Kandal province, 26 km from Phnom Penh. During the conduct of this study (16 September to 15 November 2004) average air temperature, as measured daily at 12:00, was 30.7 ± 0.89 0 C.

Experimental design

Twelve New Zealand White rabbits with average live weight of 897 ± 95.2 g were used in this experiment to determine growth performance and digestibility coefficients, according to a Randomized Block design (Table 1). The animals were weighed every five days. They were confined in cages constructed from wood and bamboo with dimensions of length 0.5 m, width 0.5 m and height 0.5 m.

Table 1. Layout of experiment

 

WS8

WS10

WS12

WS14

WS16

WS18

Block 1 (cages 1 to 6)

4

7

8

3

11

6

Block 2 (cages 7 to 12)

9

2

1

10

5

12

The treatments were:

Feeds and feeding system

Water spinach was grown in soil plots, situated in the CeAgrid-UTA Cambodia station. Plot size for the water spinach was 3 m². Effluent from biodigesters charged with pig manure was used to fertilize the water spinach. Level of effluent N was 150 kg/ha during the monthly growth cycle of the water spinach. Water spinach was harvested at a level of 1 cm above soil level, to ensure good re-growth.

The water spinach (combined stems and leaves) was offered as bunches hanging from the side of the cage. It was fed to the rabbits three times per day in the morning at 8:00 am, 12:00 am and in the afternoon at 4:00 pm. Water was not supplied as earlier observations (Miech Phalla, personal communication) indicated that rabbits have the ability to consume water from the feed to their needs as water spinach has a moisture content of almost 90%.

Data collection of growing water spinach

The fresh biomass yield of the water spinach was determined by weighing the fresh foliage at each of two harvests. Samples were separated into leaves and stems and these portions analysed for DM, N and organic matter. Samples of biodigester effluent were analysed for N.

Digestibility studies

The acid insoluble ash content of feeds and faeces was estimated according to Van Keulen and Young (1977) in the days 30 and 60 of the feeding trial. Faeces were obtained in the morning before distribution of the feed. Feed refusals were collected every day and kept frozen in plastic bags until analysis. After thawing the samples, they were mixed thoroughly by hand and pooled, ground in a coffee grinder in the fresh state and, thereafter, representative samples were used for chemical analysis.

Chemical analyses

Analysis of DM in feeds and faeces was determined by drying to constant weight by microwave radiation (Undersander et al 1993). The ash, crude fiber and N content of samples were assayed using AOAC (1990) procedures. The organic matter of feeds and faeces was calculated as 100 minus % ash.

The digestibility coefficients were calculated by standard procedures following the method of indirect digestibility (Crampton and Harris 1969), using the acid insoluble ash as inert marker. The calculation of digestibility of DM was as follows:

DM digestibility (%) = (1- A/B)*100,

where A and B are the acid insoluble ash concentrations in feed and faeces, respectively.

The digestibility of other nutrients (X) was calculated as follows:

Digestibility (X in %) = (1- A/B*XB/XA)*100,

where XA and XB are the concentrations of X in feed and faeces, respectively.

Statistical analyses

The data were subjected to analyse of variance according to the general linear model of the Minitab software (Minitab release 13.31; 2000). When the "F" test was significant (P<0.05), the means were separated using the Tukey comparison option in the Minitab software. The model used was the following:

Yijk = µ + Ti + Pj +Ak + eijk

where:

Yijk = Dependent variable,
µ = overall mean,
Ti = treatment effect,
Pj = period effect,
Ak = animal effect,
eijk = random error


Results and discussion

Mortality

One rabbit on the treatment WS 8 developed digestive upset and died after 50 days on the experiment.

Water spinach yield

Fresh biomass yield was higher in the first than in the second cutting (Figure 1). The yield in the present study was higher than reported by Kean Sophea and Preston (2001) (23.6 and 16.3 tonnes/ha for first and second harvests), with fertilization from biodigester effluent at 140 kg N/ha.

Figure 1. Fresh biomass of water spinach of 2 cutting interval
Feed characteristics

Water spinach leaves were higher in DM, crude protein and organic matter and lower in crude fiber than stems (Table 2). Compared with water spinach growing in water (Pok Samkol et al 2006), the plants growing on soil in CelAgrid-UTA were lower in crude protein (27.8 vs 35.1 % in DM). The fiber content was more than twice as high in stems compared with leaves

Table 2.  Feed characteristics of water spinach (% in DM, except for DM which is on fresh basis).

 

DM

N

Crude protein

Ash

Organic matter

Crude fiber

Proportion

Leaves

11.6

4.44

27.8

12.6

87.4

7.30

28.3

Stems

7.34

1.82

11.4

17.5

82.5

19.1

71.7

Crude protein expressed by N*6.25

Feed intake

The experiment was designed as a production function with offer level as the independent variable. As the offer level increased, the proportion of the DM consumed as leaves increased (Table 3 and Figure 2), as did the proportion of DM consumed as crude protein (Figure 3).

Table 3. Feed intake pattern (g/day) of rabbits offered different levels of water spinach

 

WS8

WS10

WS12

WS14

WS16

WS18

SEM

Prob.

Dry matter

Leaves

29.2

36.0

40.8

44.1

39.0

48.4

3.36

0.064

Stems

35.9

34.8

26.5

27.8

36.5

25.7

3.07

0.130

Total

65.1

70.8

67.3

71.9

75.5

74.1

5.42

0.745

Crude protein

 

 

 

Leaves

8.14

10.4

11.6

12.5

11.0

13.7

1.061

0.092

Stems

4.11

3.98

2.97

3.15

3.96

2.90

0.349

0.138

Total

12.3

14.3

14.6

15.6

15.0

16.6

1.270

0.366

Crude fiber

Leaves

2.13

2.61

2.99

3.24

2.81

3.56

0.238

0.050

Stems

6.89

6.69

5.04

5.33

6.68

4.87

0.579

0.139

Total

9.02

9.29

8.02

8.57

9.49

8.44

0.718

0.699

 

Figure 2. Proportion of water spinach leaves in % according to offer level. Figure 3. Relationship between proportion of leaves of water spinach consumed
and proportion of crude protein in diet DM.

Rabbits are herbivores and very selective eaters (McNitt et al 1996). Thus, given the opportunity, they consumed more leaves than stems and the leaves are much higher in crude protein.

Growth and feed conversion

The growth pattern of the rabbits on the different diets was linear, except in the last 10 to 15 days when it appeared to reach a plateau (Table 4 and Figure 4), especially evident on the treatments which previously had shown the fastest growth rates.

Table 4. Performance traits of rabbits fed different levels of water spinach as % of live weight in DM basis

 

WS8

WS10

WS12

WS14

WS16

WS18

SEM

Prob.

Live weight, g

 

 

 

 

 

 

 

Initial

1060

870

900

910

945

875

51.9

0.446

30 days

1630

1363

1375

1398

1525

1410

79.3

0.420

60 days

2080

1830

1810

1765

1975

1745

89.1

0.316

Daily gain, g

 

 

 

 

 

 

 

0-30 days

20.4

17.3

16.8

17.8

19.6

18.1

1.461

0.651

31-60 days

16.0

16.0

14.3

12.4

16.0

10.6

1.519

0.226

0-60 days

20.3

17.3

15.8

15.1

17.7

14.4

1.48

0.334

kg DM intake/kg gain

 

 

 

 

 

 

0-30 days

4.06

4.30

4.21

4.28

4.25

4.36

0.465

0.99

31-60 days

4.52

4.24

4.52

5.50

4.37

6.55

0.438

0.072

0-60 days

3.83

4.10

4.28

4.76

4.41

5.18

0.464

0.544



Figure 4. Growth curves of rabbits fed different levels of water spinach as % of live weight.

There is no obvious explanation for this result other than the suggestion that the rabbits had already reached their mature body size before the end of the experiment. As the offer level increased, the growth rate decreased (Figure 5). The relationship was much closer, and negative, when the weight gain was plotted against the proportion of the DM consumed as leaves (Figure 6).

Figure 5. Relationship between offer level of water spinach
and live weight gain.
Figure 6. Relationship between proportion of leaves of water
spinach consumed and daily weight gain

More interesting is the relationship between the proportion of the DM consumed as crude fiber and the weight gain, which in this case was positive (Figure 7). There was also a close relationship between fiber consumed and feed conversion (Figure 8)

Figure 7. Relationship between proportions of DM water spinach
consumed as crude fiber and daily weight gain.
Figure 8. Relationship between proportion of DM water spinach
consumed as crude fiber and DM feed conversion.

Digestibility coefficients

The digestibility of DM and crude protein increased as the proportion of the DM consumed as leaves increased (Table 5, Figures 9 and10).


Table 5. Mean values of digestibility coefficients (%) for rabbits offered different levels of water spinach

 

WS8

WS10

WS12

WS14

WS16

WS18

SEM

Prob.

DM

74.6

73.5

77.3

76.9

77.6

78.3

1.023

0.032

Crude protein

60.3

59.9

67.5

66.3

68.9

70.9

2.983

0.105

Ash

74.2

70.2

74.8

73.4

76.4

77.6

2.31

0.345

Organic matter

74.6

74.0

77.7

77.4

77.7

78.4

1.028

0.040

Crude fiber

56.3

51.4

55.5

50.3

52.2

48.2

2.851

0.417



Figure 9. Relationship between proportion of leaves of water spinach
consumed and DM digestibility.
Figure 10. Relationship between proportion of leaves of water spinach
consumed and crude protein digestibility.

The decrease in fiber digestibility, as the proportion of DM consumed as leaves increased, indicates that the crude fiber in the leaves is less digestible than the crude fiber in the stems (Figure 13).


Figure 11. Relationship between proportion of leaves of water spinach consumed and crude fiber digestibility.

This is the opposite of what occurs with most plant species where the cell wall component is less digestible in stems than in leaves (Van Soest 1994). The reason for this difference could lie in the architecture of the water spinach plant (Photo 1). The stems (or stolons) of the water spinach rest on the soil (or in the water) and thus do not have to support the leaves. In contrast, in most plants the stems are upright and physically support the leaves (Rangnekar 1991).


Photo 1. Architecture of water spinach plant.

Fiber plays an important role in the nutrition of the rabbit. According to Lebas et al (1997), there is a minimum requirement for roughage in order to optimise the digestive processes, and the more digestible the fiber the higher is the requirement in order to satisfy the need for 10% of indigestible fiber in the diet.

The problem with water spinach would not appear to be one of  too high digestibility of the fiber, but rather the too low concentration of fiber in the total plant (7.3% in leaf DM and 19.1% in stem DM). This hypothesis is supported by recent findings from an experiment in which two other sources of high-fiber feeds (grass and rice straw) were offered to rabbits in addition to the water spinach (Pok Samkol, Unpublished data). DM intake was increased by 50% when the rabbits had access to all three feed sources as compared with water spinach as the sole diet.


Conclusions


Acknowledgements

This paper is derived from the thesis submitted by the Senior Author as partial requirement for the MSc degree at SLU, Uppsala, Sweden, and was supported by the Mekarn regional project financed by Sida-SAREC. The authors would like to express their gratitude to all the personal of the ecological farm, CelAgrid-UTA Cambodia for help with this experiment, especially Mr. Von Vyreak for his assistance in taking care of the rabbits. Thanks are also given to Mr. Chhay Ty for laboratory analyses.


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Received 6 January 2006; Accepted 30 January 2006; Published 10 February 2006

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