Livestock Research for Rural Development 16 (7) 2004

Citation of this paper

Evaluation of ensiling methods to preserve sweet potato roots and vines as pig feed

Hoang Huong Giang, Le Viet Ly and Brian Ogle*

National Institute of Animal Husbandry, Ha Noi, Viet Nam
*Department of Animal Nutrition and Management, Swedish University of Agricultural Sciences
gianghoang97@yahoo.com


Abstract

A laboratory experiment on ensiling sweet potato (SP) included 5 different ratios of sweet potato roots (SPR) and vines (SPV): 70, 60, 50, 40 and 30% of SPR with 30, 40, 50, 60 and 70% of SPV on a dry matter basis, respectively, giving treatments SP7:3, SP6:4, SP5:5, SP4:6 and SP3:7. Samples of SP silage were analysed at 0, 7, 14, 21, 28, 42, 70 and 84 days after ensiling to determine chemical composition and fermentation and physical characteristics.

When SPR levels decreased from treatment SP7:3 to treatment SP3:7 the colour changed from yellow to a deeper green because of the dark green colour of SPV. However, the colour did not change from 14 to 84 days of ensiling. The silage on all treatments had a good smell at all times up to 84 days. With increasing ensiling time, dry matter content increased and crude protein decreased in all treatments, but the changes were not significant. Other chemical components such as NDF, calcium, and phosphorus did not change during the 84 days of ensiling in all treatments. The pH value in all treatments decreased rapidly in the first week (from around 6.4 to around 3.8)  and continued to decrease up to day 14 (to around 3.6), then remained low until 84 days. Acetic acid and lactic acid increased quickly in the first 2 weeks (P<0.01) and then remained constant to 84 days.  As the SPR level of the SP silage increased, pH values decreased (during the 84 days of ensiling) and lactic acid increased during the 2 first weeks of ensiling. The NH3-N content in all treatments fluctuated at around 2-3% of total nitrogen and was not affected by ensiling duration or ratio of root to vine.

All of the treatments resulted in good quality products.

Key words: Composition, fermentation, silage, sweet potato roots, vines


Introduction

In Vietnam around 269,000 ha of land are used for growing sweet potato, producing 1,745,300 tons of sweet potato roots in 1998 (Statistical Year Book 1999). The root is a good energy source (15.6 MJ of metabolizable energy/kg dry matter) and the vine is a source of protein (17.7% CP in dry matter) (NIAH 2001), and both are considered as good livestock feeds. One of the harvests of sweet potato coincides with the wet season, which means that large amounts of sweet potato need to be stored for use in the off-season. Sweet potato roots (SPR) have a delicate skin that is very easily broken, so the flesh also is easily bruised, broken or cut, which makes for good conditions for bacteria to attack, resulting in the sweet potato decaying. In addition, the stored roots often come under attack from weevils and rats, and farmers may lose as much as half of their stored feed. Sweet potato vines (SPV), especially after harvesting, are considered as waste, because animals cannot consume all of the huge amounts produced in the short time available before the vine decays, which occurs within 2 or 3 days. However, the vine is very expensive to purchase during the off-season.

Ensiling by-products is a simple and low-cost option, which can preserve feed for long periods (Lien et al 1994). Ensiling can also render some previously unpalatable products useful to livestock by changing the chemical nature of the feed (Kayouli and Lee 1998). Tinh et al (2000) concluded that SPV ensiled with chicken manure resulted in the highest quality feed, increasing diet crude protein content and dry matter conversion rates. Tinh et al (2001) reported that rice bran, cassava leaf meal and chicken manure are good additives for fermenting SPR, in combination with salt, and the fermented SPR can be stored at least for 90 days in the laboratory without any significant reduction of the quality, and for 4.5 months on farm.

This research then focuses on the effects of ensiling SPR and SPV together in different ratios, without any additives, and the aim was to preserve sweet potato for several months and evaluate it for later use as fattening pig feed in the off-season.


Materials and methods

Location
The experiment was conducted in the laboratory of the Animal Nutrition Department of the National Institute of Animal Husbandry, Hanoi, Vietnam (NIAH) from February to April 2002.
Sweet potato vine and root preparation

After harvesting the sweet potato vines were chopped into very small pieces (1-2 cm) and the root was washed to remove soil, then ground (f = 1-2 mm) by machine.

Mixing of sweet potato roots and vines

The prepared SPR and SPV were mixed together in 5 different ratios as 5 experimental treatments, namely 70, 60, 50, 40, 30 % of SPR with 30, 40, 50, 60, 70% of SPV, respectively, on a dry matter basis, without any additives, and designated SP7:3, SP6:4, SP5:5, SP4:6, SP3:7, respectively. Each SPR and SPV mixture had a total weight of 24 kg (fresh basis) after mixing, and was then divided into 24 equal parts (each 1 kg) and placed in 24 plastic bags that were sealed to avoid air contamination. Three bags from a treatment were put into a 10L covered jar to prevent external mechanical damage and each jar thus represented 3 replications of one sample analysed for chemical composition for every ensiling period (there were 8 different ensiling periods). All jars were stored at room temperature (25-30o C).

Measurements

Each jar of 3 bags of sweet potato silage (SPS) on each treatment included 3 replications, with samples taken at: 0, 7, 14, 21, 28, 42, 70 and 84 days after ensiling for analysis of chemical composition, including dry matter (DM), crude protein (CP), NDF, calcium (Ca), and phosphorus (P) and fermentation characteristics such as organic acids, pH and NH3. Physical characteristics of SPS such as colour and smell were also observed and recorded.

The analyses were done in the Department of Feed Analysis of NIAH. DM, CP, NDF, Ca and P were determined by using standard AOAC procedures (AOAC 1990). pH was measured in the liquid extracted from SPS samples.

Statistical analysis

The data were analysed using the General Linear Model procedure of ANOVA in MINITAB 12.21 program (1998). Tukey pair-wise comparisons were used to determine the differences between treatments with confidence level 95.0%.


Results

Physical characteristics
The SP silage had a pale yellow colour from the SPR and a dark green colour from the SPV. In the first three treatments (SP7:3, SP6:4 and SP5:5) the yellow colour was dominant, while the dark green colour of SPV was dominant in treatments SP4:6 and SP3:7. The colour in all treatments did not change after 14 days of ensiling up to 84 days. The silage on all treatments had a good smell, that did not change up to 84 days.
Chemical composition
The analysed chemical composition of fresh sweet potato shows that the DM of SPR (19.1%) was higher than the DM of SPV (15.0%). Other parameters, namely CP, NDF, Ca and P in SPR were much lower than in SPV (dry matter basis) (Table 1), which resulted in DM decreasing while CP, NDF, Ca and P were increasing from treatment SP7:3 to SP3:7 at 0 days.

Table 1.  Analyzed chemical composition of sweet potato vines (SPV) and sweet potato roots (SPR)

Parameter

SPV

SPR

Dry matter, %

15

19.1

As % of dry matter    

Crude protein

16.2

4

NDF

29.8

13.9

Calcium

1.16

0.4

Phosphorus

0.42

0.23

With increasing ensiling time, DM contents increased and CP decreased in all treatments, but the changes were not significant (P>0.05). However, DM and CP contents were different between treatments at all sampling times, due to different SPR and SPV ratios (Table 2).

Table 2. Effect of sweet potato root and vine ratio on dry matter (DM, %) and crude protein (CP, % of DM) content in sweet potato silage

Parameter

Treatment*

Time of ensiling, days

SE

P

0

7

14

21

28

42

70

84

DM

SP7:3

18.0

18.3

 18.3

18.7

18.3

18.5

18.8

19.0

0.329

0.426

SP6:4

17.2

17.3

17.4

17.7

17.5

17.6

17.9

17.9

0.293

0.712

SP5:5

16.8

16.9

17.0

16.7

17.0

17.2

17.3

17.6

0.248

0.258

SP4:6

15.9

16.1

16.2

16.1

16.3

16.3

16.0

16.3

0.218

0.838

SP3:7

15.1

15.2

15.3

15.3

15.3

15.4

15.2

15.2

0.138

0.831

CP

SP7:3

8.1

8.1

8.0

8.0

7.9

7.8

7.9

7.9

0.134

0.762

SP6:4

9.4

9.2

9.3

9.1

9.2

9.1

8.9

9.0

0.199

0.784

SP5:5

10.5

10.3

10.3

10.3

10.2

10.2

10.3

10.1

0.134

0.745

SP4:6

11.7

11.4

11.5

11.2

11.3

11.2

11.3

11.2

0.285

0.877

SP3:7

13.0

12.9

12.9

12.9

13.0

12.7

12.6

12.5

0.208

0.565

*SP7:3 consists of 70%SPR and 30%SPV, SP6:4 consists of 60%SPR and 40%SPV, SP5:5 consists of 50%SPR and 50%SPV, SP4:6 consists of 40%SPR and 60%SPV, SP3:7 consists of 30%SPR and 70%SPV
SPR: Sweet potato roots
SPV: Sweet potato vines

The NH3-N content in all treatments fluctuated in the range of 2 to 3 % of total nitrogen and was not affected by ensiling time or ratio of root to vine (Table 3).

Table 3. Effect of sweet potato root and vine ratio on ammonia nitrogen (NH3-N, % of total N) and NDF content in sweet potato silage

Parameter

Treatment*

Time of ensiling, days

SE

P

0

7

14

21

28

42

70

84

NH3-N

SP7:3

2.08

2.20

2.15

2.45

2.35

2.19

2.49

2.56

0.155

0.310

SP6:4

2.28

2.52

2.45

2.51

2.61

2.26

2.40

2.58

0.286

0.977

SP5:5

2.19

2.43

2.76

2.76

2.58

2.67

2.56

2.64

0.227

0.676

SP4:6

2.24

2.39

2.53

2.85

2.69

2.50

2.65

2.37

0.217

0.585

SP3:7

2.21

2.67

2.75

2.86

2.75

2.31

2.88

3.09

0.251

0.286

SE

0.321

0.493

0.158

0.108

0.114

0.144

0.212

0.174

 

 

P

0.993

0.969

0.126

0.075

0.225

0.227

0.585

0.142

 

 

NDF

SP7:3

19.5

18.4

18.2

18.2

18.6

19.2

18.3

18.5

0.332

0.126

SP6:4

22.7

22.5

21.3

20.7

21.6

20.2

20.8

21.6

0.792

0.379

SP5:5

24.0

24.0

22.8

22.6

23.3

22.2

23.4

22.1

0.665

0.332

SP4:6

26.5

25.3

25.3

25.6

26.3

27.1

25.2

25.1

0.562

0.174

SP3:7

28.1

27.8

27.7

27.9

27.6

28.1

27.8

27.6

0.275

0.710

*See footnote in table 2

Ca and P in all treatments were unchanged during the 84 days of ensiling (P>0.05) (Table 4).

Table 4. Effect of  sweet potato root and vine ratio on calcium (Ca, % of DM) and phosphorus (P, % of DM) content in sweet potato silage

Parameter

Treatment*

Time of ensiling, days

SE

P

0

7

14

21

28

42

70

84

Ca

SP7:3

0.58

0.55

0.56

0.62

0.61

0.59

0.61

0.59

0.020

0.172

SP6:4

0.67

0.63

0.67

0.63

0.65

0.70

0.67

0.66

0.018

0.345

SP5:5

0.80

0.79

0.77

0.79

0.83

0.81

0.82

0.81

0.014

0.198

SP4:6

0.85

0.88

0.85

0.86

0.87

0.91

0.82

0.83

0.023

0.306

SP3:7

0.92

0.93

0.95

0.97

0.94

1.00

0.97

0.93

0.024

0.286

P

SP7:3

0.26

0.27

0.24

0.26

0.28

0.25

0.25

0.24

0.016

0.790

SP6:4

0.30

0.33

0.31

0.34

0.30

0.33

0.29

0.32

0.014

0.329

SP5:5

0.32

0.31

0.30

0.29

0.33

0.30

0.31

0.31

0.012

0.457

SP4:6

0.34

0.35

0.32

0.34

0.34

0.32

0.35

0.32

0.011

0.291

SP3:7

0.37

0.35

0.35

0.33

0.36

0.37

0.37

0.38

0.017

0.683

*See footnote in table 2

pH and organic acid content
The decrease in pH was very rapid in the first week (from around 6.3 to around 3.8) and continued to decrease in the second week to a final value of around 3.6, and then remained low up to day 84 (Table 5). pH increased slightly as the ratio of roots increased in the mixtures.
 

Table 5. Effect of sweet potato root and vine ratio on  pH in sweet potato silage

Treatment*

Time of ensiling, days

SE

P

0

7

14

21

28

42

70

84

SP7:3

x6.26a

x3.74b

x3.57c

x3.60c

x3.60c

3.59c

x3.59c

x3.59c

0.041

0.000

SP6:4

xy6.35a

xy3.79b

xy3.61c

x3.60c

xy3.61c

3.62c

y3.62c

y3.62c

0.012

0.000

SP5:5

yz6.47a

xyz3.84b

xy3.60c

xy3.62c

yz3.62c

3.63c

y3.64c

y3.64c

0.028

0.000

SP4:6

z6.53a

yz3.93b

y3.64c

y3.63c

z3.64c

3.64c

y3.63c

y3.63c

0.010

0.000

SP3:7

z6.55a

z3.94b

y3.66c

y3.64c

z3.64c

3.63c

y3.64c

y3.64c

0.021

0.000

SE

0.026

0.031

0.012

0.005

0.004

0.010

0.005

0.005

 

 

P

0.000

0.008

0.006

0.002

0.001

0.074

0.002

0.001

 

 

*See footnote in table 2
a,b,c within rows, values with different superscript letters are significantly different (p<0.05)
x,y,z  within columns, values with different superscript letters are significantly different (p<0.05)

Lactic acid content increased markedly during the first 14 days of ensiling with no change thereafter (Table 6). There was a tendency for the concentration to decrease slightly as the proportion of roots in the mixture increased. Levels of butyric acid were very low at all times and on all mixtures. Acetic acid levels increased from around 4 g/kg DM in the mixtures prior to ensiling reaching around 24 g/kg DM after ensiling for 14 days.

Table 6. Effect of sweet potato root and vine ratio on organic acids (g/kg DM) content in sweet potato silage

Parameter

Treatment*

Time of ensiling, days

SE

P

0

7

14

21

28

42

70

84

Lactic acid

SP7:3

x21.7a

x88.5b

123.9c

127.6c

126.2c

124.5c

124.9c

123.0c

1.847

0.000

SP6:4

xy20.7a

x87.7b

123.1c

125.0c

123.3c

122.9c

124.3c

122.0c

1.321

0.000

SP5:5

y17.4a

y74.2b

121.7c

120.9c

122.5c

120.9c

119.2c

118.7c

1.866

0.000

SP4:6

z11.6a

yz67.0b

119.2c

121.6c

119.7c

121.4c

119.2c

119.5c

1.499

0.000

SP3:7

z10.3a

z64.6b

118.3c

120.1c

119.6c

120.5c

119.5c

119.5c

1.265

0.000

SE

0.702

1.556

1.706

2.005

1.516

1.049

1.766

2.202

 

 

P

0.000

0.000

0.188

0.130

0.070

0.125

0.106

0.609

 

 

Acetic acid

SP7:3

4.4a

17.8b

24.2c

26.2c

25.7c

26.9c

24.7c

27.5c

0.874

0.000

SP6:4

4.4a

16.5b

24.3c

24.1c

27.0c

24.2c

25.2c

25.8c

1.181

0.000

SP5:5

4.9a

18.1b

23.6c

24.7c

23.89c

24.5c

24.6c

25.2c

1.625

0.000

SP4:6

5.2a

17.4b

24.2c

26.3c

25.2c

23.8c

24.8c

24.0c

0.543

0.000

SP3:7

4.2a

16.7b

25.0c

25.9c

26.3c

24.4c

24.3c

26.6c

0.638

0.000

SE

0.219

0.403

1.935

1.590

0.712

0.874

0.797

0.820

 

 

P

0.062

0.089

0.991

0.830

0.108

0.185

0.955

0.113

 

 

Butyric acid

SP7:3

0.53

0.33

0.27

0.49

0.34

0.47

0.50

0.48

0.141

0.749

SP6:4

0.50

0.41

0.37

0.48

0.38

0.39

0.47

0.43

0.068

0.803

SP5:5

0.56

0.40

0.45

0.34

0.39

0.43

0.45

0.42

0.080

0.695

SP4:6

0.49

0.46

0.45

0.57

0.40

0.37

0.47

0.48

0.107

0.932

SP3:7

0.49

0.48

0.43

0.54

0.35

0.33

0.47

0.45

0.068

0.386

*See footnote in table 2
a,b,c within rows, values with different superscript letters are different (p<0.05)
x,y,z  within columns, values with different superscript letters are different (p<0.05)


Discussion

The SPR are rich in energy due to the high carbohydrates content (between 80 to 90% of the DM) (Dominguez 1992). SPV are relatively high in protein and contain only 8% starch and 4% sugars in DM (Onwueme 1978 cited by Winarno 1982). Based on these data, the 5 different mixtures of SPR and SPV in the present study should have carbohydrate contents from 32.4 to 59.6% of the DM at least, which would have provided good conditions for fermentation, because ensiling is a preservation method based on the fermentation of carbohydrates by microorganisms under anaerobic conditions to produce organic acids, and normally a minimum of 6 to 12 per cent water-soluble carbohydrates are required for proper silage fermentation. In our study all silages of the various mixtures of SPR and SPV represented a well preserved feed resource for pigs. These results are in agreement with Nguyen Thi Tinh et al (2000, 2001), who concluded that fermented SPV and SPR were very good and economical feed resources for fattening pigs and suitable for feeding in the uncooked form. However, trypsin inhibitors in the raw SPR decrease protein digestibility in the mixed feed, and the uncooked starch of sweet potatoes is very resistant to hydrolysis by amylase. When cooked, these trypsin inhibitors are destroyed, and the starch's susceptibility to the enzyme increases (Dominguez 1992). However, Peters et al (2001) reported that the ensiling process minimizes the trypsin inhibitors in SPR and eliminates the need to cook the feed. The most appropriate ratio between SPR and SPV in practice depends on the relative amounts of SPR and SPV produced. If dual-purpose varieties are planted in paddy rice fields as a winter-spring crop, the root production will be higher, but if the sweet potatoes are planted on upland fields which lack sufficient soil moisture for harvestable roots to form, the vine and leaf production will be more important than root production. When a variety contains a high amount of total dry matter in both roots and vines, it is recommended as a dual-purpose variety (Peters et al 2001). In the present study, all of the 5 different ratios of SPR and SPV, namely 70, 60, 50, 40 and 30 % of SPR with 30, 40, 50, 60 and 70% of SPV, respectively, on dry matter basis, were successfully ensiled without any additives. These results also show that ensiling without additives did not affect the quality of the silage, which is agreement with the results of Kayouli and Lee (1998), who found that a mixture of waste bananas, cassava roots and sweet potato tubers and leaves could be ensiled effectively without the need for additives.

During the 84 days of ensiling, there were only very slight changes in the chemical composition of SP silage, which is in agreement with several previous studies. McDonald et al (1995) reported that losses of DM of less than 5% during ensiling are acceptable. The slight decrease in CP content was because there is normally some deamination of amino acids that occurs during fermentation (McDonald et al 1995). Lin et al (1988) also concluded that the general nutrient values (including metabolizable energy), fatty acid composition and amino acid contents (including the proportion of essential amino acids) in silages of mixtures of sweet potato roots and maize meal did not change during ensiling. Ruiz (1982) showed that the dry matter content of sweet potato foliage silages did not change by adding roots (up to 1.2%) or urea (up to 1.6%). Nguyen Thi Tinh et al (2000, 2001) studied changes of DM, CP, ether extract, CF and ash of sweet potato vines silage and sweet potato roots silage with different additives, and found that there were no significant differences over time (after 14, 30, 60 and 90 days of fermentation).

In principle, a good silage should have a high lactic acid content, which is dominant to other acids such as acetic, propionic and butyric acids, and therefore is usually responsible for most of the drop in silage pH (Kung and Shaver 2001). In our study the lactic acid content in the silages of all the mixtures of sweet potato roots and vines increased rapidly in the first week (concentrations ranged from 64.6 to 88.5 g/kg DM) and continued increasing until 14 days of ensiling (concentrations from 118 to 124 g/kg DM), which resulted in pH values falling quickly (from around 6.3 to around 3.8 at 14 days of ensiling). These results agree with McDonald et al (1995), who concluded that good silages are characterized by having low pH values, usually between pH 3.7 and 4.2, and containing high concentrations of lactic acid (ranging from 80 to 120 g/kg DM in grass silages), which depend on water-soluble carbohydrate levels. The increases of lactic acid and the decreases of pH values of the sweet potato silages when SPR levels increased from 30% to 70% can be explained by the fact that water-soluble carbohydrates in SPR are higher than in SPV. Nguyen Thi Tinh et al (2000) reported that pH of SPV silages (values ranged from 3.52 to 4.20) with different additives decreased rapidly within the first two weeks. That the NH3-N content in the sweet potato silages fluctuated around 2 to 3% of total nitrogen was acceptable, as according McDonald et al (1995) it should be less than 100g NH3-N/kg of total nitrogen.


Conclusions


Acknowledgements

We are very grateful to the Swedish International Development Authority (Sida/SAREC) and the Swedish University of Agricultural Sciences, Department of Animal Nutrition and Management, for their financial support of this study. Special thanks to the staff in the Department of Feed Analysis, the National Institute of Animal Husbandry, for analysis of samples and to our colleagues Dr.Viet and Mrs. Len for their help. This paper is based on research submitted by the Senior Author to the Swedish University of Agricultural Sciences in partial fulfillment of the requirements for the MSc degree in Tropical Livestock Systems.


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Received 29 April 2004; Accepted 12 June 2004

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