FNSFood and Nutrition Sciences2157-944XScientific Research Publishing10.4236/fns.2021.1212092FNS-114083ArticlesBiomedical&Life Sciences Effect of Effluent from Biodigestion of Pre-Treated Rice Bran and Animal Manure on the Dry Matter Yield and Nutrient Uptake of <i>Amaranthus viridis</i> OluwakemiFlorence Ojo1GbolaboAbidemi Ogunwande2OlusolaOlajumoke Adesanwo3FrancisTope Olatoberu3*Institute of Ecology and Environmental Studies, Faculty of Science, Obafemi Awolowo University, Ile-Ife, NigeriaDepartment of Agricultural and Environmental Engineering, Faculty of Technology, Obafemi Awolowo University, Ile-Ife, NigeriaDepartment of Soil Science and Land Resources Management, Faculty of Agriculture, Obafemi Awolowo University, Ile-Ife, Nigeria0812202112121255126827, September 202120, December 2021 23, December 2021© Copyright 2014 by authors and Scientific Research Publishing Inc. 2014This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/

The effect of effluents from biodigestion of pre-treated rice bran in combination with two types of animal manure on dry matter yield of Amarathus viridis was investigated using two pre-treatment methods: Soaking in ordinary distilled water and boiled in distilled water at 100&degC. The pre-treated rice bran and animal manure were mixed (w/w basis) to give carbon to nitrogen ratio of 35:1 and 37:1 prior to loading into the digester to make eight different treatment combinations as follow: 1) Cow dung with no rice bran (NRB + CD); 2) Raw rice bran + cow dung (RRB + CD); 3) Soaked rice bran in ordinary distilled water + cow dung (SRB + CD); 4) Boiled rice bran + cow dung (BRB + CD); 5) Poultry manure with no rice bran (NRB + PM); 6) Raw rice bran + poultry manure (RRB + PM); 7) Soaked rice bran + poultry manure (SRB + PM); 8) Boiled rice bran + poultry manure (BRB + PM). Samples of different treatment combinations were collected before digestion, both the samples and resultant effluents were subjected to elemental analysis using AAS. The effluents from the biodigestion of these combinations were applied at two rates (80 and 150 kg N ha -1) to 3 kg air-dried and sieved soil samples (0 - 20) cm in the greenhouse, control (0 kg N ha -1) and reference pot with NPK fertilizer at the 80 kg N ha -1 were arranged in a completely randomized design replicated three times. Amaranthus plants were introduced into each treated pot, left for four weeks before harvest, dry matter yields were recorded. Results of chemical analysis of raw materials and effluents obtained after biodigestion revealed th e presence of all plant nutrients in both the raw materials and resultant effluents though the former had higher values in some nutrients than the effluent, for examples treatment combination of CD, the values for organic carbon (42.85%), Ca (3.41%) and Mg (0.61%) were higher than in the resultant effluent for CD, a similar trend was observed with other treatment combinations. Drastic reduction in heavy metal concentration was observed after digestion, Pb content in the raw materials for poultry manure reduced by 94.7% in the resultant effluent from BRB: PM thus making the effluent a better soil amendment. Raw chicken manure was richer in the nutrients needed for optimal crop growth however, raw cow dung had the highest. The amendment of effluent from boiled rice bran with poultry manure at 150 kg N ha -1 significantly increased the dry matter yield of Amaranthus viridis over control pots, NPK pots and all other amendments thus making it a good alternative to NPK fertilizer.

Biogas Rice Bran Animal Manure Effluents Yield Nutrient Uptake1. Introduction

Conventional farming has played an important role in improving production of food to meet human demands through intensive application of inorganic fertilizers [1]. High cost and scarcity of inorganic fertilizers in developing countries led to renewed interest in the use of unorthodox organic materials as nutrient sources for crop production especially Amaranthus viridis. Application of NPK and urea fertilizers is a normal practice in amaranthus production, however, previous reports revealed the negative impacts of continuous application of these mineral fertilizers both on soil properties and the environment [2]. The use of easily available and cheap agrowastes by vegetable farmers in peri-urban areas ensures the sustainability of vegetable production, more balanced crop nutrition and environmental sanitation. These agro wastes include animal wastes such as poultry manure and cow dung, and other plant residues [3]. However, huge quantities are needed to meet up the nutrient needs of many crops thus reducing its wide application. Therefore, there is a need for a low-cost technology for better utilization. Rice bran (RB) is the most abundant agricultural residue in rice producing countries around the world and one of the major by-products of the rice milling process. It constitutes about 20% of the paddy by weight [4] and is very rich in plant nutrients [5] [6]. Rice bran when ploughed into the soil takes a long time to decompose because of its high C:N ratio [7]. Rice farmers in Nigeria usually result to open burning to manage the huge quantities, this method is accompanied by a lot of environmental hazards.

Recently, research attention in tropical countries has shifted to the utilization of effluents from biodigestion of organic materials to improve soil fertility and yield of crops. Previous reports showed evidence of increased crop production by using effluent from biogidestion of organic materials [8]. [9] recorded increase in dry matter yield of radish through the application of effluent from biodigestion of organic materials. However, there is limited information on the use of effluents from the rice bran and its effects as soil amendments to improve yield and nutrient uptake of crops. Therefore, this study was conducted to investigate the effect of effluents from the biodigestion of pre-treated rice bran and animal manure on the Nutrient Uptake and Yield of Amaranthus viridis.

2. Materials and Methods2.1. Materials

Rice bran used for this study was collected from Ekiti State Rice Mill Company in Ado Ekiti, Nigeria. Fresh poultry manure and cow dung were collected at the Teaching and Research Farm of the Obafemi Awolowo University, Ile-Ife, Nigeria.

2.2. Collection of Soil Samples and Analysis

Soils samples used for the experiment were randomly collected at 0 - 20 cm soil depth from an exhaustively cropped land which had been farmed continuously for over four years at the Teaching and Research Farm of the Obafemi Awolowo University Ile-Ife located on latitudes 7˚31'N and 7˚33'N and longitudes 4˚33'E and 4˚34'E, in the rain forest zone of southwest Nigeria. The experimental soil was classified as Iwo series (ultisol) [10]. The soil samples were air dried and sieved. The fraction that passed through a 5 mm was used for greenhouse studies while the fraction that passed through a 2 mm sieve was subjected to both physical and chemical analysis in the laboratory of the Department of Soil Science and Land Resources Management. The particle size distribution was determined using the modified method of [11] described by [12] Soil pH was determined using a glass electrode pH meter in 0.01 M CaCl2 solution, [13] and modified by [14]. Total N was determined using the method described by [15]. Soil organic matter was determined using the method described by [16] as modified by [17]. Available P was extracted by Bray-1 method described by [18] as modified by [19], Visible Spectrophotometer Model 721, Axiom Mediral LMD. U.K.). Exchangeable cations were extracted using 1 N-NH4OAc [20] as modified by [21]. Concentrations of K and Na in the solution were determined with the flame photometer (PG-FP902 microprocessor model) while Ca, Mg concentrations were determined using atomic absorption spectrophotometer PG-AA500FG model. The exchangeable acidity was determined by 1 N KCl extraction solution [22]. The soil CEC was determined by the addition of exchangeable and exchangeable acidity [20] [23] modified by [24]. Micro nutrients contents (Fe, Zn, Mn Cu), and Heavy metals (Pb, Cd) were also determined [25].

2.3. Pre-Treatment of the Materials

Two pre-treatment methods were used: rice bran boiled at 100˚C for 30 minutes in (BRB), rice bran soaked for 72 hours in ordinary distilled water at ambient temperature of 29.6˚C ± 3.4˚C (SRB. Pre-treated rice bran and animal manure were mixed (w/w basis) to give carbon to nitrogen ratio of 35:1 and 37:1 prior to loading into the digesters. Eight different treatment combinations were subjected to anaerobic digestion for 16 weeks at the Department of Agricultural and Environmental Engineering 1) Cow dung with no rice bran (CD); 2) Raw rice bran + cow dung (RRB:CD); 3) Soaked rice bran + cow dung (SRB:CD); 4) Boiled rice bran + cow dung (BRB:CD); 5) Poultry manure with no rice bran (PM); 6) Raw rice bran + poultry manure (RRB:PM); 7) Soaked rice bran + poultry manure (SRB:PM); 8) Boiled rice bran + poultry manure (BRB:PM). The mixture was digested for 16 weeks and the digestion was carried out at the Department of Agricultural and Environmental Engineering). The control treatments had zero level of rice bran. After the mixing, the digesters were loaded and the digesters were then hermetically sealed. The digesters were agitated manually twice daily to ensure intimate contact between micro-organisms and the substrate as well as uniform heat distribution.

2.4. Analysis of Effluent Nutrients

Effluent samples (digested slurry) were collected for each treatment and analysed for the following parameters: total nitrogen (TN), available phosphorus (P), potassium (K), total organic carbon (TOC), iron (Fe), calcium (Ca), magnesium (Mg), zinc (Zn), manganese (Mn) and pH.

2.5. Greenhouse Experiment

The effect of effluents generated from the biogas production on the growth of Amaranthus viridis was tested in the greenhouse of the Faculty of Agriculture, Obafemi Awolowo University, Ile-Ife. Three kilogrammes of air-dried and sieved surface soil were filled into each 7 cm × 19.2 cm × 13.8 cm (height x top diameter × base diameter) pot. The pots had perforations underneath to prevent water logging and ensure soil aeration. The pots were arranged in complete randomized design, control pots and reference pots (80 Kg N ha−1 NPK fertilizer) were included to make a total of 10 treatments. The effluents were incorporated into the soil at application rates of 80 and 150 kg N ha−1 two weeks prior to sowing of Amaranthus viridis. All were replicated thrice to give a total of 54 pots labeled and arranged in a completely randomized design. The pots were moistened to and maintained at 70% of the soil’s field moisture capacity and the applied treatments were allowed to undergo incubation for a period of two weeks. Seeds of Amaranthus viridis were sown into each pot and thinned to two stands, one week after sowing (WAS).

2.6. Plant Analysis2.6.1. Determination of Plant Dry Matter and Moisture Content

The edible portions of the Amaranthus viridis (Leaves + Succulent stem) were harvested after four weeks, kept in polythene bag and immediately transported to Soil Testing Laboratory of the Department of Soil Science and Land Resources Management. The harvested plant samples were oven dried at 60˚C until a constant weight was obtained. The percent dry matter was determined according to [26]

% Dry matter = Weight of Dry Sample Weight of Fresh Sample × 100 1 .

The percent plant moisture content of the plant tissue was determined using the expression:

% water content = ( Weight of Fresh Sample ) − ( Weight of Dry Sample ) Weight of Fresh Sample × 100 1 .

2.6.2. Determination of Nutrient Uptake

The nutrients in the plant samples were extracted using wet ash digestion method. Nitrogen content was determined using Kjeldahl method as described by [15]. Other nutrients (P, K, Ca, Fe, Mg, Zn, Mn, Pb, Cr, Cd, Ar, Ni and Hg) were determined using method as described by AOAC [27]. The nutrient uptake was determined according to [26].

Dry matter weight ( gm ) = wet weight ( gm ) − [ wet weight ( gm ) × moisture ( % ) 100 % ]

Dry matter yield ( kg hectare ) = Dry matter weight ( kg ) area of Harvested land

Nutrient removal ( kg hectare ) = Dry matter yield ( kg / hectare ) × concentration ( % ) 100 %

2.7. Statistical Analysis

The data obtained from anaerobic digestion was subjected to two-way analysis of variance (ANOVA) to determine variation in properties. Where significance was indicated, the means were separated using Duncan’s New Multiple Range Test (DMRT) at 5% significance level. However, greenhouse experiment data was subjected to one-way analysis of variance (ANOVA) and means were separated using Duncan’s New Multiple Range Test at 5% significance level. The statistical analysis was performed using the GLM procedure of Statistical Analysis System [28] software.

3. Result and Discussion3.1. Physicochemical Properties of Soil

The physical and chemical properties of the soil used in the study were presented in Table 1. The soil was loamy sand in texture with pH of 6.5 indicating a slightly acidic condition. Total N (1.0 g∙kg−1), organic carbon (17.3 g∙kg−1), available P (7.46 mg∙kg−1) and exchangeable Mg (0.18 cmol∙kg−1) were below the

Pre-planting physical and chemical characteristics of soils
ParametersMean values
pH (1:1 soil to water)6.5
Total N (g∙kg−1)1.0
Total organic carbon (g∙kg−1)17.3
Available P (mg∙kg−1)7.46
Exchangeable cations (cmol∙kg−1)
Ca2+0.34
Mg2+0.18
K+0.50
Na+0.30
CEC (cmol∙kg−1)1.40
Exchangeable Acidity H+ (cmol∙kg−1)0.09
Micronutrients (mg∙kg−1)
Fe0.16
Zn0.10
Mn0.08
Cu0.06
Heavy metals (mg∙kg−1)
Pb0.01
Cd0.01
Particle size distribution (g∙kg−1)
Sand105.5
Silt838.0
Clay58.0
Textural classLoamy sand

critical values for soils of Southwestern Nigeria according to [29]. Similarly, micronutrient contents were below the critical values for optimum crop production [30] thus indicating the low fertility status of the soil.

3.2. Selected Chemical Properties of the Feedstock and Effluent

The nutrients and heavy metal contents in feedstock and effluents were presented in Table 2 and Table 3. The results revealed the high nutrient content of raw poultry manure compared with other feedstocks, for example, highest values in N (4.48%) and P (1.93%) were recorded for raw poultry manure values in while raw cow dung had the highest organic carbon, Ca and Mg (42.85%, 3.41% and 0.61%, respectively). Rice bran had the highest K value (2.37%). Raw poultry manure gave highest Fe (528 mg∙kg−1), Zn (475 mg∙kg−1), Mn (644% mg∙kg−1), Pb

Nutrient content in feedstock and effluents
FeedstockElements
NPKTOCCaMg
%
Cow Dung1.261.630.4442.853.410.61
Poultry manure4.481.931.4340.153.260.56
Rice bran1.471.372.3715.800.070.48
Effluents
NRB:CD2.511.430.3326.943.220.48
RRB:CD2.581.400.5924.913.060.54
SRB:CD3.231.390.3733.483.420.52
BRB:CD2.851.400.4328.553.260.49
NRB:PM3.281.831.2633.632.920.47
RRB:PM3.431.781.2536.032.860.43
SRB:PM3.481.831.3235.993.450.41
BRB:PM3.631.781.3237.783.780.51

Where NRB:CD = no rice bran + cow dung; RRB:CD = raw rice bran + cow dung; SRB:CD = soaked rice bran + cow dung; BRB:CD = boiled rice bran + cow dung; NRB:PM = no rice bran + poultry manure; RRB:PM = raw rice bran + poultry manure; SRB:PM = soaked rice bran + poultry manure; BRB:PM = boiled rice bran + poultry manure.

Micro nutrients and heavy metals concentration in feedstock and effluent
FeedstockElements
FeZnMnPbCdCrArNiHg
mg∙kg−1
Cow Dung126.25183.25391.002.840.213.602.932.342.84
Poultry manure528.70475.10644.5024.453.0630.1112.801.950.81
Rice bran1.110.943.470.180.260.010.010.830.15
Effluents
NRB:CD12.5114.5413.061.110.110.060.030.020.01
RRB:CD12.0814.5812.871.120.110.030.020.010.01
SRB:CD13.4914.7713.771.190.110.020.010.010.01
BRB:CD12.5114.0813.151.110.090.030.020.010.01
NRB:PM14.6715.4913.621.260.160.030.020.010.01
RRB:PM14.7215.3413.371.220.130.030.010.010.01
SRB:PM15.4115.3513.151.310.100.020.010.010.01
BRB:PM15.7615.6013.721.280.130.010.010.010.01

Where NRB:CD = no rice bran + cow dung; RRB:CD = raw rice bran + cow dung; SRB:CD = soaked rice bran + cow dung; BRB:CD = boiled rice bran + cow dung; NRB:PM = no rice bran + poultry manure; RRB:PM = raw rice bran + poultry manure; SRB:PM = soaked rice bran + poultry manure; BRB:PM = boiled rice bran + poultry manure.

(24.45 mg∙kg−1), Cd (3.06 mg∙kg−1), Cr (30.11 mg∙kg−1) and Ar (12.80 mg∙kg−1). However, raw cow dung gave highest Ni and Hg.

The result of chemical composition of effluent of different treatment combinations after bio digestion showed higher nutrient content compared with raw feedstocks, for example, N content in the effluent CD without rice bran (2.51%) was higher than raw CD (1.26%), similar observation was also reported in previous studies [31] [32] [33]. Among the different feedstocks subjected to biogestion, effluent from poultry manure effluent (PM, RRB: PM, SRB: PM and BRB: PM) contained higher amount of TOC, N, P, K, Fe and Zn compared to effluent of rice bran and cowdung. Drastic reduction in the micronutrients and heavy metal contents of the effluents from biodigestion compared to raw feedstocks was observed, thus showing the potential of these effluents as an environmental-friendly alternative fertilizer for sustainable soil management. For example, about 98% decrease in Pb content was recorded for all PM treatments compared to the raw sample. In addition, likehoodly of micronutrients toxicity will be less pronounced with the effluents compared to application of raw samples. These results are in close conformity with previous work by [34]. Result of chemical composition of the effluent from bio digestion of combined rice bran and animal manure showed the potential of these effluents as a viable alternative to mineral fertilizer. Almost all the plant nutrients were present in an adequate amount.

3.3. Effects of Effluent from Bio-Digestion of Rice Bran with Animal Manure Treatment on Dry Matter Yield, Nitrogen, Phosphorus and Potassium Uptake of Amaranthus viridis Plants

The results showing the effects of effluents from biodigestion of rice bran and animal manure on dry matter yield, nitrogen, phosphorus and potassium uptake of Amaranthus viridis were presented in Table 4. Application of effluents from different treatment combinations significantly increased dry matter yield of Amaranthus viridis over the control pot, highest dry matter yield was recorded from pot treated with effluent from biodigestion of BRB:PM at the rate of 150 kg N ha−1 and significantly higher than NPK treated pot, this is an indication of the potential of effluents from biodigestion of organic materials as viable alternative to mineral fertilizer. This result was in close conformity with earlier research findings [9] [35] [36] [37]. In addition, no significant difference in the dry matter yield was observed among all the pots treated with effluents at 80 kg N ha−1 and NPK treated pot.

Pots treated with effluents and NPK fertilizer significantly (p < 0.05) had higher N. P and K uptake over the control pot. However, highest values in N and K uptake were recorded in pots treated with NPK fertilizer while plants harvested from pot treated with BRB: PM at rate of 150 kg N ha−1 had the highest P uptake. The increased N and K uptake in NPK treated pot over effluents treated pots could be as a result its high solubility. The result corroborated the work of [38] who reported significant increase in the nutrients content of cucumber leaf.

Dry matter yield, nitrogen, phosphorus and potassium uptake of Amaranthus viridis plants
TreatmentsRatesDMYNPK
(kg N ha−1)gmg∙kg−1
Control015.01c8.00l 13.01l15.76m
NPK8015.88cd78.61a 78.30e 248.07a
NRB:CD8014.21f60.36hi 51.91j 49.36j
15015.20c70.48cd 68.12g 65.85i
SRB:CD8014.47f57.22jk 72.66f 20.54l
15015.61d72.52bc 88.74c 49.59j
RRB:CD8016.42ab 68.96de 82.14d 47.95j
15015.81cd72.66bc 97.62b 67.06i
BRB:CD8014.53f65.24fg 57.89i 48.00j
15016.00c 71.20cd 68.54g 41.05k
NRB:PM8014.49f 54.33k 47.29k 164.62h
15015.09c60.34hi 59.56i 183.66f
SRB:PM8015.80cd62.56gh 69.37g 208.48d
15016.07bc67.16ef 79.47de 204.81e
RRB:PM8015.09c57.60ij 63.90h 180.88g
15016.06bc 69.78de 81.13d 211.34c
BRB:PM8014.52f 62.48hg 76.84e 207.64d
15016.65a 75.22b 102.97a 229.58b

Means having the same letter(s) in the columns are not significantly different at 5% significant level. Where NRB:CD = no rice bran + cow dung; RRB:CD = raw rice bran + cow dung; SRB:CD = soaked rice bran + cow dung; BRB:CD = boiled rice bran + cow dung; NRB:PM = no rice bran + poultry manure; RRB:PM = raw rice bran + poultry manure; SRB:PM = soaked rice bran + poultry manure; BRB:PM = boiled rice bran + poultry manure.

3.4. Effects of Effluent from Bio-Digestion of Rice Bran with Animal Manure Treatment on Calcium and Magnesium Uptake of Amaranthus viridis Plants

Positive significant (p < 0.05) effects of the effluents and NPK treatments over control pot were recorded for Ca and Mg uptake in Amaranthus viridis as presented in Figure 1.

3.5. Effects of Effluent from Bio-Digestion of Rice Bran with Animal Manure Treatment on Heavy Metal Uptake of Amaranthus viridis Plants

The result showing the uptake of heavy metals in Amaranthus viridis as

influenced by the application of effluents from different treatment combinations was presented in Table 5. Extremely low values in all the heavy metals studied further support the potential of using effluents from biodigestion of rice bran and animal manure as viable fertilizer compared with mineral fertilizer.

4. Conclusion

The study revealed the high plant nutrient status of effluents from biodigestion of rice bran with animal manure, extremely low amount of micronutrients and heavy metal too showed the potentials of using these effluents as a viable alternative to mineral fertilizers. The positive impact of the effluents on nutrient uptake and yield of Amaranthus viridis observed further confirmed its suitability as a good soil amendment. This study confirmed the effectiveness of effluent from bio digestion of rice bran with animal manure as a low cost, environmentally friendly

Heavy metal uptake of Amaranthus viridis plants
TreatmentsRatesPbCdCrAsNiHg
(kg N ha−1)mg∙kg−1
Control00.00020.0002l0.0001c0d NdNd
NPK800.0002i0.0002l0d0d NdNd
NRB:CD800.0004g0.0006h0d0d NdNd
1500.0007c0.0008f0d0d NdNd
SRB:CD800.0004g0.0006h0.0001c0d NdNd
1500.0009c0.0007g0.0002b0d NdNd
RRB: CD800.0012b 0.0013c 0.0002b 0.00001c Nd Nd
1500.0015a0.0019a0.0003a0.00004b NdNd
BRB:CD800.0002i 0.0003k0d 0d NdNd
1500.0005f0.0006h0d0d NdNd
NRB:PM800.0003h 0.0005i 0d 0d Nd Nd
1500.0003h 0.0008f 0d 0d Nd Nd
SRB:PM800.0003h0.0004j0.0002b 0d NdNd
1500.0004g0.0004j0.0002b0d NdNd
RRB:PM800.0008d 0.0010d 0.0003a 0.00001c NdNd
1500.0012b 0.0016b 0.0003a 0.00006a Nd Nd
BRB:CM800.0005f 0.0006h 0.0002b 0.00001c Nd Nd
1500.0009c 0.0009e 0.0002b 0.00006a Nd Nd

Means having the same letter(s) in the columns are not significantly different at 5% significant level. Where NRB:CD = no rice bran + cow dung; RRB:CD = raw rice bran + cow dung; SRB:CD = soaked rice bran + cow dung; BRB:CD = boiled rice bran + cow dung, NRB:PM = no rice bran + poultry manure; RRB:PM = raw rice bran + poultry manure; SRB:PM = soaked rice bran + poultry manure; BRB:PM = boiled rice bran + poultry manure.

fertilizer over mineral fertilizer for the production of Amaranthus viridis. This will ensure food security at a sustainable level.

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

Cite this paper

Ojo, O.F., Ogunwande, G.A., Adesanwo, O.O. and Olatoberu, F.T. (2021) Effect of Effluent from Biodigestion of Pre-Treated Rice Bran and Animal Manure on the Dry Matter Yield and Nutrient Uptake of Amaranthus viridis. Food and Nutrition Sciences, 12, 1255-1268. https://doi.org/10.4236/fns.2021.1212092

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