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  • Prospects of Integrating Caviaculture and Fish Farming in the Western Region of Cameroon

    Emile MIÉGOUÉ 1   Pégis Davy TAGNING ZEBAZE 2   Thomas EFOLE EWOUKEM 3   Fernand TENDONKENG 1   Jules LEMOUFOUET 1   Ronald NGANYO KOMGUEP 2   et Etienne TEDONKENG PAMO 1  

    1University of Dschang, Faculty of Agronomy and Agricultural Sciences, Department of Animal Production, Animal Nutrition and production Research Unit

    2University of Dschang, Faculty of Agronomy and Agricultural Sciences, Department of Animal Production, Ichthyology and Applied Hydrobiology Research Unit

    3University of Dschang, Faculty of Agronomy and Agricultural Sciences, Department of Forestry, Ichthyology and Applied Hydrobiology Research Unit

    Abstract

    This study was conducted within three months at the University of Dschang Research and Application Farm (5°44’-5°36’ et 5°44’-5°37’ LN ; 10°06’-9°94’ et 10°06’-9°85’ LE). The main objective was to evaluate the integration perspectives of caviaculture and fishery. Specifically, the study was aimed at evaluating the production of guinea pig dungs, its bromatological composition and appreciating the nitrogen/phosphorus ratio in other to determine the adequate quantities of manure for a proper fertilization of fish ponds. Hence, 96 guinea pigs weighing averagely 390 ± 110g each were randomly distributed into two comparable lots (floor covered with litter and floor without litter) and were subjected to 8 feeds (5 grasses and 3 legumes). Each lot had 6 repetitions of 8 individuals. The animals were fed three times daily within 30 days. The dungs of guinea pigs were collected after three days between 6 and 8am during the experimental period. They were then selected and weighed using and electric balance of 0.1g sensitivity. At the end of the study, the following results were obtained: a guinea pig of 390 ± 110 g in confinement produced between 51.7 ± 0.4 to 60.5 ± 0.7g (fresh weight) of dung per day. The bromatological analysis of these dungs showed that they are made of organic material (80.0%), dry matter (94.3%), crude protein (10.7%), ash (19.9%) and nitrogen (22.7%). These results attesting the richness of these dungs helped in estimating the quantities (103.4g to 206.8g) of dung/day/100m2 for the breeding of 2 to 4 guinea pigs per fish pond of 100 m2 for an integrated breeding (guinea pig-fish).

    Author Contributions
    Received 03 Apr 2019; Accepted 17 Jul 2019; Published 26 Jul 2019;

    Academic Editor: Martínez-Morcillo S, Toxicology Unit, Veterinary School, University of Extremadura, Caceres, Spain.

    Checked for plagiarism: Yes

    Review by: Single-blind

    Copyright ©  2019 Emile Miégoué, et al.

    License
    Creative Commons License     This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

    Competing interests

    The authors have declared that no competing interests exist.

    Citation:

    Emile MIÉGOUÉ, Pégis Davy TAGNING ZEBAZE, Thomas EFOLE EWOUKEM, Fernand TENDONKENG, Jules LEMOUFOUET et al. (2019) Prospects of Integrating Caviaculture and Fish Farming in the Western Region of Cameroon. International Journal of Aquaculture Research and Development - 1(1):13-18.

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    DOI 10.14302/issn.2691-6622.ijar-19-2762

    Introduction

    Malnutrition is one of the main problems that African populations suffer and this is particularly linked to a deficit in protein especially animal protein 1. In fact, the consumption of different categories of meat barely reaches 20g/inhabitant/day that is more 10g less than the minimum 33g minimum recommended by WHO 2. FAO 3 suggests that the intensification and diversification of production systems will be a great tool in establishing a balanced diet for the populations. Integrated fishery is therefore proposed as a promising alternative to increase the availability of proteins especially in African rural localities. In Sub-Saharan Africa particularly in Cameroon, fishery is one of the principal sources of animal protein for human population. However, it emergence collides with many constraints such as feed. Adequate experimentations of feed manufacturing based on local by-products have been developed but they face tough competition with other speculations (fowl, pig, etc.) towards essential ingredients. Hence, there is necessity of alternative feeding sources 4; 5; 6 and this is also due to the fact that many inputs available to farmers are of low nutritive value 7. However, the improvement of pond yields through fertilization is a practice used for a long in the world. 8. Fertilizers are products whose use helps in the maintenance and improvement of primary production and the physical, chemical and biological properties of the pond 9. Nevertheless, their use in fisheries remains limited due to the high competitiveness of agricultural 10 and the nature of large zooplankton produced 11. In fact, these fertilizers promote a majority production of large zooplankton 11. Caviaculture is one of the new speculations of animal husbandry of family farms which is strongly promoted today in Cameroon 12; 13; 14. Actually, this breeding is very promising due to the fact that breeding guinea pigs does not need a high capital, their meat are of good quality, no odour and they are suitable as a pet with a ready market 15; 16. However, there has been no integration of guinea pig’s dungs in fishery although they may be an alternative source with regards to fertilizers for the production of zooplanktons. Hence, the objective of this study is to contribute to the evaluation of the potentialities of a caviaculture and fish farming integration in the Western Region of Cameroon. Specifically, this study is aimed at evaluating the production of guinea pigs dungs, its bromatological composition and appreciating the nitrogen/phosphorus ratio in other to determine the quantity of manure necessary for a proper fertilization of fish ponds.

    Methodology

    Study Zone

    The study was undertaken at the University of Dschang Research and Application Farm (FAR) and in the laboratory of Animal Nutrition of the University of Dschang with the following geographical coordinates: 5°44’-5°36’ and 5°44’-5°37’ Latitude North; 10°06’-9°94’ and 10°06’-9°85’Longitude East and an altitude of 1394 m in the Western Region of Cameroon. It has a Cameronian climate with an altitude characterized by a short dry season (mid-November to mid-March) and a long rainy season (mid-March to mid-November). Rainfalls vary between 1500 and 2000mm per year with an average of 1800mm and an average temperature of 22°C 17.

    Animal Material

    The guinea (Caviaporcellus) pigs used in this study were bought from peasants from the Menoua division, Western Region of Cameroon. A total of 96 (48 males and 48 females) guinea pigs weighing between 390 and 500g averagely were bought from local markets (Bafou and Fongo-Tongo).

    Housing

    The study was conducted within a special building of 50 m² which protects the animals from rain, sun; excessive cold and predators while providing them light with good ventilation. In this building, 96 guinea pigs were uniformly distributed in 12 boxes (of 7.2 m2) separated with the help of plywood placed on cemented floor. Six (6) boxes were covered with a layer of litter made of white wood chip and six were without litter.

    Feeding

    These Animals were Fed 3 Times/Day with 8 Different Feed

    Bracharia ruziziensis, Trypsacum laxum, Panicum maximum, Pennisetum clandestinum, Pennisetum purpureum, Arachis glabata, Desmodium intortum, and Calliandra calothirsus harvested two times per week from the university campus and its environs.

    Experimentation and Data Collection

    96 (48 males and 48 females) adult guinea pigs (Caviaporcellus) weighing 390 ± 110 g averagely were used. These animals were randomly distributed into two lots and maintained in 12 identical boxes of 0.6 m2 each (4 males and 4 females of comparable weight per box). From these 12 boxes, six (6) had a floor covered with 375g of litter and six had an empty floor. Within 12 weeks (3 months), these 96 individuals were reared and fed 3times/day (7-7:30am, 12-12:30 and 5:30-6pm) with Brachariaruziziensis, Trypsacumlaxum, Panicum maximum, Pennisetumclandestinum, Pennisetum purpureum, Arachis glabata, Desmodiumintortum, and Calliandracalothirsus. The guinea pigs dungs were collected after 3 days at the same time between 6 to 7 am within the experimentation period. After cleaning the boxes, the dungs from the floor without litter were separated from feed debris and weighed while those from the floor with litter were equally separated from feed debris and weighed with litter using and electric scale (CAMRY). The weight of the dungs from the littered floor was then separated from that of the initial litter in other to evaluate the quantity of dung produced. After this collection, three samples per lot were taken for bromatological analysis in the laboratory of Animal Nutrition of the Faculty of Agronomy and Agricultural Science (FASA) of the University of Dschang as described by Kjeldhal 18 in other to determine the nitrogen and phosphorus content as described by Pauwels et al19. The analysis helped in evaluating the quantity of dungs necessary for the fertilization of a fish pond with a known area and to know the number of guinea pig to be reared in a fish pond with a known area.

    Evaluation of the Quantity of Dung Produced by a Guinea Pig

    At the end of the experiment, the total quantity of dung collected from the littered floor was determined. This quantity deduced from that of the litter helped to determine the exact quantity of dung produced by the animals. In the second lot without litter, the calculation method was the same with the exact quantity of dung produced directly obtained without litter.

    Statistical Analysis

    In other to compare the differences between the nature of the floor and the breeding boxes for the collection of dungs of guinea pigs, the different data collected were subjected to the test of student. The Ducan test was used to separate means at a threshold significance of 1% when there was significant different between the means. The SPSS 21.0 software was used for the analysis.

    Results and Discussion

    Productivity of Dungs of Guinea Pigs

    (Table 1) shows the productivity of guinea pigs dungs by animal reared on a littered and empty floor respectively.

    Table 1. Production of guinea pig dungs
    Period / Methods Daily (g) weekly (g) Monthly (g)
    Without litter 51.69±0.36b 361.83±2.53 b 1550.7±10.83 b
    With litter 60.53±0.64 a 423.71±4.49 a 1815.9±19.26 a

    a and b: means with the same letters on the same line are not significantly different (P>0.01)

    The quantity of dungs collected was greater when the floor was covered with litter. Hence, 60.53±0.64g and 51.69±0.36g of dung/guinea pig/day were respectively collected from a littered and empty floor. This weight difference is significant at a threshold of 1% (p˂0.01). This might be due to the fact that the litter that absorbed urine was not taken into consideration during the weighing of the weight and calculations. Urine has good nitrogen content. It would be therefore appropriate to advise farmers to collect dungs from a littered floor. Hence, not only the biomass would be high, but also the nitrogen content.

    Dry Matter Productivity of Guinea Pig Dung

    The daily dry matter productivity of guinea pig dung per animal is summarized in Table 2

    Table 2. Daily dry matter production of guinea pig dung per animal
      Floor with litter Floor without litter
    Weight of fresh dung (g) 60.53± 0 .64a 51.69 ± 0.36b
    Weight of dry matter (g) 57.06 ± 0.11a 48.73 ± 0.07b
    % dry matter 94.28 ± 0.12a 94.28 ± 0.05a

    a and b: means with the same letters on the same line are not significantly different (P>0.01)

    The percentage of dry matter is high with or without litter (94.28%) which is an evidence of low moisture content of 5.72%. Hence, the dungs of guinea-pigs present a good content of dry matter available for the production of planktonic biomass and the direct feeding of fish species in heterotrophy ponds. This is in accordance with the works of Dabbadie et al 20 which stipulate that when an organic particle enters water, it future doubles. It is either consumed directly by heterotrophic especially some fish or degraded to release mineral elements which permits the production of phytoplankton by photosynthesis. However, FAO, 21, Dabbadie et al 20 and Pouomogne 22 determined the maximum safety level of animal organic matter in cool and temperate climate of 0.6kg DM/j/100m2 fish pond and in hot and tropical climates of 1.2 kg DM/100m2/j fish pond.

    Chemical Composition of the Dungs of Guinea Pig

    The different chemical components of the guinea pigs dungs are presented in Table 3 and Table 4.

    Table 3. Chemical composition of the guinea pigs dungs in percentage of dry matter
    Chemical composition of dungs Dry matter Crude protein Ash Organic matter
    Percentage (%) 94.28 ± 0.12 10.65 ± 0.20 19.89 ± 0.01 80.01 ± 0.21

    Table 4. Mineral content of guinea pigs dungs
    Minerals of dungs Total minerals (%) Nitrogen (%) Phosphorus (%)
      19.89 ± 0,50 22.715 ± 0,32 0.74 ± 0,21

    (Table 3) summarizes the crude protein, ash and organic matter contents of dungs. The different percentages of the crude protein, ash and organic matter are respectively 10.65%; 19.89% and 80.01%. This explains the richness of these dungs in nutritive elements which are available for the feeding of different fish species. The crude protein content (10.65%) in the guinea pigs dungs corroborates with the results obtained by Friote 23 and Pouomogne 24 on the crude protein content of some plants and fruits often used for the feeding of fish and fertilization. They explained that crude protein contents between 6 and 26% give good yields. This high content of organic matter (80.01%) is largely greater than 15% obtained with pig manure and slightly less than 88% in chicken droppings obtained by Efole 25. This content (80.01%) of organic matter is high for the fertilization of fish ponds in other to stimulate the natural production of phytoplankton and zooplankton.

    After the conversion of percentages into grams, it is noted that in 51.69g of dungs produced, there exist 11.74g of nitrogen and 0.38g of phosphorus. The high quantity of nitrogen noted in the dungs can be due to the high protein content of feed. Therefore, these dungs can be of great aquaculture interest as the N/P ratio of the inputs is an important factor for the organic fertilization of fish ponds. According to Pouomogne et al 22, the nitrogen and phosphorus quantities in water have to be 1mg/l and 0.5 mg/l respectively. Moreover, in Thaïland having weather conditions (average temperature=25°c, average altitude=1778.33m) similar to that of the Western Region of Cameroon Knud-Hansen 26 noted that there is no universal recipe for the maximum rate of nitrogen and phosphorus fertilization because of the variability of fish ponds (every fish pond has its specificity). However, Knud-Hansen 26 stated that this rate might be around 30kg of nitrogen/ha/week and 10kg of phosphorus/ha/week in the breeding of tilapia that is 42.85 g/day/100 m2 and 14.28 g/day necessary /100 m2 respectively. Lin et al 27 proposed contributions made between 20 and 40g of nitrogen/100m2/day. Also, Edward 28 noted that in Thaïland 2 to 4 kg of organic nitrogen /ha/day are necessary for the production of 7.3 and 10.95 tons of fish/ha/year in the breeding of tilapia. According to the nitrogen production by guinea pigs and propositions of the above mentioned authors, 2 to 4 guinea pigs/day/100m2is necessary for the individuals to produce 20 to 40g of nitrogen/day as recommended by Lin et al 27 and Edward 28. These animals have to produce between 88.06 to 176.12 g of dungs per day. These numbers can give an expected result of 10.21tons of fish/ha/year. However, according to Dabbadie and Lazard 20, during integration, the number of animals varies with the intensification level, weight and age of the animals.

    Conclusion

    At the end of this study on the prospects of integrating caviaculture and fish farming in the Western Region of Cameroon, it appears that the production of guinea-pig manure is of the order of 60.53 ± 0.64g when the floor is littered and of 51.69 ± 0.36g when the floor is not covered.

    The bromatological analysis showed that the guinea pig dungs have high content of organic matter (80.01%), dry matter (94.28%), ash (19.89%), crude protein (10.65%), nitrogen (22.715%) and phosphorus (0.734%). However, the phosphorus content has to be improved in other to optimize production.

    From these results, one can conclude that the integration of caviaculture-pisciculture is possible with a lot of interest taking into account based on these interesting bromatological values obtained. This is because the fertiliser is effective when it has high nitrogenous and phophorus content.

    With regard to all these quantities of nitrogen and phosphorus in the dungs, a ratio of 2 to 4 guinea pig/ 100m2 fish pond can be proposed but corrections should be made as regarding the phosphorus content which is slow in the dungs. This type of breeding (integrated breeding) helps in the reduction of production cost.

    However, the study should be extended for a longer period of time by including tests (experiments) in fish ponds.

    References

    1.FAO. (2009) Situation mondiale de l’alimentation et de l’agriculture: point sur l’élevage. FAO (Ed). Rome (Italie). 202, p..
    2.FAO. (1990) La situation mondiale des pêches et de l’aquaculture ; Département de Pêches et Aquaculture, FAO (Ed). , Rome (Italie)
    3.FAO. (2006) State of world aquaculture. FAO Fisheries technical paper. No500. Rome. 128p + Annexes .
    4.Lazard J. (1984) L’élevage du tilapia en Afrique: Données techniques sur sa pisciculture en étang In Bois et foret des tropiques. 300(206), 33-50.
    5.Pouomogne V. (1993) Growth response of Nile Tilapia to cow manure and supplemental feed. , Cameroon Journal of Agricultural Science 30(4), 1-14.
    6.R E Brummett, Noble et. (1995) Analysis of aquacultures investments in periurban. Yaoundé, Cameroon. Aquaculture Economics and Management,8(5/6): 1-10.
    7.Morissens P, Oswald M, S. (1996) Designing new fish farming models. , Bull.Fr. Pêche pisci 385, 01-16.
    8.Efole E T. (2011) Optimisation biotechnique de la pisciculture en étang dans le cadre du développement durable dans l’exploitation familiale agricole au Cameroun. Agrocampus Thèse de doctorat à l’Université de Dschang.176p.
    9.Kerchove V Van De, M Carpaye D et. (2002) L‟épandage pour tirer parti de l’intérêt. , Aquaculture 110.
    10.Tafatia T. (2013) Effet de quelques engrais sur la productivité du NKEA (Solanum macrocarpon) (Solanaceae) sur le sol ferralitique à Yaoundé. Mémoire de Di.P.E.S.II Université de Yaoundé I. 61.
    11.Agadjihouède H, A Bonou. (2010) Production des zooplanctons en bassin fertilisés avec la fiente de volaille et la bouse de vache. , Calavi. 01 BP 526 Cotonou. Benin. Int. J. Biol. Sci 4(2), 432-442.
    12.Hardouin J, Demey F, Fransolet F. (1991) Le cobayeCaviaporcellusL., animal de boucherie en pays tropicaux. Animales de Gembloux. 97 : 69-80.
    13.Ngou N J D, Kouonmenioc J, Fotso T, Cicogna M, Castroville C et al. (1995) Possibilités de développement de l'élevage du cobaye en Afrique subsaharienne: le cas du Cameroun. World Animal Review FAO/AGA. 83(2), 20-28.
    14.F et Grongnet J. (2011) Ingestion et digestibilité in vivo du Panicum maximum associé à trois compléments: tourteau de coton. (Gossipium hirsutum) et Euphorbia heterophylla chez le cobaye (Cavia porcellus). L'agronome. [CD-ROM] , Montpellier, France:, Cirad, Gret, France-MAE. Tropicultura 28(3), 173-177.
    15.NRC. (1991) Microlivestock; Little-known small animals with a promising economic future. National Academy Press. , Washington, DC.pp 241-249.
    16.Meutchiéyé. (2013) Et pourquoi pas l’élevage de cobaye? Technique animale. Cameroun. Voie du paysan. 24.
    17.DDADER. (2010) Rapport circonstancie sur les changements climatiques dans le département de la Menoua. 10.
    18. (1990) Official method of analysis15thedition. AOAC. , Washington DC, AOAC (Association of Official Analytical Chemist)
    19.J M Pauwels, E van Ranst, Verloo M, A Mvondo Ze. (1992) . Manuel de Laboratoire de pédologie. Publications Agricoles N° 28. Bruxelles:AGCD .
    20.Dabbadie L, Lazard J, Oswald M. (2002) Pisciculture et élevage non conventionnel : pisciculture, mémento de l’agronome, CIRAD-GRET(Ed), ministère des affaire étrangère. , (France) 2, 1571-1651.
    21.FAO. (1997) Méthodes simples pour l’aquaculture pisciculture continentale. , Rome.232p
    22.Pouomogne V, J P Nana, J B Pouomogne. (1998) Principes de Pisciculture appliquée en milieu tropical africain. Comment produire du poisson à coût modéré (des exemples du Cameroun). CEPID/Coopération Française Yaoundé. Presses Universitaires d’Afrique (Ed), Yaoundé (Cameroun). 236, p..
    23.Friot D. (2002) Quelques aliments et matière premières utilisés en alimentation des animaux dans les zones tropicales. In Mémento de l’agronome CIRAD-GRET (CD-ROM), Ministère des affaires étrangères , Paris (France), 36p .
    24.Pouomogne V. (2005) Study and analysis of feed and nutrients (including fertilizers) for sustainables aquaculture developement in Cameroun. , FAO 31, p..
    25.Efole T. (2008) Evaluation du rendement agro-écologique de la pisciculture en étang en zone soudano-guinéenne d’altitude de l’Ouest-Cameroun. Thèse de master en biotechnologie et production animale Université de Dschang. , Cameroun, 89p
    26.Knud-Hansen. State University (1998) Pond fertilization: Ecological Aproach and Application In pond dynamics/ Aquaculture Collaborative Research Support Progrm. , Oregon 102-103.
    27.C K Lin, D R Teichert, Bartholomew W, K L Veverica. (1997) Fertilization regimes. In dynamics of ponds aquaculture.Edited by. , Bocaraton 437, p.
    28.Edwards P. (1993) . , Integrated fish farming.InfofishInt 5, 45.