Mineral Composition and Effect of Biochar on Preweaning Reproductive and Growth Performance in Cavy (Cavia porcellus) ()
1. Introduction
In Africa in general and in Cameroon in particular, the imbalance observed between population growth and animal protein supply leads to increased malnutrition in most low-income families [1] [2] [3]. To fight against this scourge, the development and popularization of mini-breeding offer an alternative source of protein as much as they would contribute globally to the country’s economy through the promotion of employment, trade and the preservation of biodiversity [4]. Thus, caviar farming, which does not require large initial investments, has the characteristics of an economically profitable mini-farm that can effectively participate in the fight for food security [5]. Despite its potential for meeting these needs, animal feed remains a real handicap for improving its production [5] since it represents more than 70% of production costs [6]. One of the possible solutions is the use of fodder legumes and other non-conventional protein sources whose nutritional value varies very little according to the seasons [3]. However, it has been observed that animals do not make the most of these forages, due to the poor health of their intestinal flora. Like ruminants, cavy harbor a large microbial population that ensures digestion and maintenance of microbial activity that requires a continuous supply of minerals to ensure proper functioning of the cecum. Yet, besides C, H, O, N, and S, mineral elements (Mg, Ca, K, and P) are also present on the surfaces of biochar [7]. It is widely documented that, vitamins and minerals play an important role in animal growth and physiological functions, as well as reproductive performance [8]. Phosphorus and magnesium are essential skeletal components and are also involved in microbial fermentations in the rumen flora. Iron, present in hemoglobin, transports oxygen to tissue and muscle cells. It is essential for the production of adenosine triphosphate (ATP), the primary source of body energy. Selenium (Se) is necessary for growth, fertility of animals and prevention of various diseases [9]. Previous studies have shown positive effects of Canarium schweinfurthii Engl kernel charcoal used as growth promoters in birds [10]. The biochar modified feed has shown potential in controlling zoonotic pathogens in poultry [11]; reducing methane emissions in the rumen of cattle [12] and goat [13]. This charcoal could also bind feed toxins [10] that are either excreted in feces or degraded by certain organisms in the animal’s gut microbiota. Based on previous results, the use of biochar in guinea pig diets could improve digestibility and therefore production performance. As very little information exists to this effect, the objective of the present study is to determine the mineral composition of cassava peelings, cocoa pod husks and bean tops biochar in order to evaluate their effects on the reproductive performance and pre-weaning growth of cavy.
2. Material and Methods
2.1. Study Area
This study was conducted between February and April 2021 in the Animal Production and Nutrition Research Unit (URPRONAN) of the University of Dschang. Located in the highlands of West Cameroon at an altitude of 1410 m, at longitude East 09˚5' - 10˚06' and latitude North 5˚36' - 5˚44'. This region receives between 1500 and 2000 mm of water per year, with temperatures ranging from 10˚C to 25˚C. The climate is equatorial with a short dry season from mid-November to mid-March and a long rainy season from mid-March to mid-November.
2.2. Animal Material and Housing
For this trial, ninety-six (96) adult cavies were placed in a completely randomized setup, i.e., 80 females and 16 males of comparable weight (400 ± 0.25) distributed in four identical boxes of size (2.5 m × 0.5 m), delimited by plated counter. Each box contained 4 males and 20 females conducted for 31 days. The floor of each lodge was lined with white wood shavings, which were renewed weekly to avoid the accumulation of feces and urine. Each lodge was equipped with a heating device, a plastic drinker and two wooden feeders and covered with a wire mesh to avoid the introduction of predators.
2.3. Plant Material
The plant material consisted of agricultural residues (cassava peelings of variety 8034; cocoa pod husks of variety forastero and bean tops of variety GLP) (Figure 1) harvested in the department of Menoua, for the manufacture of the different organic charcoals. These agricultural residues were chosen because of their accessibility and local availability.
2.4. Processing of the Different Biochar
The biochar used was obtained by slow pyrolysis of three plant residues that were chosen because of their accessibility and local availability. The different biochar obtained were crushed and sieved with a 2 mm mesh sieve before being incorporated at 0.8% in the compound feed.
(a) (b) (c)
Figure 1. Cassava peelings (a); cocoa pod husks (b); bean tops (c).
2.5. Experimental Rations
The ration was formulated according to the nutritional requirements of the cavy, and the ingredients were purchased from dealers of agricultural by-products. A single feed was composed with these ingredients (Table 1) and to this feed was added 0.8% of biochar powder as a feed additive to make the different experimental rations. The different rations were then pelleted before being fed to the animals.
The daily pelleted ration served was 0.15 g/g PV for each treatment consisting of the following:
• T: basal diet without charcoal (control);
• EM: basal diet containing 0.8% cassava peelings charcoal powder;
• CC: basal diet containing 0.8% charcoal powder of cocoa pod husks;
• FH: basal diet containing 0.8% charcoal powder of bean tops.
2.6. Evaluation of the Mineral Composition of Biochar
The powder of each biochar (100 g) was collected and analyzed at the laboratory of Environmental Analysis of the University of Laval-Quebec for the determination of the mineral composition following the procedure described by AOAC [14].
2.7. Evaluation of the Effects of the Different Biochar Powders in the Ration on the Reproductive Performance of the Cavy
A digestibility test was previously carried out with six organic charcoals (plantain peelings, cassava peelings, cocoa pod husks, coconut husks, maize cobs and bean tops) compared to the basal diet. Three charcoals (cassava peelings, cocoa pod husks and bean tops) were selected for this trial. Ninety-six (96) adult cavies were placed in a completely randomized design. At the beginning of the trial, the number of breeding females as well as their fasting weight was recorded and these females were distributed homogeneously in each pen where they followed several successive stages: mating—gestation—parturition—lactation—weaning of the young. During gestation, the number of females that aborted was recorded. The number of females that gave birth and the date of parturition were then recorded. At birth, the number of stillborn and live-born kids was recorded.
Table 1. Centesimal composition of the feed.
*The analytical calculation of the 10% concentrate used shows 40% crude protein, 3% lysine, 1.7% methionine, 7% calcium, 1.8% phosphorus and 2100 kcal/kg metabolizable energy.
Then, the number of dead kids before weaning and the number of weaned kids were also recorded. The amount of feed served (between 7:00 and 9:00 am) was maintained in pregnant and lactating pigs until weaning (21 days after birth).
The following reproductive parameters were evaluated:
Fertility or parturition rate = (females with mid-calf)/(females mated) × 100;
Fecundity rate = (stillbirths + live births)/(females bred) × 100;
Net fecundity rate = (live-born young)/(females bred) × 100;
Litter size = (pups born)/(females in mid-calf);
Viability at birth = (live births)/(live births) × 100;
Weaning viability or weaning rate = (weaned)/(live-born) × 100;
Pre-weaning mortality rate = (kids dead before weaning)/(kids born alive) × 100.
2.8. Evaluation of the Effects of Different Biochar Powders in the Diet on the Pre-Weaning Growth Performance of Cavy
At birth, each newborn was identified with numbered loops attached to the ear. Furthermore, at farrowing, the dams were weighed as well as their young. Also, during this breeding period, the weights of breeding females, during lactation and of the pups after birth were recorded weekly. These data were used to determine feed intake, weekly weight change, total weight gain (TG) (g) and average daily gain (ADG).
2.9. Statistical Analysis
Data were subjected to one-way analysis of variance (ANOVA) following the general linear model (GLM). When significant differences existed between treatments, the means were separated by the Waller Duncan test at the 5% significance level [15]. The SPSS 26.0 analysis software was used.
3. Results
3.1. Mineral Composition of the Different Biochar
The mineral composition of the different biochar produced shows that it varies with the nature of the substrate (Table 2). The bean husk charcoal has the highest ash content (26%), while the lowest content is that of cocoa pods. Regarding macro-elements, Ca, K and P concentration was higher with bean husk biochar, and Na concentration was higher in cassava peel biochar. Cocoa pod shell biochar showed the highest Mg concentration. For trace elements, the concentration of Cd, Cr, Fe, Pb and Se was higher with cassava peel biochar, and that of B, Cu, Ni and Zn was higher in cocoa pod shell biochar. The bean husk biochar had the highest concentration of Mo.
3.2. Effects of Different Biochar Powders on Reproductive Performance
The average reproductive performances of females according to the type of charcoal included in the ration revealed (Table 3) that females receiving the rations containing the different biochar showed (except for fertility rate), the lowest fertility rates, net fertility rate, viability at birth compared to the control. Similarly, the abortion rate was very high (>50%) in females receiving the ration containing the biochar.
3.3. Effects of Different Biochar Powders on Growth Performance in Cavy
3.3.1. Feed Intake in Female Breeders
The inclusion of the different biochar at 0.8% in the pelleted feed had no significant effect (p > 0.05) on the ingestions of dry matter, organic matter, crude protein and crude cellulose in female breeders (Table 4).
Table 2. Mineral composition of biochar.
Table 3. Average reproductive performance in cavy according to the different rations.
Table 4. Feed intake in cavy during gestation according to different rations.
SEM: Standard Error on the Mean; p: Probability; CV: Coefficient of Variation; T: Feed without charcoal (control); EM: Feed containing 0.8 charcoal based on cassava peelings; CC: Feed containing 0.8 charcoal based on cocoa pod husks; FH: Feed containing 0.8 charcoal based on bean hulls.
3.3.2. Variation in Weight of Lactating Females
The variation in the average weight of lactating females during the lactation period shows that, overall, the percentage of weight loss of animals fed the charcoal-containing diet remained low compared to that of animals fed the control ration (Figure 2). In fact, lactating cows receiving the EM ration recorded a weight gain of 0.91%; the CC ration, a loss of 9.87%; the FH ration, a loss of 1.49% and the control ration a loss of 21.71%.
3.3.3. Weight Variation of Pre-Weaned Kids
The variation in the weight of the kids from birth to weaning, according to the rations (Figure 3) shows that, at birth and at weaning, the animals receiving the FH ration had the highest average weight (96 g and 197.25 g). The animals receiving the 0.8% cassava peel charcoal (EM) ration had the lowest average weight (79.83 g) at birth, while at weaning the lowest average weight (137.7 g) was recorded with the animals receiving the control ration (T). The animals receiving the FH ration had the highest weight gain (105.47%), followed by the animals receiving the EM ration (102.92%), then the animals receiving the CC ration (74%) and finally those receiving the control ration (52.49%).
Overall, we note that the animals receiving the feed containing organic charcoal showed the best results, especially those receiving charcoal made from bean tops.
The weight evolution of kids from birth to weaning according to the feed rations reveals that at birth, the different rations had no significant (p > 0.05) effect on piglet weights (Table 5).
At weaning, the weights of animals receiving the control, EM, and CC rations were comparable and significantly lower than those receiving the FH ration.
The TG and ADG of the animals receiving the rations containing the biochar were significantly higher than the control, and the FH ration had the highest TG and ADG (p < 0.05).
4. Discussion
For this study, the organic biomasses used to make the different biochar are of
Figure 2. Variation in average weight of lactating females from farrowing to weaning, according to feed rations.
Figure 3. Variation in piglet weight from birth to weaning, according to rations.
Table 5. Weight evolution of kids from birth to weaning according to feed rations.
a; b; c; d: Means with the same letters on the same line are not significantly different at the 5% level; ADG: Average daily gain; SEM: Standard error of the mean; P: Probability, CV: Coefficient of variation; ( ): Number of kids.
plant origin (cassava peelings, cocoa pod husks and bean tops) and rich in carbon. In Cameroon, these residues are buried in the soil as an amendment or burned, resulting in environmental pollution [16]. However, in agronomy, these residues would present more advantages when used as biochar. Feedstock, temperature, temperature rise rate, and particle size can affect the physicochemical properties and quality of biochar [17]. However, biochar is predominantly composed of carbon, hydrogen, nitrogen-oxygen, and sulfur [13]. Besides C, H, O, N, and S, mineral elements are also present on the surfaces of biochar [7]. The high mineral concentration in bean tops charcoal is thought to be related to the high ash content in the charcoal. Indeed, Zama et al. [7] report that, increasing the ash content of coals favors increasing the concentration of Mg, Ca, K and P. which is in agreement with our results.
Regardless of the reproductive parameter studied, females receiving the control ration showed the best rates, (except for fertility rate, litter size, viability at weaning and pre-weaning mortality rate which are comparable between treatments) compared to the other treatments. Abortion rates of 50%; 62.50% and 63.16% respectively of EM; CC and FH charcoals were recorded. This rate remained very high compared to the 11.76% observed at the control ration. This high abortion rate could be explained by the fact that carbons generally have a high specific surface area which gives them a high adsorption capacity (A). This could also be related to the very high phosphorus level on the surface of biochar, which could affect the absorption of certain minerals. As demonstrated by Guivier (1974), quoted by Boussarie [18], an excess of phosphorus is very damaging because it increases the need for Mg, Ca, K by reducing their intestinal absorption by 50%. Overall, excess phosphorus in the diet is more harmful to the guinea pig than excess calcium, which is relatively well tolerated. It should also be noted that calcium deficiency at the end of gestation can result in difficult births and dystocia. Hence, the birth of unsustainable kids and very weak females those sometimes die a few days after giving birth. The highest abortion rate with the FH ration would be due to the high level of macro-elements (calcium, potassium and phosphorus) in the bean charcoal. These macronutrients could interfere with the absorption of trace elements such as copper, iodine, manganese, selenium and zinc, which have an important impact on reproduction [19] and whose deficiency causes abortion [20]. Females receiving rations containing 0.8% charcoal (EM, CC and FH) had the lowest fecundity (44.44%, 43.75% and 42.11%) and net fecundity (33.33%, 25% and 21.05%). This would be related to the high rate of abortions recorded with these rations, which thus reduce the number of pups at farrowing. Therefore, the viability rate will be affected, as this rate is related to the number of viable pups at birth. Feed intake was comparable between the different treatments. These results are contrary to those obtained by Mekbungwan et al. [21] who reported that biochar would significantly increase feed intake in kids when incorporated into the ration. On the other hand, the work of Kana et al. [10] showed that biochar significantly decreased feed intake in poultry when incorporated into the ration. This difference would be explained by the fact that feed intake varies by animal species.
From farrowing to weaning, a low percentage of weight loss was recorded in lactating females fed a diet containing biochar. Since one of the particularities of cavy is the suckling of their offspring, this low weight loss would be related to the number of lactating animals. This is because milk secretion could continue after abortion. In contrast to the lactating females on the charcoal diet, those on the control diet showed a significant weight loss. This could be explained by the fact that during lactation, dams expend a lot of energy for milk production [22]. In addition, the female has to make a lot of effort to cover the demand of the young [23]. She must therefore mobilize her body reserves to ensure satisfactory milk production, which would explain the observed weight loss. However, the slight weight gain in lactating females fed the EM diet could be explained by the presence of the more concentrated trace elements in this charcoal: iron (172,115.11 mg/kg) which is essential for the production of adenosine triphosphate (ATP), the primary source of body energy; and selenium (53.21 mg/kg) which is necessary for growth, fertility and the prevention of various diseases [9]. In this study, the average birth weights of the kids were comparable to each other. At weaning, the incorporation of biochar in the feed improved the weight gain of the kids. This is thought to be due to the fact that biochar increases digestion of the feed while providing a habitat for the gut microbiota to become more efficient [12]. The highest average weight (197.25 ± 46.9 g) obtained with the FH ration is thought to be related to the macronutrients involved in the microbial fermentations of the cecal flora. Thus, phosphorus and magnesium would be used by the caecal microbes for cellulose digestion and microbial protein synthesis [19]. This results in increased nutrients from the coprophagic process in the guinea pig [18]. Like the ruminant, the proper inclusion of calcium in the ration is imperative for proper physiological function and growth of cavy [24].
5. Conclusion
At the end of this study, it appears that:
• The mineral composition of biochar varies with the nature of the substrate;
• The supplementation of biochar as a feed additive (0.8%) in the guinea pig feed is detrimental to reproduction;
• Cassava peelings biochar is better for postpartum growth in cavy while bean tops biochar shows the best results for kid growth.