1. Introduction
The demographic growth of the populations of the Third World countries induces a strong demand for proteins of animal origin. To solve this problem, particular emphasis must be placed on mini-breeding in general and the breeding of guinea pigs (Caviaculture) in particular, which could be an alternative to fighting against malnutrition and poverty in Africa in general and in Cameroon in particular [1]. In fact, guinea pig is monogastric with a strictly herbivorous diet, which makes better use of local food resources [2]. It is mostly bred and consumed in western and southern Cameroon. It is involved in various cultural events such as dowries, weddings and funerals. In addition, its breeding can help increase the income of the peasant and it is also used in science as an experimental animal [3].
Despite these nutritional, economic and cultural advantages, caviaculture is still slow to take off because of its low productivity due to the instability of its intestinal flora [4] [5]. Indeed, a variation of its diet would be likely to unbalance its intestinal microflora leading to poor growth and a high rate of mortality. Concerned with this problem, several studies have been carried out with the aim of discovering substances capable of stabilizing the intestinal flora, preventing mortalities on one hand and improving the growth of animals on the other hand. As such, feed additives in general and phytobiotics in particular have seen their use increase in recent years [6]. Indeed, phytobiotics are preparations made using the roots, barks, leaves, stems, plant extracts, spices and/or essential oils which, in animal feed, could improve the zootechnical performance of animals.
Dracaena arborea is a plant of the Asparagaceae family [7], native to Central Africa, used in traditional pharmacopoeia to treat epilepsy and infertility among others [8]. Indeed, this plant reveals the presence of bioactive compounds such as saponins and terpenoids which, according to Abdel-Ghaney et al. [9] and Chakraborty et al. [10] are growth promoters and are believed to have a beneficial effect on the intestinal microflora by increasing the absorption of nutrients. The aim of the present study is therefore to contribute to the improvement of the diet of guinea pigs, through the valuation of Dracaena arborea roots powder as a feed additive, on growth characteristics and some hematological parameters of young guinea pigs post-weaned.
2. Materials and Methods
2.1. Study Zone
The study was carried out from January to April 2020 at the Application and Research Farm (FAR) and the Animal Production and Nutrition Research Unit (URPRONAN) of the University of Dschang. Dschang is a locality located in the West Region of Cameroon, at 1400 m altitude and 05˚26' North latitude and 10˚26' East longitude. The average temperature in the area is 20˚C and the relative humidity reaches 83.5%. The rainfall, which is between 1500 and 2000 mm, is unevenly distributed between a rainy season (from mid-March to mid-November) and a dry season (from mid-November to mid-March).
2.2. Animal Equipment and Housing
The study involved 40 weaned, local breed, 3-week-old guinea pigs (20 males and 20 females) from the FAR of the University of Dschang. The animals were randomly distributed into 4 groups or treatments of 10 subjects each (05 males and 05 females) and kept in boxes (1.25 m in length, 0.60 m in width and 0.25 m in height) constructed with plywood and fitted with wire mesh covers to protect animals from predators.
2.3. Plant Material
The plant material consisted of fresh young roots of Dracaena arborea and Trypsacumlaxum. The young roots, harvested at the foot of an adult Dragon tree in Dschang were then chopped to a size of about 5 cm, dried in an oven set at 40˚C for 48 hours, crushed and sieved using a 0.9 mm diameter sieve. The powder thus obtained was analyzed at URPRONAN to determine its chemical composition. Trypsacumlaxum, used as a staple food, was harvested daily at the FAR and pre-wilted before being fed ad libitum to the animals the next day. The chemical compositions of Dracaena arborea and Trypsacumlaxum powder are shown in Table 1.
2.4. Formulation of the Different Experimental Rations
Four rations were made from the different levels of incorporation of Dracenaarborea roots powder into the concentrated feed (Table 2) consisting of ingredients purchased from local agricultural by-product dealers. As such, the rations Da0; Da0.25; Da0.5 and Da0.75 were formulated from the respective incorporation, of 0%; 0.25%; 0.5% and 0.75% Dracenaarborea. Each group or batch of animals received, in addition to Trypsacumlaxum served ad libitum, 40 g of the considered ration as follows:
- Control or basic ration Da0: Trypsacumlaxum ad libitum + 40 g of feed composed of 0% Dracenaarborea powder/animal/day (Batch D0);
Table 1. Bromatological composition of Dracaena arborea roots powder.
Table 2. Percentage composition and bromatological characteristics of the compound feed.
*Premix 2%: Crudeprotein: 40%; Lysine: 3.3%; Methionine: 2.4%; Calcium: 8%; Phosphorus: 2.05%; Metabolizableenergy: 2078 kcal/kg.
- Ration Da0.25: Trypsacumlaxum ad libitum + 40 g of feed composed of 0.25% Dracenaarborea powder/animal/day (Batch Da0.25);
- Ration Da0.5: Trypsacumlaxum ad libitum + 40 g of feed composed of 0.5% Dracenaarborea powder/animal/day (Batch Da0.5);
- Ration Da0.75: Trypsacumlaxum ad libitum + 40 g of feed composed of 0.75% Dracenaarborea powder/animal/day (Batch Da0.75).
2.5. Experimental Design
Forty (40) weaned guinea pigs (20 males and 20 females), of local breeds aged between 3 to 4 weeks were randomly assigned to 4 groups or batches of 10 subjects each. Each batch consisted of 05 males and 05 females housed separately to avoid mating. Feed rations were randomly assigned to different groups of animals. The control or basic ration allocated to group D0 did not contain Dracaena arborea powder. The animals of batches D2, D3 and D4 received in addition to the basic ration, 0.25% (ration Da0.25); 0.5% (Da0.5 ration) and 0.75% (Da0.75 ration) respectively, of Dracaena arborea roots powder incorporated in the compound feed. Drinking water containing vitamin C (185 mg in 3l of drinking water) was served ad libitum.
2.6. Growth Performance Assessment
The animals were fed once a day, between 7 am and 9 am, with their respective rations. At the start of the test, then every week (every 07 days), the animals were weighed and the weights recorded for the evaluation of the weight change from the 3rd to the 11th week of age as well as the total weight gains (TG) and average daily gains (ADG).
2.7. Evaluation of Carcass Characteristics and Some Digestive Organs
At 11 weeks of age, animals from each batch were subjected to a 12 hour fasting period, then slaughtered by cervical dislocation and throat bled to assess carcass characteristics, weights and measurements of the organs involved in digestion. The carcass yields, lengths and proportions of the different organs (digestive tract, intestine and cecum) in relation to the live weight of the animals at slaughter were evaluated. All the weights were measured using a digital balance with a capacity of 7 kg and a precision of 1 g. The length of the bowel was taken with a precision 1 mm tape measure.
2.8. Evaluation of Haematological Parameters
When the animals were slaughtered as described above, their blood was collected directly from the jugular vein using heparinized tubes (with anticoagulant), for the determination of the concentration of red and white blood cells, lymphocytes, monocytes, granulocytes, blood platelets, hemoglobin, and determination of hematocrit, mean blood cell volume, and mean hemoglobin concentration. All these hematological analyses were performed using the Genius electronic hemacytometer (Model KT-6180, S/N 701106101557).
2.9. Statistical Analyses
The data collected was subjected to one-way analysis of variance (ANOVA) (feed ration) according to the general linear model (MLG). When there were significant differences between treatments, means were separated using the Waller Duncan test at 5% significance level [11]. The analysis software used was SPSS 20.0.
3. Results
3.1. Effects of Incorporating Dracaena arborea Root Powder on Feed Intake in Guinea Pigs
Figure 1 illustrates the dietary intake of young guinea pigs at week 11, depending on the treatments and it appears that the values were not significantly (p > 0.05) different between the rations.
3.2. Effects of the Incorporation of Dracaena arborea Root Powder on the Weekly Weight Development of Guinea Pigs from the 3rd to the 11th Week of Age
The weekly weight evolution of guinea pigs from the 3rd to the 11th week of age is illustrated in Figure 2. It appears that the addition of Dracaena arborea roots powder to the ration resulted in an increase in live weight of weaned animals
Figure 1. Ingestion of guinea pigs according to treatment, at week 11. Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea.
Figure 2. Weekly weight evolution of young guinea pigs according to the treatments, from the 3rd to the 11th week of age. Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea, Da0.75 = Control + 0.75% of Dracaena arborea; W: Week.
from the 3rd to the 11th week of age, regardless of the ration. However, the highest live weight was obtained with the Da0.25 ration which, moreover, was comparable (p > 0.05) to that of weaned animals consuming the Da0.5 ration and significantly higher (p < 0.05) than those obtained with the Da0 and Da0.75 rations, which remained comparable (p > 0.05) with each other.
3.3. Effects of Incorporating Dracaena arborea Root Powder on Total Weight Gain (TG)
The comparison of the total weight gains of guinea pigs at the 11th week of age, depending on the rations, is shown in Figure 3.
It emerges from this Figurethat the total gains recorded were 139.25 g, 170.6 g, 161.75 g and 134.50 g respectively for the Da0, Da0.25, Da0.5 and Da0.75 treatments. These values for the animals which received the Da0.25 and Da0.5 rations were comparable (p > 0.05) to each other and significantly higher (p < 0.05) than those of the animals which received the Da0 and Da0.75 rations which, moreover, were comparable (p > 0.05).
Figure 3. Comparison of total weight gains for different treatments, at Week 11. a, b, c: the means with the same superscripts on the same row are not significantly different (p > 0.05); Da0: Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea.
3.4. Effects of Incorporating Dracaena arborea Root Powder on Average Daily Weight Gain (ADG)
The comparison, according to the rations, of the average daily gains at the 11th week is illustrated by Figure 4 and there we observe that the highest ADG (3.04 g) was observed with the ration Da0.25 which, nevertheless, was statistically comparable (p > 0.05) to that of the animals of the Da0.5 batch (2.88 g), moreover comparable to that of the animals of the Da0 batch (2.48 g) and significantly (p < 0.05) greater than that of the animals of batch Da0.75 (2.4 g).
3.5. Effects of Incorporating Dracaena arborea Root Powder on the Consumption Index
It appears from Figure 5 that the consumption indices of the different rations were not significant (p > 0.05) influenced by the addition of powder from the roots of Dracaena arborea in the ration.
3.6. Effects of the Incorporation of Dracaena arborea Roots Powder on Carcass Characteristics and Some Organs of the Digestive Tract of the Guinea Pig
Table 3 shows the effects of incorporating Dracaena arborea roots powder on the carcass characteristics of guinea pigs at the 11th week of age. It appears that the live weight at slaughter and the weight after bleeding recorded with the animals receiving the Da0.25 and Da0.5 rations were comparable (p > 0.05) but significantly higher (p < 0.05) than those of animals given the Da0 and Da0.75 rations which, moreover, were comparable (p > 0.05) to each other. The same trend was observed with commercial and conventional carcass weights. The addition of powder from the roots of Dracaena arborea had no significant effect
Figure 4. Comparison of average daily weight gains according to the different treatments, at the 11th week. a, b, c: the means with the same superscripts on the same row are not significantly different (p > 0.05); Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea.
Figure 5. Comparison of the consumption index between the different treatments, at the 11th week. Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea.
Table 3. Characteristics of the guinea pig carcass, according to the treatments.
a, b:the means with the same superscripts on the same line are not significantly different (p > 0.05); MSD: Mean standard deviation; P: Probability (5%); Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea; LWs: Live weight at slaughter.
(p > 0.05) on head, heart, kidney and entire digestive tract weights, as well as on commercial and classical carcass yields and organ proportions.
3.7. Effects of the Incorporation of Dracaena arborea Roots Powder on the Characteristics of Some Organs of the Digestive Tract
The weights and lengths of some digestive organs in guinea pigs at the 11th week according to treatments are presented in Table 4 and it appears that apart from the weight of the empty caecum and the length of the large intestine which were significantly influenced (p < 0.05), the addition of powder from the roots of Dracaena arborea had no significant effect (p > 0.05) on the organs of the digestive tract, regardless of the ration.
3.8. Effects of the Incorporation of Dracaena arborea Roots Powder on Some Haematological Parameters
Table 5 shows the effect of powder from the roots of Dracaena arborea on some haematological parameters in guinea pigs at week 11. It emerges that the blood platelet levels of the animals consuming the Da0 and Da0.5 rations were comparable (p > 0.05) and significantly higher (p < 0.05) than those of the animals from the Da0.25 and Da0.75 batches which, moreover, were comparable (p > 0.05) to each other. As regards lymphocytes (LYMPH), their concentrations in the animals of the Da0.5 and Da0.75 batches were comparable (p > 0.05) to each other but significantly higher (p < 0.05) than those animals from batches Da0 and Da0.25, which are otherwise comparable. The granulocyte concentration of the animals of the Da0 batch was significantly (p < 0.05) higher than that of the animals of batches Da0.25, Da0.5 and Da0.75 which, moreover, were comparable (p > 0.05) among themselves. Adding powder from the roots of Dracaena arborea to the ration had no significant effect (p > 0.05) on the other parameters.
Table 4. Weights and lengths of some organs of the digestive tract of guinea pigs, according to the treatments.
a, b:the means with the same superscripts on the same line are not significantly different (p > 0.05); MSD: Mean Standard Deviation; P: Probability; Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea.
Table 5. Effects of the incorporation of Dracaena arborea roots powder on some haematological parameters in guinea pigs.
a, b:the means with the same letters on the same line are not significantly different (p > 0.05); MSD: Mean Standard Deviation; P: Probability; Da0 = Control; Da0.25 = Control + 0.25% of Dracaena arborea; Da0.5 = Control + 0.5% of Dracaena arborea; Da0.75 = Control + 0.75% of Dracaena arborea; WBC = white blood cells, LYMPH = lymphocytes, MONO = monocyte, GRAN = granulocyte, RBC=red blood cells, HCT = hematocrite MGV = mean globular volume, HGB = hemoglobine MHC = mean hemoglobin concentration, PLT = platelet.
4. Discussion
Feed intake was comparable among the different treatments. Tene et al. [12] came to the same conclusion, incorporating ginger powder into the ration of post-weaned guinea pigs. The highest value (21.13 g DM/animal/d) recorded with the Da0.5 ration is close to that of the work of Faihum et al. [13] (29.59 g DM/animal/d) in guinea pigs fed with leaves of Moringaoleifera and Commelinabenghalensis and that of Tsafack [14] (30.94 g DM.animal/d) in guinea pigs fed with a ration containing 1% garlic and coupled with Stylosanthesguanensis. On the other hand, this value is lower than that reported by Zambou [5] (38.12 g DM/animal/d) in guinea pigs subjected to a ration containing 0.5% garlic powder. Thus, the same trend is observed with the work of Mweugang et al. [15] which revealed that feed consumption varies with the level and nature of the plant material incorporated in the ration.
The highest live weight recorded at the 11th week was obtained with the Da0.25 ration (372.43 g). This result is superior to that of Tsafack [14] (301 g) recorded in guinea pigs fed a ration containing 1% garlic and coupled with Stylosanthesguanensis, Miégoué et al. [1] (324.5 g) who used a ration supplemented with Arachisglabrata and Zougou et al. [4] (221 g) who fed the animals a ration with an energy content of 2800 Kcal/kg and crude protein of 18%. On the other hand, Zambou [5] obtained 395 g with a ration containing 0.1% garlic powder. These differences are thought to be due to the chemical composition of the feed containing Dracaena arborea roots powder and to the nature of the plant material incorporated in each of these rations.
The highest mean daily weight gain was recorded in animals receiving the Da0.25 ration (3.04 g/d). This result is superior to those obtained by, Zambou [5] (2.7 g/d) in animals fed a ration containing 0.5% garlic and by Tsafack [14] (2.74 g/d) in guinea pigs fed a ration containing 1% garlic and coupled with Stylosanthesguanensis. These differences could be explained by the presence in the ration of saponins and terpenoids from the powder of the roots of Dracaena arborea which would have stimulated the intestinal microflora, thus increasing the absorption of nutrients.
The consumption index was comparable between the different treatments. The highest value was recorded with the Da0 ration (7.54) and the lowest with the Da0.25 (6.80) ration. These values remain higher than those of Zougou et al [4] and Miégoué et al. [2] who obtained 5.20 and 4.18, respectively in animals given a ration containing 18% crude protein and in animals fed Pennisetumpurpureum.
The highest live weight at slaughter (372.43 g) was recorded with the Da0.25 ration. This result is lower than that of Zambou [5] (395 g) in guinea pigs fed a ration containing 0.1% thyme. This difference is explained by the chemical composition and the level of incorporation of the additive used. On the other hand, this result is superior to that of Noumbissi [16] (253.80 g) in guinea pigs fed with a ration supplemented with Tithonia. diversifolia. In addition to the above, Zougou et al. [4] recorded 221 g in guinea pigs fed a ration containing 16% protein. These differences could be explained by the nature of the bioactive molecules contained in the powder of the roots of Dracaena arborea, which could have favored the growth of guinea pigs.
The highest commercial and conventional carcass weights (161.75 g and 307.75 g respectively) were recorded with the Da0.25 ration. These results are superior to those obtained by Zambou [5] (114.83 g and 252.50 g) respectively for the weights of commercial and conventional carcasses in guinea pigs fed a ration containing 0.5% garlic. These differences could be related to the weight of the animals at slaughter, the chemical composition and the level of incorporation of the additive in the ration.
The highest commercial and conventional carcass yields (39.5% and 75.75% respectively) were recorded with the D0.25 ration. The highest conventional carcass yield is comparable to that of Zambou [5] (70.67%) in guinea pigs fed a ration containing 1% thyme. These results may be linked to the chemical composition of the powder of Dracaena arborea roots contained in the ration.
The highest liver weight (11.33 g) was obtained with the Da0.75% ration. This result is superior to that obtained by Zougou et al. [4] (10.96 g) and Zambou [5] (9.68 g) respectively in guinea pigs fed a ration containing 18% protein and in those fed a ration containing 1% garlic. From the above, Noumbissi [16] obtained 9.20 g in guinea pigs fed with a ration supplemented with T. diversifolia. The result obtained in the present work could be linked to the presence of the anti-nutritional factors contained in the powder of Dracaena arborea roots, which would have stimulated the liver to intervene in the detoxification process of the rations.
The highest small intestine density (0.08 g/cm) was obtained with the Da0 ration and the lowest (0.06 g/cm) was obtained with the D0.25% ration. These results are close to those obtained by Zougou et al. [4] (0.09 g/cm and 0.08 g/cm) in guinea pigs fed a ration containing 16% protein. Similarly, Zambou [5] obtained 0.07 g/cm and 0.08 g/cm in guinea pigs fed a ration containing 0.5% and 1% garlic. However, these different values are linked to the length and weight of the intestine. Indeed, the larger the intestine, the greater the microbial population and the greater the absorption of nutrients [17]. Moreover, these results are much lower than the 0.18 g/cm obtained by Tendonkeng et al. [18] in guinea pigs fed with Pennisetumpurpureum and supplemented with Desmodiumintortum. This can be explained by the high level of crude protein contained in this legume which improves digestibility and therefore absorption of nutrients, hence the development of the absorption surface.
The highest values for granulocytes (0.250.103/µl), platelets (805.103/µl) and for lymphocytes (6.92.103/µl) were, respectively, obtained with the rations Da0, Da0.5 and Da0.75. These values corroborate the observations of Djoumessi et al. [19] who found that the incorporation of Cucumalonga powder as a food additive in the ration of guinea pigs significantly improved these blood parameters. The explanation given by them was that phytobiotics are often used to purify blood and increase immunity by stimulating the body’s defense cells. In addition, Zambou [5] obtained 395.103/µl for platelets, 5.56.103/µl for lymphocytes and 4.35.103/µl for granulocytes. These different values might be linked to the chemical composition and the level of incorporation of the additive used. Overall, these values fall within the range of reference values of guinea pig hematological parameters governed by Quesenberry et al. [20].
5. Conclusion
At the end of this work it appears that the incorporation of powder from the roots of Dracaena arborea at 0.25% in the ration of weaned guinea pigs made it possible to obtain the highest live weight and weight gain at the 11th week of age. The Da0.25 and Da0.5 rations produced the highest carcass yields (commercial and conventional) and the highest caecum weight. Powder from the roots of Dracaena arborea had a significant effect on granulocytes, platelets and lymphocytes. But overall, the results were within the range of normal guinea pig haematological parameters. In short, the powder from the roots of Dracaena arborea is an appreciable source of protein that can be used up to 0.25% in the food, to improve the growth of guinea pigs, without abnormalities on their digestive organs and their haematological parameters.