Introduction
Trypanosomiasis is a neglected tropical infectious disease of medical and veterinary importance in sub-Sahara Africa caused by a protozoan parasite of the genus
Trypanosoma. The species
T. brucei brucei is responsible for African Animal Trypanosomiasis (AAT) called Nagana in West Africa, while
T. b. rhodesiense and
T. b. gambiense cause Human African Trypanosomiasis (HAT) or sleeping sickness [
1,
2]. It is a parasitic disease that occurs in sub-Saharan Africa, within the distributional limits of its vector, the tsetse fly [
3]. Control of trypanosomiasis is principally achieved by chemoprophylactic or chemotherapeutic agents [
4]. Most of these drugs for the control of both animals and humans are chemically related [
5]. It has been estimated that as many as 35 million doses of trypanocides are used annually in sub-Saharan Africa alone [
6]. This represents a figure suitable to treat only around one-third of the cattle at risk [
7]. The chemotherapy of African trypanosomiasis is limited by problems of scarcity of drugs, drug resistance, high price, adverse reaction and toxicity [
8,
9]. Therefore, it is important to search for cheaper, more effective, easily available, and less toxic chemotherapeutic agents for the treatment of the disease.
Majority of people from Africa, including Nigeria depend on medicinal plants for the treatment of various diseases, and most of these plants have proven to be effective but lack scientific elucidation. Indeed, there have been a lot efforts to discover new anti-trypanosomals typically of plant origin based on the available information of their use in folklore medicine [
10]. Several studies have demonstrated the trypanocidal activity of various plants such as
Tapinanthus globiferus, Peristrophe bicalyculata, Securidaca longipedunculata, Moringa oleifera,
Garcinia hombroniana,
Camellia sinensis,
Salvia offiicinalis, Azadirachta indica, Morinda lucida, and
Tridax procumbens [
4,
11‐
17]. However, the toxicity of herbal remedies, their adverse effects on integrity of internal organs such as the liver and kidney are mostly unknown. There has been claim that natural plant products are safe, these could be accepted only after the plant product have passed through toxicity testing using modern scientific methods.
Brillantaisia owariensis P. Beauv belongs to the family Acanthaceae, and it is a tropical African species widespread in the forest regions of western (Togo, Nigeria) and central Africa, westward to Guinea and Sierra Leone, eastward to South Sudan, and southward to northern Angola.
B. owariensis commonly known as bush cow food is a perennial shrubby plant 20 cm- 2 m tall [
18]. Leaves of
B. owariensis are used for the treatment of anemia by traditional healers in Congo [
19]. The species is used to aid conception and is decocted to ease childbirth and menstrual pains. It is also used against stomach ache, chest conditions, infantile spleen affections, malnutrition, yaws, and rheumatism [
18]. To the best of our knowledge, no available data on toxicity and trypanocidal activity of
Brillantaisia owariensis in-vivo. Therefore, this study was designed to assess the oral acute toxicity, and anti-trypanosomal activity of
Brillantaisia owariensis in BALB/c mice.
Materials and methods
Plant collection and authentication and processing
The whole plant was collected from the wild in Ondo State, South western, Nigeria. After which it was identified in the Herbarium Unit, Department of Botany, Ahmadu Bello University Zaria. The whole plant was rinsed in running tap water severally, air-dried in the Laboratory and thereafter pulverised using mortar and pestle, and ground to a fine powder with an electric blender to enhance the penetration of the extracting solvents into the cells, thus facilitating the release of active principles [
20].
Plant extraction and concentration
Thirty grams (30 g) of the powdered whole plant was measured using a weighing balance and poured into a two-liter container, 1.5 l of distilled water was gently added to it, tightly screw-capped, and agitated thoroughly. After two hours, the container was shaken thoroughly again and repeated thereafter at four hours interval. After 24 h, the container was shaken thoroughly and the content was filtered gently using a sieve into a clean container. The filtrate was poured into an evaporating dish, placed on a water bath to obtain a solid and more concentrated form of the extract.
About thirty grams (30 g) of the powdered whole plant was measured into a sac-like mesh cloth. The sac was then placed into a flask containing 300 mL of methanol and mounted on a Soxhlet machine. A tube-like glass was fixed on the open end of the flask on the machine and covered, switched on, and set at 100 °C. As the solvent in the flask boils, it evaporates and soaks the content of the flask which gradually releases the chemical content leaving residues in the sac. This process continues until the content of the sac became white while the solvent appeared green. Thereafter, the machine was switched off, allowed to cool, the set up dismantled and the sac was removed. The extract was then collected in a bottle, transferred to an evaporating dish, placed in a water bath set at 100 °C to allow the methanol to evaporate and a concentrated extract was obtained.
Acute toxicity studies
Acute oral toxicity of the whole plant extracts of
B. owariensis was carried out using Lorke’s [
21] method, which involves two phases:
Phase 1
Nine mice were divided into three groups of three each. Each group of mice was administered different doses (10, 100, and 1000 mg/Kg) of the test substance. The mice were placed under observation for 24 h to monitor their behavior as well as mortality [
21].
Phase 2
Three mice were distributed into three groups of one mouse each. Each mouse was administered higher doses of 1600, 2500, and 5000 mg/kg, respectively, of the test substance and then observed for 24 h for behavior as well as mortality [
21]. The LD
50 was then computed as the geometric mean of the highest dose that did not cause mortality in mice and the lowest dose that caused mortality in the mice by the formula:
$$ {\mathrm{LD}}_{50}=\sqrt{\left({D}_0\times {D}_{100}\right)} $$
D0 = Highest dose that gave no mortality,
D100 = Lowest dose that produced mortality.
Experimental design, trypanosome inoculation and treatment
Forty adult BALB/c mice (Mus musculus) of both sexes weighing 19-22 g bred within the animal house, Faculty of Pharmaceutical Sciences, Ahmadu Bello University, Zaria were used. They were kept to acclimatize under standard laboratory conditions in the Department of Zoology, Zoology Research Laboratory, for 2 weeks before commencement of the experiment. They were housed in clean cages with wood shavings as bedding, which was changed twice a week. They were fed with animal feed (grower) and given access to clean water ad libitum. They were grouped into eight and each group has five mice. Mice from groups 1, 2, 3, 4, and 5 were infected intraperitoneally with 0.1 ml of the inoculum containing about 1× 106 trypanosomes/mL. Trypanosoma brucei brucei was obtained from stabilates maintained at the Department of Veterinary Parasitology and Entomology, A.B.U. Zaria, Nigeria. Treatment began on the day the parasites were first detected in the bloodstream which was three (3) days post-inoculation.
Group 1: Negative control; infected and treated with 1 ml normal saline.
Group 2: Positive control; infected and treated with Diminazene aceturate 3.5 mg/kg.
Group 3: Infected treated with aqueous extract (A-50 mg/kg/day).
Group 4: Infected treated with methanol extract (M-50 mg/kg/day).
Group 5: Infected treated with aqueous extract (A-75 mg/kg/day).
Group 6: Infected treated with methanol extract (M-75 mg/kg/day).
Group 7: Infected treated with aqueous extract (A-100 mg/kg/day).
Group 8: Infected treated with methanol extract (M-100 mg/kg/day).
Pharmacological evaluation of extracts
Determination of mean daily rectal temperature
To obtain rectal temperature, each mouse was hand-restrained and placed on a horizontal surface, e.g., a cage lid. The tail was then lifted, and a probe (covered with Vaseline) was gently inserted into the rectum to a fixed depth (typically, up to 2 cm) [
22].
Daily weight changes
The weights of the mice were monitored daily using an automated electronic scale. To weigh a mouse, a round plastic container was placed on the scale and adjusted to zero followings which the animal was dropped inside the container and subsequently weighed [
23].
Determination of Parasitaemia in experimental mice
Parasitaemia level was monitored daily in blood obtained from the tail of infected mice. The number of parasites per ml of blood was determined microscopically at × 400 magnification using the “rapid matching” method by Herbert and Lumsden [
24], and the number of trypanosomes per field was converted to antilog to provide the absolute number of trypanosomes per ml of blood [
25].
Determination of packed cell volume
A heparinized capillary tube was filled with blood obtained from the ocular vein to up to about three quarter; one side of the capillary tube was filled with modeling clay (plasticine). The filled tube was placed in the microhaematocrit centrifuge and spin at 12000 g for 5 min. The spinner tube was then placed into a specially designed scale, read and expressed as a percentage [
26].
Histopathologic examination of liver and kidney tissues
After two weeks of single acute oral administration of the aqueous and methanol whole plant extracts of B. owariensis mice were sacrificed for histopathologic assessment of liver and kidney tissues. Tissue specimens collected from the kidney and liver were preserved in 10% buffered neutral formalin (BNF). After 48 h of fixation, the tissue samples were processed (washed in 50% and 70% alcohol), embedded in paraffin wax and sectioned at 5 μm using a microtome. The sections were mounted on clean grease-free glass slides and stained with Haematoxylin and Eosin (H&E) stains. Histopathologic lesions were examined microscopically at X40 objective and photomicrography was done with the aid of a digital camera (Canon 16 Mpx). Grading of liver and kidney histological alterations were classified as mild, moderate and severe damage based on the level and severity of necrosis and lesions present.
Data analysis
The data obtained from the study were summarized; the mean rectal temperatures, mean weights changes, parasitaemia scores, mean packed cell volume, of all the animals in the groups were represented and compared on multiple line graphs using Microsoft Excel Chart Wizard [
27].
Discussion
One of the best ways to ascertain the safety of plant extracts is toxicological assessment accompanied by appropriate histological studies. The acute oral toxicity studies (LD
50) for methanol and aqueous plant extracts in this study were calculated at 3535 mg/kg/body weight. A scale proposed by Lorke [
21] roughly classifies substances that posess LD
50 < 1.0 mg/Kg as very toxic; those with LD
50 up to 10 mg/kg as toxic, LD
50 up to 100 mg/kg as less toxic and slightly toxic when LD
50 up to 1000 mg/kg. Substances with LD
50 values more than 5000 mg/Kg are non-toxic. This therefore suggest that the extract of
Brillantaisia owariensis is non-toxic. Similarly, the acute toxicity study of the stem-bark methanol extract of
Khaya senegalensis had an LD
50 of 3807 mg/Kg / body weigh in rats and declared as non-toxic [
28]. The Liver and kidney are important organs that play a vital role in bio-transformation and elimination of many toxic together with their metabolites from the body, and are the primary target organs of toxic injury because of its role [
29,
30]. In this study it was observed that oral administration of the extract caused some mild to moderate histological effects mostly in the liver and kidney indicating that it mildly hepatotoxic and nephrotoxic. Lymphocytic cell infiltration observed may be due to presence of the flavonoid glycoside present in
B. owariensis, the presence of flavonoid glycosides has been suggested to cause focal inflammation around the portal triad on the liver with no effect on the kidney [
31]. Presence of saponin in plant extract has been reported to cause histopathological alterations in rats [
32].
There was no significant increase in the mean daily rectal temperature of all extract-treated animals. A characteristic sign and symptom of trypanosomosis in susceptible animals is the increase in body temperature [
33,
34]. Despite undulating parasitaemia observed in mice treated with methanol extract and progressive parasitaemia observed when treated with aqueous extract, there was no conforming undulating pyrexia. This could be due to the presence of the compound Acetamide, N-(4-hydroxyphenyl)-N-methyl (Paracetamol) which is an antipyretic, which may have be responsible for insignificant increase in mean rectal temperature of the test organisms. Anosa [
35] observed that increase in parasitaemia and pyrexia did not simultaneously occur. The result from this study is in discordance with the reports of Mbaya et al. [
36,
37] that a direct relationship exists between undulating pyrexia and fluctuating parasitaemia in trypanosomosis.
Although weight loss has been observed as one of the primary clinical signs of African trypanosomosis [
38], the lack of significant loss of weight in mice employed for this study may be related to the high sources of nutrients in
B. owariensis [
39]. Furthermore, an important factor for the attained weight gain in mice in this study could be associated with increased supply of oxygen and nutrients due to the improved PCV level [
40]. In contrast to this study, Ngure et al. [
41] reported that all trypanosome-infected mice treated with
Azadiracta indica bark extract showed a significant decline in body weight during the experimental period except those treated with Melasorpol (Mel-B).
The in-vivo antitrypanosomal activity of the extracts revealed that there was no cessation or complete elimination of parasites from the bloodstream of infected mice when administered aqueous and methanol extract of
B. owariensis, but only reduced the level of parasitaemia. Several researchers made similar observations on reduction in parasitaemia when different plant extracts were administered to laboratory animals [
42‐
44]. It is very likely that the oral route of administration of the plant extract in this study could course the failure of the extract to clear the parasite from the blood because the active compounds in the extracts may have failed to reach the site of action or rapid metabolization [
45,
46]. It is also possible that the secondary metabolites in the extracts underwent biotransformation within the gastrointestinal tract and liver, thereby preventing completely elimination of the parasites. It is also likely that the non-efficacy of the plant could be the trypanosome species employed in this study or the animal model used [
47]. It has been reported that BALB/c mice show lesser survival and less parasite control when compared to C57Bl/6 mice [
48], and that BALB/c mice exhibit prolonged survival in
T .B. gambiense infection, in contrast to
T. b. rhodesiense and
T. b. brucei infections [
49].
The reduction of PCV values by more than 20% of the baseline values in all mice day 3 post-infection is an indication of haemolytic anaemia, and is considered the most characteristic symptom whose severity is linked to the level of parasitaemia [
50]. Interestingly, following treatment with aqueous and methanol extracts of
B. owariensis, there was significant restoration of the haemolytic condition and increase in the survival time in all the treated groups over the negative (non-treated) control group, and this could be attributed to the presence of secondary metabolites such as alkaloids with have been reported to reverse haemolysis [
51,
52]. Additionally, it has been reported that
B. owariensis is rich in amino acids which are building blocks of protein with a high quantity of Glycine which is needed during periods of rapid growth and for the biosynthesis of porphyrins of haemoglobin [
39]. Similarly,
Brillantasia nitens is reported to have haematinic activity [
53]. Furthermore, the haematic activity of B. owariensis observed in this study, thus lend credence to it use in folklore medicine in the management of anaemia South Western Nigeria, and other African countries especially in Democratic republic of Congo [
19].
Generally, the infected mice that were treated with methanol extract had the highest mean survival time of 8 days compared to the mice treated with aqueous extracts and the non-treated negative control. This could be attributed to high presence of alkaloids, saponins, cardiac glycoside, and anthraquinone in the methanolic extract with higher antitrypanosomal activities [
54,
55].
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