Sudan Journal of Medical Sciences
Volume 13, Issue no. 4, DOI 10.18502/sjms.v13i4.3599
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Research Article

Evaluation of Antimicrobial Activity of
a Sudanese Herbal Plant (Piliostigma
reticulatum)
Shamsoun Khamis Kafi1, Fatima Mekki Abdalla2, and
Mohamedelfateh Salaheldin Eljack3

1Department of microbiology, Faculty of medical laboratory science, the National Ribat
University
2Department of microbiology, National Ribat Teaching Hospital
3Medical Parasitology Department, Faculty of Medical Laboratory Science, National Ribat
University

Abstract
Background: Piliostigma reticulatum is a plant that is found in a wide area of Sahelo-
Sudanian region of Africa. It is widely used in Africa as a traditional medicine for
the treatment of a wide range of diseases including epilepsy, anxiety, and agitation.
The leaf extract was found to have antimicrobial activity. In Sudan (Nuba mountains
in particular), it is widely used to dress new wounds and as well puerperal sepsis.
Moreover it’s fruit is eaten and used to prepare juice. Reported studies concerning
antimicrobial activity of the plant in Sudan could not be found. This study therefore
aimed to evaluate the antimicrobial action of Ethanolic and Aqueous extract of leaves
and barks of the plant.
Methods: Barks and leaves of P. reticulatum were obtained from North Kordofan
State. They were then air dried in the shade and milled into powder using Mortar.
Methanolic and water extract of each part of the plant was prepared using a Soxhlet
apparatus. The following concentrations of extracts of each part (bark and leaves)
of the plant were prepared using Distilled water (50 mg/ml, 25 mg/ml, 12.5 mg/ml,
6.25 mg/ml, 3.125 mg/ml, and 1.56 mg/ml). Antimicrobial action of the different
concentrations of the extracts of the two parts of the plant on selected bacterial
and fungal species was performed using well diffusion technique. Antimicrobial
susceptibility of the tested organisms to serial concentrations (40 µg, 20 µg, 10 µg,
and 5 µg) of three antibacterial (Gentamicin, Ampicillin, and Tetracycline) and 2 anti-
fungal (Nystatin and clotrimazole) was evaluated using well diffusion method.
Results: The methanolic extract of P. reticulatum leaves showed high antibacterial
activity against Bacillus subtilis (inhibition zone 22 mm), S. aureus (25 mm), P.
aeruginosa (23 mm), and E.coli (20 mm). The extract also showed antifungal activity
against A. niger (23 mm) and C. albicans (23 mm). The aqueous extract revealed
low activity against P. aeruginosa (10 mm) and no action on the rest of the
microorganisms.

How to cite this article: Shamsoun Khamis Kafi, Fatima Mekki Abdalla, and Mohamedelfateh Salaheldin Eljack (2018) “Evaluation of Antimicrobial
Activity of a Sudanese Herbal Plant (Piliostigma reticulatum),” Sudan Journal of Medical Sciences, vol. 13, issue no. 4, pages 264–276.
DOI 10.18502/sjms.v13i4.3599

Page 264

Corresponding Author:

Mohamedelfateh Salaheldin

Eljack;

email:

m.elfatehsalah@gmail.com

Received 15 September 2018

Accepted 9 December 2018

Published 26 December 2018

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S. K. Kafi et al. This article

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Editor-in-Chief:

Prof. Mohammad A. M.

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Sudan Journal of Medical Sciences S. K. Kafi et al

Conclusion: In this study, the methanolic extract of the leaves inhibited the
growth of all the tested bacteria and fungi but with varied activity (inhibition
zones between 8 mm and 20 mm). The highest activity was against B.
subtilis (inhibition zone 20 mm), followed by A. niger and C. albicans (19 mm
each), then P. aeruginosa (18 mm). Methanolic extract of the leaves revealed
moderate activity against E. coli(13 mm) and low activity against S. aureus (8
mm).

Keywords:

1. Introduction

Piliostigma reticulatum is a plant that occurs in the Sahelo-Sudanian region of Africa
from Senegal, Mauritania to Sudan and has been introduced to Mozambique (Fibres,
1846). The plant is a dioeciously shrub or small tree up to 10–15 meters tall, bole short,
rarely straight, up to 30 cm in diameter. The outer bark is deeply fissured, cracked grey
to brown, and the inner bark pink to red crown rounded and dense. The branches are
grey, waxy, and glabrous. The leaves alternate conspicuously bilobed, petiole 1–3.5 cm
long, swollen at both ends, blade 5–12 cm X 4–18 cm, chordate or rounded at base,
lobes rounded more or less cuneate (Figure 1).

The flowers are unisexual, 2.5 cm in diameter, calyx 5 toothed, 15–20 cm long, petals
5 obovate, white with pink stripes, male flowers with 10 stamens, anthers brown
(Figure 2). Fruit an oblong pod 15–30 cm X 2.5–5 cm, straight undulate woody, hard,
glabrous, or sparsely pubescent, brown flat, pruinose, sometimes twisted and cracked,
indehiscent and persisting, many seeded [1].

The plant is used widely in Africa as a traditional medicine for the treatment of
many diseases, such as malaria, tuberculosis, and diarrhea [2]. Piliostigma reticulatum
is used in traditional medicine in Cameron to treat epilepsy, anxiety, and agitation. In
fact the results of a study done in Cameron suggested that it possesses anxiolytic and
antipyretic properties in mice and could really be helpful in the treatment of anxiety
[3].

The leaf extract from the plant was found to exhibit anti-microbial activity against
some bacteria and fungi such as Staphylococcus aureus (NCTC 6571, Escherichia coli
(NCTC 10418), Bacillus subtilis (NCTC 8236), Proteus vulgaris (NCTC 4175), Aspergillus niger
(ATCC 10578), and Candida albicans (NCTC 10231) [4]. Vibriocidal action of P. reticulatum

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among other medicinal plants was studied and proved to be effective in killing Vibrio
spp. [5]. In Nuba mountains in Sudan, the plant is widely used. The young leaves with
their acidic taste are eaten. The fruits after maturation and drying is also eaten for its
sweet taste and nowadays used for preparation of juice. The fresh bark of the plant is
used for fresh wound dressing as it coagulates blood and is believed to enhance healing
of the wound by keeping it clean. In the old days before the introduction of primary
healthcare and midwifery facilities, the inner soft bark of P. reticulatum was widely
used after delivery to cover the episiotomy wound (based on personal observation,
one of the authors being part of the Nuba community).

This study was conducted to evaluate the antimicrobial activity of P. reticulatum on
selected bacterial and fungal spp.

Figure 1: Fruits and leaves of P. reticulatum.

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Figure 2: Leaves and flowers of P. reticulatum.

2. Materials and Methods

2.1. Preparation of the different plant’s parts

Barks and leaves of P. reticulatum were obtained from North Kordofan State. The bark
and leaves of the plant were dried in the shade and then milled using Mortar and Pestle
to prepare a powder.

2.2. Preparation of the extracts

Eighty five grams of the air-dried and coarsely powdered material of each plant part
was exhaustively extracted for 20 hours with methanol (40–60ºC) in a Soxhlet appa-
ratus. The methanolic extract was filtered and evaporated under reduced pressure
again using Rota-vapor. Each residue was weighed and the yielded percentage was
determined. The methanol residue was redissolved or suspended in methanol. The
final volume was adjusted to give the specific concentration (100 mg/ml) and kept in
a refrigerator until used.

Aqueous extract of each dried, ground plant part (10 g) was prepared by infusion
using boiled distilled water. It was allowed to soak in a beaker on water bath with
occasional shaking for four hours. The residue was then dried and weighed and the
yield percent was obtained. The final volume of the residue was adjusted to 10 ml
sterile distilled water, and used immediately.

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2.3. Preparation of the standard test organisms

The standard organisms were obtained from the department of Microbiology and Par-
asitology, Medicinal and Aromatic Plant Research Institute, Khartoum and inoculated
into broth that was then incubated at 37ºC aerobically for 24 hours.

2.4. Preparation of the standard bacterial suspensions

One ml aliquots of a 24-hours broth culture of the test organisms were aseptically
distributed onto nutrient agar slopes and incubated at 37ºC for 24 hours. The bacterial
growth was harvested and washed off with 100 ml sterile normal saline, to produce a
suspension containing about 108–109 colony forming units per ml. The suspension was
stored in the refrigerator at 4ºC till used. The average number of viable organisms
per ml of the stock suspension was determined by the means of the surface viable
counting technique. Serial dilutions of the stock suspensions were made in sterile
normal saline solution and 0.02 ml volumes of the appropriate dilution were transferred
by micropipette to the surface of dried nutrient agar plates. The plates were allowed to
stand for 2 hours at room temperature for the drops to dry, and then incubated at 37ºC
for 24 hours. After incubation, the number of developed colonies in each drop was
counted. The average number of the colonies per drop (0.02ml) was multiplied by 50
and by the dilution factor to give the viable count of stock suspensions, expressed as
the number of colony forming unit per ml of suspension. Each time fresh stock suspen-
sion was prepared, all the aforementioned experimental conditions were maintained
constant so that suspensions with very close viable count would be obtained [6, 7].

2.5. Preparation of standard fungal organisms

The standard fungi were obtained from the department of Microbiology and Parasitol-
ogy, Medicinal and Aromatic Plant Research Institute, Khartoum and were maintained
on Sabouraud’s dextrose agar, incubated at 25ºC for 4 days. The fungal growth were
harvested and washed with sterile normal saline and finally suspended in 100 ml of
sterile normal saline and the suspension was stored in refrigerator till used.

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2.6. Testing of antibacterial susceptibility

The paper disc diffusion method was used to screen the antibacterial activity of plant
extracts and performed by using Mueller Hinton agar (MHA). The experiment was
carried out according to the National Committee for Clinical Laboratory Standards
Guidelines [8]. Bacterial suspension was diluted with sterile physiological solution to
108cfu/ml (turbidity = McFarland standard 0.5). One hundred microliters of bacterial
suspension were swabbed uniformly on surface of MHA and the inoculum was allowed
to dry for 5 minutes. Sterilized filter paper discs (Whatman No.1, 6 mm in diameter)
were placed on the surface of the MHA and soaked with 20 µl of a solution of each
plant extracts. The inoculated plates were incubated at 37 ºC for 24 h in the inverted
position. The diameters (mm) of the inhibition zones were measured.

2.7. Testing for antifungal activity

The same method as for antibacterial activity was used. Sabouraud dextrose agar was
used instead of nutrient agar. The inoculated medium was incubated at 25ºC for three
days for the A. niger and two days for C. albicans.

2.8. Determination of minimum inhibitory concentration (MIC) by
agar plate dilution method

The principle of the agar plate dilution is the inhibition of growth on the surface of the
agar by the plant extracts incorporated into the medium. Plates were prepared in the
series of increasing concentrations of the plant extract. The bottom of each plate was
marked off into six segments. The organisms tested were inoculated into broth media
over night to obtain 109 CFU/ml. A loop-full of diluted culture was spot with a standard
loop that delivers 0.001 ml on the surface of each segment and then incubated at 37ºC
for 18 hour (9). Piliostigma reticulatum extract was prepared in the series of decreasing
concentrations in the following order 50, 25, 12.5, 12.5, 6.25, 3.125, and 1.56 mg/ml.
The end point (MIC) is the least concentration of antimicrobial agent that completely
inhibits the growth. MIC for each microbe was reported in term of mg/ml.

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2.9. Antibacterial activity of reference drugs

In the present work, three antibiotics (Ampicillin, Gentamicin, and tetracycline) were
used as reference drugs. Antibacterial drugs were tested at different concentrations
obtained by dissolving 0.1 g of each powdered drug in 100 ml sterile distilled water to
give a concentration of 1000 μg/ml followed by serial dilutions to give concentrations
of 40, 20, 10, and 5 μg/ml. These drugs were tested against reference bacteria, that is,
Bacillus subtilis, Staphylococcus aureus, Escherichia coli, and Pseudomonas aeruginosa.

2.10. Antifungal activity of reference drugs

In the present work, two antifungal agents (Nystatin and Clotrimazole) were used as
reference drugs. Antifungal drugs were tested at different concentrations obtained
by dissolving 0.1 g of each powdered drug in 100 ml sterile distilled water to give a
concentration of 1000 μg/ml followed by serial dilutions to give concentrations of 40,
20, 10, and 5 μg/ml. These drugs were tested against reference fungi. A. niger and C.
albicans.

3. Results

3.1. Screening for antimicrobial activity of methanolic and aqueous
extracts of Bark and Leaves of P. reticulatum (kharoub)

The methanolic leaves extract of P. reticulatum showed high antimicrobial activity
against Gram positive and negative bacteria with inhibition zone of 20 mm against
B. subtilis, 18 mm against P. aeruginosa. It also showed high activity against C. albicans
and A. niger (inhibition zone 19 mm against each one). The methanolic leaves extract
revealed moderate activity against E. coli and low activity against S. aureus (inhibition
zones of 13 mm and 8 mm, respectively) (plates 2–3).

The aqueous extract showed moderate activity against A. niger (inhibition zone 12
mm) and no activity against the rest of the tested organisms (Table 1).

The methanol Bark extract of Piliostigma reticulatun showed pronounced activity
against S. aureus (inhibition zone 25 mm), and high activity against P. aeruginosa,
B. subtilis, and E.coli (inhibition zones of 23 mm, 22 mm, 20 mm, respectively). The
methanolic bark extract also showed pronounced activity against A. niger and high

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activity against C. albican (inhibition zones of 24 mm and 23 mm, respectively) (Table
1 and plate-1).

The aqueous extract showed low activity (10 mm) against P. aeruginosa and inactive
against the rest of the organisms (Table 1).

3.2. Comparison between the antimicrobial activity of the most
active Bark and Leaves methanolic extracts with standard
reference drugs

E. coli was found to be resistant to all the three drugs (ampicillin, gentamicin, and
tetracycline) at all concentrations while sensitive to the leaves and bark ethanolic
extract of the plant. It was also found to be resistant to tetracycline and ampicillin at
all concentrations but sensitive to leaves and bark ethanolic extracts of P. reticulatum
(Table 2). Bacillus subtilis revealed sensitivity to all the three antibiotics used and the
ethanolic leaves and bark extracts of the plant but resistant to the aqueous extracts
(Tables 1 and 2).

Candida albicans was found to be sensitive to both antifungal used in all concen-
trations and as well methanolic leaves and bark extract of the plant but resistant
to aqueous extracts. Aspergillus niger showed sensitivity to all extracts except the
aqueous bark extract. It also revealed sensitivity to nystatin and clotrimazole except
in low concentration (Tables 1 and 3).

The leaves methanolic extract of P. reticulatum activity against B. subtilis was equiv-
alent to the activity 10 μg/ml gentamicin.

The Bark methanol extract of P. reticulatum activity against B. subtilis was similar
to the activity of 20 μg/ml gentamicin. The methanol bark extract activity against S.
aureus was similar to that of 40 μg/ml tetracycline. The diameter of the inhibition of
methanolic bark extract against C. albicans was similar to that caused by 12.5 μg/ml
nystatin (Tables 2 and 3).

3.3. Determination of the minimum inhibitory concentrations

The minimum inhibitory concentrations of the bark methanolic extracts of P. reticula-
tum was found to be 3.125 mg/ml for S. aureus and P. aeruginosa and 1.56 mg/ml for B.
subtilis, E. coli, A. niger, and C. albicans. Regarding the methanolic leaves extract, MIC
for S. aureus was 50 mg/ml, 6.25 mg/mg for C. albicans, and 3.125 mg/ml for B. subtilis,
P. aeruginosa, and A. niger (Table 4).

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T 1: The diameter of the inhibition zone in mm of the methanolic and water extracts of P. Reticulatum
against standard tested organisms.

Type of extract The size of inhibition zone (mm) against the different standard organisms

E. coli P.
aeruginosa

B. subtilis S. aureus A. niger C. albicans

Leaves methanolic
extract

13 18 20 8 19 19

Leaves water extract Resistant Resistant Resistant Resistant 12 Resistant

Bark methanolic
extract

20 23 22 25 24 23

Bark water extract Resistant 10 Resistant Resistant Resistant Resistant

Interpretation of results: Mean diameter of inhibition zone in mm (MDIZ): (> 8 mm: Sensitive, 12–15
mm: Intermediate : < 8 mm: Resistant.

T 2: Antibacterial activity of reference drugs against standard bacteria.

Type of the
antibiotic

Concentration
of the drug in
the antibiotic

disc

The diameter of the inhibition zone in mm

E. coli P. aerugi-
nosa

B. subtilis S. aureus

Ampicillin 40 Resistant Resistant 15 25

20 Resistant Resistant 14 20

10 Resistant Resistant 13 18

5 Resistant Resistant 12 15

Gentamicin 40 Resistant 29 9 35

20 Resistant 21 22 33

10 Resistant 20 20 30

5 Resistant 19 17 28

Tetracycline 40 Resistant Resistant 25 25

20 Resistant Resistant 23 Resistant

10 Resistant Resistant 19 Resistant

5 Resistant Resistant 18 Resistant

4. Discussion

The methanol and aqueous extracts of the Leaves and Bark of P. reticulatum were
screened for their anti-microbial activity against six microorganisms, two standard
Gram-positive bacteria (S. aureus and B. subtilis), two Gram-negative bacteria (E. coli
and P. aeruginosa) and two standard fungi (A. niger and C. albicans) using disc diffusion
method.

In this study, the methanolic extract of P. reticulatum bark and leaves extracts were
found to have broad spectrum antimicrobial activity against the gram-positive and
negative bacterial species tested as well as the two fungal species. The bark ethanolic

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T 3: Antifungal activity of reference drugs against standard fungi.

The antifungal Drugs Conc. Used μg\ml The diameter of the inhibition zone in mm

A. niger C. albicans

Nystatin 500 27 32

50 17 28

25 14 26

12.5 Resistant 23

Clotrimazole 40 30 42

20 22 40

10 20 31

5 Resistant 28

T 4: Minimum inhibitory concentrations (MIC) of P. reticulatum methanolic extracts against the
standard microorganisms.

Part Used Solvent Conc.
Used
mg/ml

The diameter of the inhibition zone in mm

B. subtilis S. aureus E. coli P. aerugi-
nosa

A. niger C. albicans

Bark Methanol 50 22 20 16 13 14 16

25 14 19 15 12 14 14

12.5 14 11 14 11 14 13

6.25 14 11 13 11 13 13

3.125 11 0 10 0 10 11

1.56 0 0 0 0 0 0

leaves Methanol 50 18 8 13 17 17 18

25 17 0 12 15 13 16

12.5 14 0 11 15 13 14

6.25 13 0 11 14 13 12

3.125 11 0 0 11 10 0

1.56 0 0 0 0 0 0

extract showed higher activity against all tested bacteria and fungi compared to leave
extract. Based on microbial species, the bark ethanolic extract showed higher effect
on S. aureus inhibition zone of 25 mm followed by A. niger (24 mm), then P. aeruginosa
and C. albicans (23 mm each).

Contrary to our results, Daniel and Malomo reported that P. reticulatum was not
active against P. aruginosa but showed high activity (with inhibition zone 22 mm
against B. subtilis and 20 mm against E. coli [11]. The antimicrobial effect of the
methanolic bark and leave extract were even better than the drugs used (ampicillin,
gentamicin, and tetracycline).

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Plate 1: Invitro antimicrobial activity of P. reticulatum Bark extract (m) methanol extract (w) water extract
against Staphylococcus aureus.

Plate 2: Invitro antimicrobial activity of P. reticulatum Bark extract (m) methanol extract (w) water extract
against Pseudomonas aeruginosa.

The aqueous extract of the plant showed low antibacterial activity against P. aerugi-
nosa (inhibition zone10 mm), while inactive against rest bacterial and fungal organisms
tested. Similar results were reported by a study done in 2009 in which the hot and cold
aqueous extracts of P. reticulatum exhibited low antimicrobial activity against E. coli,
Shigella dysenteriae, Salmonella typhimrium, Staphylococcus aureus, and Pseudomonas
aruginosa with zones of inhibition ranging between 8–10 mm and 4–7 mm for bacterial
and fungal species, respectively [12].

However, one of the previous studies found no difference between the methanolic
and aqueous extract of the plant [10]. The active ingredient is possibly alcohol soluble
and water insoluble resulting in the variation in the antimicrobial effect of the two

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Plate 3: Invitro antimicrobial activity of P. reticulatum Leaves extract (m) methanol extract (w) water
extract against A. niger.

types of extract, moreover the concentration of the active ingredient is probably higher
in the bark than the leaves. This can explain why bark extract was more effective than
the leave extract.

In conclusion, the methanolic extract of bark showed more anti-microbial activity
than leaves extract.

Acknowledgement

The authors are indebted to and appreciate the role of staff members of the depart-
ments of Microbiology and Parasitology of the Medicinal and Aromatic Plant Research
Institute for their help in preparation of the extracts.

References

[1] Fibres. (1846). Description, original, geographic distribution, uses and production
and international trade of P. reticulatum. Prota (Plant Resourcer of Tropical Africa)
vol. 29, p. 299.

[2] Dosso, K., N’guessan, B. B., Bidie, A. P., et al. (2011). Antidiarrheal activity of an
ethanol extract of the stem bark of Piliostigma reticulatum (Caesalpiniaceae) in rats.
African Journal of Traditional, Complementary and Alternative Medicines, vol. 9, no. 2,
pp. 242–249.

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[3] Sidiki, N., Djafsia, G., Njapdounke, K. J. S., et al. (January–March 2013). Anxiolytic
and antipyretic activities in the decoction of leaves of Piliostigma reticulatum. Asian
Journal of Pharmaceutical and Health Sciences (AJPHS), vol. 3, no. 1.

[4] Olalekan, J., Babajide, et al. (2008). Flavonols and an oxychromonol from Piliostigma
reticulatum. Phytochemistry, vol. 69, no. 11, pp. 2245–2250.

[5] Akinsinde, K. A. and Olukoya, D. K. (1995). Vibriocidal activities of some local herbs.
Journal of Diarrhoeal Diseases Research, vol. 13, no. 2, pp. 127–129.

[6] Miles, M. and Misra, S. S. (1938). The estimation of the bacterial power of the blood.
Journal of Hygiene, vol. 38, pp. 7–32.

[7] Collee, J. G., Barrie, P. M., Andrew, G. F., et al. (1996). Practical medical microbiology.
Specimen collection, culture container and media (fourteenth edition), section A,
vol. 5, pp. 95–109. Singapore: Longman Singapore Publisher Ltd.

[8] NCCLS. (1999). Methods for determining bactericidal activity of antibacterial agents:
Approved guideline. NCCLS document M26-A. Villanova, PA: NCCLS.

[9] Abd-Ulgadir, K. S., Suliman, S. I., Zakria, I. A., et al. (2015). Antimicrobial potential of
methanolic extracts of Hibiscus sabdariffa and Ricinus communis. Advancement in
Medicinal Plant Research, vol. 3, no. 1, pp. 18–22.

[10] Aderogba, M. A., Okoh, E. K., Okeke, I. N., et al. (2006). Antimicrobial and anti-
inflammatory effects of Piliostigma reticulatum leaf extract. International Journal of
Pharmacology, vol. 2, no. 1, pp. 70–74.

[11] Daniels, A. O. and Malomo, O. (2014). Preliminary studies on the antimicrobial effect
and phytochemicals studies of some Nigerian medicinal plant on some human
pathogens. International Journal of Current Microbiology and Applied Science, vol. 3,
no. 3, pp. 910–923.

[12] Awe, S. and Omojasola, P. F. (2009). A comparative study of the antibacterial activity
of Piliostigma reticulatum bark extract with some antibiotics. Ethnobotanical Leaflets,
vol. 2009, no. 9, article 11.

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	Introduction 
	Materials and Methods
	Preparation of the different plant's parts
	Preparation of the extracts
	Preparation of the standard test organisms 
	Preparation of the standard bacterial suspensions
	Preparation of standard fungal organisms
	Testing of antibacterial susceptibility
	Testing for antifungal activity
	Determination of minimum inhibitory concentration (MIC) by agar plate dilution method 
	Antibacterial activity of reference drugs
	Antifungal activity of reference drugs 

	Results
	Screening for antimicrobial activity of methanolic and aqueous extracts of Bark and Leaves of P. reticulatum (kharoub) 
	Comparison between the antimicrobial activity of the most active Bark and Leaves methanolic extracts with standard reference drugs
	Determination of the minimum inhibitory concentrations

	Discussion
	Acknowledgement
	References