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Journal of Biosciences and Medicines, 2025, 13(6), 83-105
https://www.scirp.org/journal/jbm
ISSN Online: 2327-509X
ISSN Print: 2327-5081
Prevalence of Vaginitis at the University
Hospital Center of Yaounde (CHUY) and Effect
of Plant Extracts Combinations and
Conventional Antifungals on the Growth of
Multidrug-Resistant Candida albicans
Steve Henri Voundi1,2, Victor Moussango Davy1,3* , Fadil Moctar Achetkouognigni2,
Landry Kengne Gounmadje2, Marie Ampères Boat Bedine4 , Franck Alain Tchinda Fonkou5,
Hortense Gonsu Kamga6, Modeste Lambert Sameza6, Maximilienne Ascencion Nyegue2
Biotechnologies Laboratory, University Institute of Technology, University of Douala, Douala, Cameroon
Department of Microbiology, Faculty of Sciences, University of Yaounde I, Yaounde, Cameroon
3
Laboratory of Biochemistry, Faculty of Science, University of Douala, Douala, Cameroon
4
Phytopathology and Agricultural Zoology Research Unit, Faculty of Agronomy and Agronomic Sciences, University of Dschang,
Dschang, Cameroon
5
Appalachian College of Pharmacy, Virginia, USA
6
University Hospital Center of Yaounde (CHUY), Yaounde, Cameroon
1
2
How to cite this paper: Voundi, S.H., Davy,
M.V., Achetkouognigni, F.M., Kengne, G.L.,
Bedine, B.M.A., Fonkou, T.F.A., Gonsu, K.H.,
Sameza, M.L. and Nyegue, M. A. (2025) Prevalence of Vaginitis at the University Hospital
Center of Yaounde (CHUY) and Effect of
Plant Extracts Combinations and Conventional Antifungals on the Growth of Multidrug-Resistant Candida albicans. Journal of
Biosciences and Medicines, 13, 83-105.
https://doi.org/10.4236/jbm.2025.136009
Received: May 8, 2025
Accepted: June 9, 2025
Published: June 12, 2025
DOI: 10.4236/jbm.2025.136009
Abstract
Background: The spread of vaginal infections in Cameroon and the resistance
of the causative pathogens to antimicrobials require regular monitoring to establish new therapies. The objective of this study was to determine the prevalence of vaginitis among pregnant women at the University Hospital Center
of Yaoundé (CHUY) and to evaluate the effects of combinations of plant extracts and conventional antifungals on the growth of Candida albicans isolates.
Methods: Cervicovaginal samples collected from women were used to identify
the involved pathogens and determination of infection prevalence. The effects
of aqueous extracts of Alchornea cordifolia, Antrocaryon klaineanum, and
Cylicodiscus gabunensis were then evaluated on the growth of five Candida
albicans isolates, all resistant to at least three antifungals. This involved determining their sensitivity to the plant extracts and identifying inhibition parameters (MIC and MFC). Subsequently, combinations of plant extracts and plant
extracts/conventional antifungals were prepared and tested on the isolates’
growth. The determination of the FICI (Fractional Inhibitory Concentration
Jun. 12, 2025
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Journal of Biosciences and Medicines
�S. H. Voundi et al.
Copyright © 2025 by author(s) and
Scientific Research Publishing Inc.
This work is licensed under the Creative
Commons Attribution International
License (CC BY 4.0).
http://creativecommons.org/licenses/by/4.0/
Open Access
Index) highlighted the effects of the combinations on C. albicans. Results: The
prevalence of genital infections at CHUY was 70% during the study period,
comprising 30% for vulvovaginal candidiasis (VVC) and 40% for bacterial
vaginosis. From the samples collected, nine C. albicans isolates were obtained,
five of which were multi-resistant to at least three antifungals. A high resistance
rate was recorded with azoles, notably Fluconazole at 88.88%, compared to
77.77% for Miconazole and Econazole. The plant extracts showed inhibitory
properties on the growth of C. albicans, with inhibition diameters ranging
from 6 to 15 mm. Both the plant extracts and the conventional antifungal
(Amphotericin B) inhibited C. albicans growth with MIC values ranging from
0.097 to 6.25 mg/mL. The combination of A. cordifolia and A. klaineanum
extracts exhibited a synergistic effect, especially on isolates Cab2, Cab3, and
SR ATTCP 37037 (FICI = 0.498; 0.372; and 0.186). The combination of A.
cordifolia and Amphotericin B also demonstrated a synergistic effect on C.
albicans isolates Cab3 and Cab8 (FICI = 0.380; 0.505). These results indicate
that combinations of A. cordifolia and A. klaineanum, as well as A. cordifolia
and Amphotericin B, could be exploited in developing effective drugs against
genital infections caused by C. albicans.
Keywords
Plant Extracts, Conventional Antifungals, Combinations, Inhibition,
C. albicans
1. Introduction
A vaginal infection is the presence and abnormal proliferation of micro-organisms
in the vagina, causing an inflammation known as vaginitis. Vaginal infections currently constitute a significant public health concern among women in general, and
particularly among pregnant women or those of childbearing age [1] [2]. The
WHO estimates over 374 million new cases of genital infections occur worldwide
each year [3]. They occur in 85 to 90% of cases following infection by fungi belonging to the genus Candida [4]. Other causes include bacteria (Staphylococcus aureus,
Klebsiella pneumoniae, Proteus vulgaris, Shigella spp) and parasites (Trichomonas
vaginalis) [5] [6]. In Cameroon, studies conducted in the city of Douala on the
prevalence of pathogens involved in vaginal infections and risk factors have shown
a prevalence of 28% [7]. Others, carried out by Ngaba et al. [8] and Nsagha et al.
[9] in the cities of Douala and Yaounde, showed higher prevalences of around
70.5% and 68.7%, respectively.
The treatment of infections caused by drug-resistant Candida faces several major challenges, exacerbated by the scarcity of therapeutic options and the rapid
evolution of resistance mechanisms. To date, the management of C. albicans infections relies on four available classes of conventional antifungals (azoles, echinocandins, polyenes, and pyrimidines) [4] [9]. Despite the efficacy of these drugs,
cases of recurrence are regularly reported. The improper use of anti-infective
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agents, combined with the genetic variability of microbes, promotes the emergence of resistance and the development of uncommon infections [10]. Infections
caused by resistant Candida can be difficult, sometimes impossible to cure, and
are on the rise. Meanwhile, research activities aimed at developing effective antimicrobials are particularly lengthy and costly, especially in developing countries
[11]. Moreover, aside from their long-term toxicity, conventional drugs can cause
numerous side effects. In light of this, it is imperative to seek effective control
methods that are especially low-cost, less toxic, and have a broad spectrum of action to offer alternatives to conventional therapy [12]. Indeed, in developing countries, nearly 80% of the rural population relies on medicinal plants for healthcare
[13] [14]. These plants offer several advantages due to their active natural compounds; they help prevent and combat fungal infections. Moreover, they are often
easy to cultivate or source and can be utilized in various forms (infusions, decoctions, macerations, essential oils, capsules), enabling a natural, personalized, and
organism-friendly approach to treatment [15].
Alchornea cordifolia, Antrocaryon klaineanum and Cylicodiscus gabunensis
are African medicinal plants traditionally used in Cameroon either individually
or in combination with other plants to treat infectious diseases, including genital
infections [16]. Studies have shown that these plants also possess antioxidant and
anti-inflammatory properties [17]. Furthermore, research conducted by Adedayo
et al. [18] demonstrated that combinations of these plants can not only broaden
their spectrum of activity but also prove more effective by reducing the required
concentration of each extract. These findings could have significant implications
for drug development. Further investigation is warranted to evaluate the effects of
these plant combinations on resistant pathogens and explore the combination of
plant extracts with conventional antifungals in the same context.
This study aims to determine the prevalence of vaginal infections caused by C.
albicans, evaluate the susceptibility of multidrug-resistant C. albicans isolates to
combinations of plant extracts of Alchornea cordifolia, Antrocaryon klaineanum
and Cylicodiscus gabunensis and reference antifungal agents.
2. Material and Methods
2.1. Determining the Prevalence of Vaginitis
The collection of information related to the study of the prevalence of vaginitis
was carried out over a period of five months, from October 2021 to February 2022,
during an internship at the Bacteriology Laboratory of the University Hospital
Center of Yaounde (CHU-Y). The prevalence was calculated by dividing the number of cases by the size of the exposed population. The target population consisted
of pregnant women of all ages who came for gynecological consultation at CHUY and exhibited symptoms of a vaginal infection diagnosed by a physician during
the consultation. The inclusion criteria were not to be under antibiotic or antifungal treatment during the sampling period and to agree to sign informed consent.
In total, 50 pregnant women were selected for sampling.
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=
Prevalence
Number of cases
× 100
Study population
(1)
2.2. Collection of Plant Material
The barks of Alchornea cordifolia, Antrocaryon klaineanum, and Cylicodiscus
gabunensis were collected in the locality of Kometou, Yaounde (Latitude: 4˚03'00"
N, Longitude: 11˚33'00" E, Cameroon) for the first plant, and in the locality of
Ebolowa (Latitude: 2˚54'59.99" N, Longitude: 11˚08'60.00" E, Cameroon) for the latter two. The collected plant samples were identified at the National Herbarium of
Cameroon by comparison with the specimen identification numbers 9657/SRF/Cam,
21574/SRF/Cam, and 1742/SRF/Cam, respectively for Alchornea cordifolia, Antrocaryon klaineanum, and Cylicodiscus gabunensis.
2.3. Isolation of Pathogenic Candidates
The fungal pathogens consisted of the reference strain C. albicans ATCC 37037
and clinical isolates of Candida albicans obtained from the sample population of
50 pregnant women suffering from vaginal infections, who came for consultation
at CHUY during the period from October 2021 to February 2022.
Cervico-vaginal samples were collected by swabbing according to the method
described by Catalan et al. [19]. In the gynecological position, under lighting, the
speculum was gently inserted in the closed position into the vagina until the fornix, where it was opened in a horizontal position. Swabs of the lateral walls and
the posterior fornix of the vagina were taken. A sample was also taken from the
endocervix after cleaning the exocervix with a sterile gauze pad. The presence of
clinical signs was noted before each sampling.
2.4. Determining and Characterising the Type of Vaginal Flora
The determination of the type of flora was carried out according to the protocol
of Donders et al. [20]. After collecting the samples, macroscopic examinations
consisted of noting the appearance of leucorrhea and the odor of vaginal secretions after the removal of the speculum from the vagina, as well as the characteristics of the leucorrhea (color, smell, and appearance). Regarding microscopic observations, a direct fresh state examination was performed. Indeed, the vaginal
secretions were diluted in a few drops of sterile physiological saline and then
placed on a clean slide using a Pasteur pipette, while respecting sterilization rules.
This slide was covered with a coverslip and examined under an optical microscope
at 40x magnification. This examination allows for the detection of possible microorganisms, assessment of their morphology and abundance, observation of their
motility, and the search for the presence of yeasts, epithelial cells, polymorphonuclear cells, and red blood cells.
The subsequent Gram staining allowed the bacteria to be colored and distinguished by their ability to retain gentian violet (Gram-positive) or fuchsin (Gramnegative), as well as to identify any imbalance in the vaginal flora. The flora can
be classified as type I (abundant flora), type II (normal flora), type III (partially
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destroyed flora), or type IV (completely destroyed flora) [21].
2.4.1. Culture of Samples
The culture was performed on the first day of sampling using two swabs. In a plate
containing the culture medium, and with the help of one swab from each sample,
we inoculated tightly in the first quadrant, moderately in the second, and loosely
in the third to obtain isolated colonies, while respecting sterilization precautions.
The cervical swab was used to inoculate the EMB (Eosin Methylene Blue) and
chocolate agar with polyvitex media, and the swab from the vaginal wall was immediately inoculated onto Sabouraud agar with chloramphenicol and fresh blood
agar [20]. For the blood agars (cooked and fresh), incubation was carried out at
37˚C for 24 to 48 hours under anaerobic conditions and in a humid atmosphere.
The Sabouraud-chloramphenicol medium was incubated at 37˚C for 24 to 72
hours. Positive cultures on EMB, Chocolate + polyvitex, and blood agar media
allowed the diagnosis of bacterial vaginosis, while positive cultures on SDA were
used for the diagnosis and macroscopic identification of Candida species.
2.4.2. Microscopic Identification of Candidas
The identification of yeasts was performed by naked-eye observation of colonies
grown on Sabouraud Dextrose Agar as described by Barantsevich [22]. The appearance of whitish, round, creamy colonies about 2 to 3 mm in size, with a convex elevation and regular contour indicated the presence of Candida.
To differentiate C. albicans from other Candida species, a filamentation test
(germ tube test) was conducted by placing a few Candida colonies collected with
a platinum loop into 0.5 mL of human serum. The resulting mixture was incubated at 37˚C for 3 hours. After incubation, a drop of the suspension was observed
under a 40x objective between a slide and coverslip. The observation of a germ
tube in approximately 50% of the yeasts present was indicative of C. albicans. Otherwise, the yeast was concluded to be a Candida species.
2.5. Evaluation of the Susceptibility of C. albicans to Conventional
Antifungal Agents
The antifungal susceptibility test was performed using the diffusion method
(Kirby-Bauer method) according to the protocol used by Alexyuk et al. [23]. This
test allows the assessment of the sensitivity of a yeast to selected antifungal agents.
Inoculum preparation: The inoculum was prepared at a concentration equivalent to the 0.5 McFarland standard. First, a culture was grown on SDA medium
and incubated at 37˚C for 24 to 48 hours. The next day, several colonies of similar
morphology (if possible) were picked to avoid selecting an atypical variant. The
colonies were then suspended in saline medium using a cotton swab and standardized with the 0.5 McFarland standard. The inoculum was finally adjusted by
spectrophotometry. The fungal suspension was used optimally within 15 minutes.
Plate inoculation: The fungal inoculum was inoculated using the swabbing
technique. This involved dipping a sterile cotton swab into the suspension, then
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removing excess liquid by rotating the swab against the tube walls to avoid overinoculation of the plates. The swab was then spread over the entire surface of the
agar in three directions to form tight streaks.
Placement of antifungal disks: Five antifungal disks (Econazole, Miconazole,
Fluconazole, Nystatin, Amphotericin B) were firmly placed on the surface of the
inoculated agar.
Reading inhibition zone diameters: The edge of the inhibition zone was read
with the naked eye, with the plate placed 30 cm from the eye. The inhibition zones
were read from the back of the agar plates against a black background illuminated
by reflected light. Results were measured by the diameter of the inhibition zone
using a caliper. Interpretation of results was described as (S) for sensitive, (I) for
intermediate sensitivity, and (R) for resistant.
The isolates of C. albicans that showed resistance to at least three (R ≥ 3) conventional antifungals will be selected to test their susceptibility to plant extracts.
The antifungal that demonstrated the best activity after the antifungal susceptibility test will be selected for further testing.
2.6. Preparation of Plant Extracts
Aqueous extracts were prepared according to the following protocol. Indeed, the
plants were dried away from the sun for 2 weeks, then ground using a grinder and
the various powders were obtained. For each plant the solvent used was water
(H2O). 100 g of powder from each plant material (Alchornea cordifolia, Antro-
caryon klaineanum, and Cylicodiscus gabunensis) were immersed in 1000 mL of
boiling water for 4 hours until exhaustion. The resulting decoction was left to rest
to cool, then filtered using a 0.23 mm pore-size filter. The filtrate was then left to
rest for 24 hours and subsequently dried in drying oven at 60˚C for 72 hours. The
obtained dry extracts were weighed, labeled, and stored in a refrigerator at 4˚C.
The extraction yield was determined according to the following formula (2):
=
Yield ( % )
Extract mass obtained
× 100
Mass of plant material
(3)
2.7. Evaluation of the Antifungal Potential of Plant Extracts and
Amphotericin B on C. albicans Using the Well Diffusion Method
The susceptibility of C. albicans isolates and strains was evaluated using the well
diffusion method according to the CLSI [24]. The strains were sub cultured by the
streak method on Sabouraud Dextrose Agar (SDA) to obtain pure and fresh colonies aged 48 hours. Then, isolated colonies were collected using a sealed Pasteur
pipette and suspended in 5 mL of distilled water, adjusted to a density equivalent
to the 0.5 McFarland standard, corresponding to a load of 108 cells/mL. Stock solutions of the extracts were prepared at a concentration of 100 mg/mL by dissolving the different extracts in 1 mL of distilled water to obtain the stock extract solution at 100 mg/mL. The stock solution of Amphotericin B was prepared by dissolving a 100 mg tablet in 100 mL of distilled water and making the appropriate
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dilution to reach a concentration of 1 mg/mL.
After the media solidified, Petri dishes were first inoculated by swabbing with
the inoculum of the different previously prepared strains. Then, wells of 6 mm
diameter were made using a punch. Finally, a volume of 75 µL of the test extract
solutions was introduced into each well. The inoculated Petri dishes were left for
15 minutes (pre-diffusion) under the hood and then incubated at 37˚C for 48
hours. After incubation, the inhibition zone diameters were measured, and the
sensitivity of each strain to the extracts was classified by the diameter of the inhibition zones according to the following scale: Resistant (R) for a diameter less than
6 mm, Intermediate (I) for a diameter between 6 and 13 mm, Sensitive (S) for a
diameter greater than 13 mm.
2.8. Evaluation of the Antifungal Potential of Plant Extracts and
Amphotericin B on C. albicans Using the Well Dilution Method
The determination of the inhibition parameters of plant extracts on strains and
isolates of C. albicans was carried out using the broth dilution method described
by CLSI [24], with some modifications. To do this, in each well of a 96-well microplate, a volume of 100 μL of Sabouraud Dextrose Broth (SDB) liquid medium
was added. Then, 100 μL of the stock solution of the extract to be tested or Amphotericin B (used as the reference antifungal) was added into the first four wells
of the first column (rows A, B, C, and D). After mixing, a two-fold serial dilution
was performed up to the eleventh well (starting from wells A, B, C, and D) by
transferring 100 μL from the previous well to the next well after homogenization.
This resulted in a concentration range of the extract from 25 to 0.0244 mg/mL for
extracts of A. cordifolia, C. gabunensis, A. klaineanum, and from 250 to 0.0244
mg/mL for Amphotericin B. Finally, 100 μL of fungal inoculum with a density
equivalent to the 0.5 McFarland standard (108 cells/mL) was added to each well.
The final volume was 200 μL per well, and all tests were performed in triplicate.
One row of the microplate was used as a negative control for the activity of the
extracts, containing only the culture medium and the extracts at different concentrations. Additionally, some wells in the column containing only the culture medium and the inoculum were used as positive controls for microbial growth. The
microplate was covered with its lid, sealed with cling film, and incubated at room
temperature for 24 to 48 hours. Microbial growth was detected by adding 20 μL
of Alamar Blue solution to the test wells, followed by incubation for 30 minutes.
The minimum inhibitory concentration (MIC) was defined as the lowest concentration of extract or Amphotericin B at which no visible microbial growth was
observed with the naked eye. Growth was characterized by a color change from
blue to red, and the absence of growth was indicated by the maintenance of the
blue color.
For the determination of the minimum fungicidal concentration (MFC), 50 μL
from each well with a concentration equal to the MIC was taken and added to 150
μL of Sabouraud broth. The mixture was incubated under the same conditions as
for the MIC determination and revealed with Alamar Blue.
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The fungicidal activity was evaluated according to the scale, which consisted of
calculating the MFC/MIC ratios: if MFC/MIC < 4, the substance is fungicidal; if 4
≤ MFC/MIC ≤ 16, the substance is fungistatic; and if MFC/MIC > 16, the substance is tolerant.
2.9. Study of Antifungal Effect of Plant Extracts and Amphotericin
B Combinations on C. albicans Using the Checkerboard Method
The effect of combinations of plant extracts and Amphotericin B on strains and
isolates of C. albicans was evaluated using the checkerboard method as described
by Liu et al. [25]. For this, we formulated three pairs of combinations of extracts
from A. cordifolia, A. klaineanum, C. gabunensis, and Amphotericin B in volumeto-volume proportions. The combinations tested were: A. cordifolia-A. klaineanum,
A. cordifolia-C. gabunensis, and C. gabunensis-A. klaineanum. The plant extracts
whose combination demonstrated the best activity were selected and combined
with the reference antifungal (Amphotericin B) following the same protocol to
evaluate their efficacy.
To do this, 50 µL of serial two-fold decreasing concentrations of substance A
were added vertically, and 50 µL of serial two-fold decreasing concentrations of
substance B were added horizontally so that each well contained a 50 µL cross of
a concentration from the dilution range of each substance. Then, 100 µL of fungal
inoculum at 108 CFU/mL was added to all wells. The MIC of each substance alone
was determined in parallel, where 50 µL of the same dilution series received 50 µL
of Sabouraud Dextrose Broth (SDB) and were inoculated with 100 µL of the fungal
suspension. The 96-well microplate was then sealed and incubated at 37˚C for 18
- 24 hours. After incubation, 20 µL of Alamar Blue was added to each well to assess
fungal growth and incubated at 37˚C for 30 minutes.
The MIC values of the extracts and their combinations allowed calculation of
the fractional inhibitory concentrations (FIC) according to the following formulas
(3):
FICI
= FIC1 + FIC2
(3)
FIC A = MIC of substance A in combination/MIC of substance A alone.
FIC B = MIC of substance B in combination/MIC of substance B alone.
According to Zainol et al. [26], the effects of combinations of antimicrobial substances are classified as: Synergistic if the sum of the FICI index or FICI ≤ 0.5;
Additive if 0.6 ≤ FICI ≤ 1; Indifferent if 1 < FICI ≤ 4; Antagonistic if FICI > 4.
2.10. Statistical Analysis
Data regarding the type of genital infection, the distribution of flora, and the susceptibility of C. albicans to conventional antifungal drugs were entered into an Excel
spreadsheet, and figures were generated accordingly. Concerning the effect of plant
extracts on the growth of C. albicans, the experiment was performed in triplicate
and the data were presented as mean standard deviation (±SD). Duncan’s method
was used to evaluate the significant differences between the data, and statistically
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significant differences were set at p < 0.05. Graph of this part were performed with
GraphPad Prism version 10.3.1 (GraphPad Software, Boston, MA, USA).
3. Results
3.1. Prevalence and Type of Genital Infection in the Study
Population
Out of 50 PVC samples analyzed, 15 were diagnosed negative for infectious vulvovaginitis, while 35 were positive. This results in a frequency of infectious vulvovaginitis or genital infection in the study population of 70%. Infectious vulvovaginitis was then distributed according to the nature (bacterial, fungal, and parasitic)
of each causative agent, and the results obtained, expressed as a percentage distribution, are shown in Figure 1 below. From this figure, it is noted that no cases of
vaginal parasitosis (due to Trichomonas vaginalis) were observed, 30% of cases
were vulvovaginal candidiasis (due to Candida spp. and C. albicans), and 40%
were bacterial vaginosis (due to Gardnerella vaginalis).
Figure 1. Distribution of the type of genital infection in population.
3.2. Distribution of the Type of Vaginal Flora According to the
Types of Associated Infections
Out of a total of 50 women consulted in the context of this study, the analysis of
the vaginal flora made it possible to establish the distribution of flora types according to the type of infection in the patients (Figure 2). It appears that, regarding cases of bacterial vaginosis, the majority (15 out of 18) of the patients
present a disrupted vaginal flora (type IV). On the other hand, among patients
with vaginal candidiasis as well as those who are not infected, the normal vaginal
flora (type II), with a total of 10 out of 15 and 12 out of 15 respectively, is the
most represented.
3.3. Distribution and Specification of Isolated Yeast Species
Figure 3 below shows the distribution of vulvovaginal candidiasis (VVC) accordDOI: 10.4236/jbm.2025.136009
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ing to the Candida species involved. This figure reveals that, out of 15 isolates
obtained, C. albicans was the species most frequently responsible for VVC, with a
frequency rate of 60% (i.e., 9/15 isolates).
Figure 2. Distribution of flora type according to type of infection in patients.
Figure 3. Breakdown of yeasts isolated by species.
3.4. Susceptibility Profile of C. ablicans Isolates to Conventional
Antifungal Agents
The antifungigram test was performed with five conventional antifungals (Econazole, Miconazole, Fluconazole, Nystatin, Amphotericin B) on the nine C. albi-
cans isolates obtained. Table 1 presents the sensitivity and resistance profile of the
Candida albicans isolates to the five antifungals tested. This table shows that 8 C.
albicans isolates were resistant to at least 1 conventional antifungals and are therefore multidrug-resistant. Isolates Cab2 and Cab8 were resistant to 4 antifungals;
Cab3, Cab5, and Cab9 showed resistance to three antifungals; Cab4, Cab6, and
Cab7 were resistant to two antifungals; and finally, isolate Cab1 was resistant to
one antifungal.
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Table 1. Sensitivity profile of different isolates of C. albicans to the five antifungal drugs
tested.
Isolates
Species
Conventional antifungals
Total
Amphotericin
resistance
Econazol Fluconazol Miconazol Nystatin
B
Cab1 C. albicans
S
S
R
S
S
1
Cab2 C. albicans
S
R
R
R
R
4
Cab3 C. albicans
S
R
R
R
S
3
Cab4 C. albicans
S
R
S
R
S
2
Cab5 C. albicans
S
R
R
R
S
3
Cab6 C. albicans
S
R
R
S
S
2
Cab7 C. albicans
S
S
R
R
S
2
Cab8 C. albicans
S
R
R
R
R
4
Cab9 C. albicans
S
R
R
R
S
3
R: Resistant; S: Sensitive ; Cab: C. ablicans isolate.
Isolates of C. ablicans showing resistance to at least three conventional antifungal
agents were selected to test their succeptibility to plant extracts. The histogram in
Figure 4 below shows the results expressed as percentage sensitivity for each conventional antifungal on the 9 isolates after antifungigram testing. An analysis of this
figure reveals that the sensitivity of Candida isolates varies depending on the different antifungals. Amphotericin B and Nystatin had the highest spectra of action with
sensitivities of 100% and 77.77%, respectively. They were followed by Econazole and
Miconazole, which demonstrated a sensitivity rate of 22.23%. Except for Cab4, all
other isolates were resistant to Fluconazole, which therefore showed a low sensitivity
(11.11%). In terms of intermediate sensitivity, we obtained 0% with all the antifungals tested. Regarding the resistance rate, Amphotericin B recorded 0%, Nystatin
22.23%, Econazole and Miconazole 77.78%, and Fluconazole 88.88%.
Figure 4. Distribution of C. albicans according to their susceptibility to conventional
antifungal drugs.
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3.5. Yields Extracts of Plants
The extraction yield of plants was 28.41 % for A. cordifolia, 12.65% for A.
klaineanum and 8.3% for C. gabunensis (Table 2).
Table 2. Extraction yield of differents plants.
Yields extracts
A. cordifolia
A. klaineanum
C. gabunensis
28.41%
12.65%
8.3%
3.6. Anti-Candida Activity of Individual Plant Extracts and
Amphotericin B
The antifungal potential of Alchornea cordifolia, Antrocaryon klaineanum,
Cylicodiscus gabunensis, and Amphotericin B was evaluated on five multidrugresistant Candida albicans isolates (Cab2, Cab3, Cab5, Cab8, and Cab9) and on
the reference strain C. albicans ATTCP 37037. Figure 5 below shows the inhibition diameters (mm) of the substances tested on six C. albicans yeasts. This figure
reveals that the inhibition diameters generated by the plant extracts vary depending on the plant extract tested. At the tested concentration of 100 mg/mL, Amphotericin B was statistical more active than all the plant extracts (p < 0.05 according to Duncan’s test). Also, the extract of A. cordifolia was statisticaly more
active (p < 0.05) than the other extracts, with inhibition diameters of 14.7 mm on
Cab2, 13.5 mm on Cab3, 13.8 mm on Cab5, 14.6 mm on Cab8, 13.2 mm on Cab9,
and 13.5 mm on the reference strain C. albicans ATTCP 37037. This was followed
by the extract of A. klaineanum, which showed an average inhibition diameter on
all C. albicans isolates of 8.63 mm. Finally, the extract of C. gabunensis demonstrated an average inhibition diameter of 6.4 mm on all C. albicans isolates. From
these observations, it can be concluded that all C. albicans isolates were sensitive
Figure 5. Effect of plant extracts on the growth (diameters in mm) of 6 C. albicans yeasts.
For the same isolate and different plant extract activity, the histograms bearing different
letters (a, b, c, d) present a significant difference at p ≤ 0.05. For the same plant extract for
different isolates, the histograms with different letters (1, 2, 3) are significantly different at
p ≤ 0.05 according to Duncan’s text.
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to the extract of A. cordifolia (inhibition diameter > 13 mm) and showed intermediate sensitivity to the extracts of A. klaineanum and C. gabunensis (6 < inhibition diameter < 13 mm).
3.7. MIC and CMF of Extracts on the Growth of C. albicans Isolates
The MICs and MFCs were determined by microdilution, and the results are recorded in Table 3 below. An analysis of this table shows that the MICs and MFCs
vary from one extract to another and depending on the isolates. The MICs of the
A. cordifolea extract were 0.39 mg/mL for isolate Cab5, 0.781 mg/mL for isolates
Cab2, Cab3, Cab8, Cab9, and 1.56 mg/mL for the reference strain C. ablicans
ATCC 37037. A. klaieneanum extract showed MICs ranging from 0.390 to 1.56
mg/mL on the growth of the strains. Also, the C. gabunensis extract presented
MICs between 0.195 and 6.250 mg/mL. Regarding the MFCs, they ranged from
1.56 to 3.125 mg/mL for the A. cordifolea extract, from 6.250 to 12.5 mg/mL for
A. klaieneanum extract, and 3.125 mg/mL for the C. gabunensis extract. The obtained MICs and MFCs allowed the calculation of the MFC/MIC ratio to determine the nature of inhibition of each extract (fungicidal, fungistatic, or tolerant).
In this results, A. cordifolea extract demonstrated fungicidal activity on four isolates (Cab2, Cab8, Cab9, and ATCC 37037) (MFC/MIC < 4) and fungistatic activity on two isolates (Cab3 and Cab5) (4 ≤ MFC/MIC ≤ 16). Furthermore, A.
klaieneanum extract showed fungistatic activity on Cab2, Cab8, and ATCC 37037.
C. gabunensis extract, it exhibited tolerant activity on Cab8 (MFC/MIC > 16) and
fungistatic activity on ATCC 37037. Amphotericin B showed fungicidal activity
on Cab2 and Cab8, and fungistatic activity on Cab5, Cab9, and ATCC 37037.
Table 3. Inhibition parameters of plant extracts on clinical isolates of C. ablicans.
Plant extracts
Antifungal
Isolates Parameters A. cordifolia A. klaieneanum C. Gabunensis Amphotéricine B
Cab2
Cab3
Cab5
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MIC (mg/ml)
0.781
0.781
3.125
0.0156
MFC (mg/ml)
1.562
6.250
Nd
0.0312
MFC/MIC
2
8
Nd
2
Activity
Fungicide
Fungistatic
Nd
Fungicide
MIC (mg/ml)
0.781
0.390
1.562
0.0156
MFC (mg/ml)
3.125
12.50
Nd
0.0312
MFC/MIC
4
32
Nd
Nd
Activity
Fungistatic
Tolerant
Nd
Nd
MIC (mg/ml)
0.390
0.390
0.781
0.0039
MFC (mg/ml)
3.125
6.250
Nd
0.0625
MFC/MIC
8
16
Nd
16
Activity
Fungistatic
Fungistatic
Nd
Fungistatic
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Continued
Cab8
Cab9
SR
MIC (mg/ml)
0.781
0.781
0.195
0.0156
MFC (mg/ml)
1.562
Nd
3.125
0.0312
MFC/MIC
2
Nd
32
2
Activity
Fungicide
Nd
Tolerant
Fungicide
MIC (mg/ml)
0.781
1.562
6.250
0.0078
MFC (mg/ml)
1.562
Nd
Nd
0.0625
MFC/MIC
2
Nd
Nd
8
Activity
Fungicide
Nd
Nd
Fungistatic
MIC (mg/ml)
1.562
1.562
0.781
0.0039
MFC (mg/ml)
3.125
12.5
3.125
0.0625
MFC/MIC
2
8
2
16
Activity
Fungicide
Fungistatic
Fungistatic
Fungistatic
Legend: Nd: Not determined, MIC: Minimum Inhibitory Concentration, MFC: Minimum
Fungal Concentration, Cab: C. ablicans isolate, SR: souche de référence ATTCP 37037.
3.8. Effect of Combinations of Different Plant Extracts and
Amphotericin B on the Growth of C. ablicans
The effect of combinations of plant extracts A. cordifolia-A. klaineanum, A. cordifolia-C. gabunensis and C. gabunensis-A. klaineanum on isolates and strains of
C. albicans is shown in Table 4. This table groups their individual MICs, the MICs
of the combinations, the Fractional Inhibitory Concentrations (FIC), and the
Fractional Inhibitory Concentration Indexes (FICI).
It appears from this table that the combination of A. cordifolia-A. klaineanum
extract (Ac + Ak/v:v) demonstrated a synergistic effect on Cab2, Cab3, and SR
ATTCP 37037 with respective FICI values of 0.498, 0.372, and 0.186; an additive
effect on Cab5 and Cab8 (FICI = 0.748); and an indifferent effect on Cab9 (FICI
= 1.499). Regarding the combination A. cordifolia-C. gabunensis (Ac + Cg/v:v),
it showed a synergistic effect on SR ATTCP 37037 (FICI = 0.498); an additive
effect on Cab2, Cab5, and Cab9 (FICI = 0.998, 0.747, and 0.747 respectively);
and an indifferent effect on isolates Cab3 (FICI = 2.249) and Cab8 (FICI =
1.499). The combination C. gabunensis-A. klaineanum (Cg + Ak/v:v) presented
an additive effect on Cab3 (FICI = 1.000); an indifferent effect on Cab8, Cab9,
and SR ATTCP 37037 (FICI = 2.499, 2.500, and 2.249 respectively); and an antagonistic effect on Cab2 and Cab5 with FICI values of 5.001 and 5.005 respectively.
The plant extracts of A. cordifolia and A. klaineanum proved to be the most
active, both in antifungal tests of individual extracts and in combination. These
two plants were each combined with a reference antifungal (Amphotericin B) and
tested on isolates and strains of C. albicans. The results of this test are presented
in Table 5. It emerges from this table that the combination A. cordifolia-AmphoDOI: 10.4236/jbm.2025.136009
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tericin B (Ac + AmB/v:v) demonstrated a synergistic effect on Cab3 and Cab8
(FICI: 0.380 and 0.505 respectively); a additive effect on Cab2 and Cab9 (FICI:
0.761 and 0.636); a indifferent effect on SR ATTCP 37037 (FICI: 1.275); and a
antagonistic effect on Cab5 (FICI: 4.602). The combination A. klaineanum-Amphotericin B (Ak + AmB/v:v) showed an additive effect on SR ATTCP 37037 with
a FICI value of 0.637; an indifferent effect on Cab2, Cab3, Cab8, and Cab9 (FICI:
1.274, 2.256, 2.512, and 1.512 respectively). From these results, it appears that the
combination A. cordifolia-A. klaineanum was more active than all the extract–
extract plant combinations. Also, the combination A. cordifolia-Amphotericin B
proved more effective than the combination A. klaineanum-Amphotericin B. Furthermore, all combinations demonstrated better anticandidasis activity than the
individual plant extracts. The sensitivity of the isolates and strains of C. albicans
to the different combinations varied from one isolate to another and also depending on the type of combination.
Table 4. Interactions of plant extract-plant extract combinations on isolates and strains of C. ablicans.
Isolates
Cab2
Cab3
Cab5
Cab8
Cab9
SR
Ac +Ak (v:v)
plants
MICES
extracts
MICco FCI FICI EFFECT MICco
FCI
0.390
0.499
Ac
0.781
0.195
0.249
Ak
0.781
0.195
0.249 0.498
Cg
3.125
Ac
0.781
0.097
0.124
Ak
0.390
0.097
0.248 0.372
Cg
1.562
Ac
0.390
0.195
0.500
Ak
0.390
0.097
0.248 0.748
Cg
0.781
Ac
0.781
0.195
0.249
Ak
0.781
0.390
0.499 0.748
Cg
0.195
Ac
0.781
0.390
0.499
Ak
1.562
1.562
1.00 1.499
Cg
6.25
Ac
1.562
0.097
0.062
Ak
1.562
0.195
0.124 0.186
Cg
0.781
S
nd
S
nd
A
nd
A
nd
I
nd
nd
S
Ac + Cg (v:v)
nd
0.499
0.195
0.249
nd
2.00
0.097
0.248
nd
0.499
0.390
0.499
nd
1.000
0.195
0.249
nd
0.5
0.390
0.249
0.249
3.125
4.001 5.001
3.125
1.000
An
I
0.195
0.5
1.000
A
0.781
0.5
A
1.562
4.005 5.005
An
0.781
1.000
I
0.390
0.499 2.499
0.390
2.000
I
A
3.125
2.000 2.500
3.125
0.500
I
nd
0.498
nd
A
nd
0.749
3.125
FICI EFFECT
nd
1.499
0.195
FCI
nd
0.747
0.390
MICco
nd
2.249
3.125
EFFECT
nd
0.998
1.562
0.195
FICI
Cg + Ak (v:v)
S
3.125
2.000 2.249
0.195
0.249
I
Legend: Ac: A. cordifolia; Ak: A. klaineanum; Cg: C. gabunensis; SR: Reference strain ATTCP 37037; Cab: C. ablicans Isolate; S:
Synergy; I: Indifferent; A: Additive; An: Antagonist; FCI: Fractional Inhibitory Concentration; FICI: Fractional Inhibitory Concentration Index; FIC: Fractional Inhibitory Concentration; MICIE: MIC of individual extracts; MICco: MIC of combinations.
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Table 5. Effect of plants extracts and Amphotericin combinations on C. ablicans.
Isolates
Cab2
Cab3
Cab5
Cab8
Cab9
SR
Ac + AmB (v:v)
Substance
CMIIS
Ac
0.781
Ak
0.781
AmB
0.0156
0.008
0.512
Ac
0.781
0.097
0.124
Ak
0.390
AmB
0.0156
0.004
0.256
Ac
0.390
0.195
0.500
Ak
0.390
AmB
0.0039
0.016
4.102
Ac
0.781
0.195
0.249
Ak
0.781
AmB
0.0156
0.004
0.256
Ac
0.781
0.0975
0.124
Ak
1.560
AmB
0.0078
0.004
0.512
Ac
1.560
0.390
0.250
Ak
1.560
AmB
0.0039
MICco
FCI
0.195
0.249
nd
EFFECT
A
0.195
0.249
1.274
I
0.016
1.025
S
2.258
I
5.102
An
2.512
I
1.512
I
0.637
A
0.781
2.002
0.004
0.256
An
0.390
1.000
0.016
4.102
S
1.562
2.000
0.008
0.512
nd
0.636
nd
FICI
nd
0.505
nd
FCI
nd
4.602
nd
MICco
nd
0.380
nd
EFFECT
nd
0.761
nd
0.004
FICI
Ak + AmB (v:v)
A
1.562
1.000
0.004
0.512
nd
1.275
1.025
I
0.195
0.125
0.002
0.512
Legend: Ac: A. cordifolia; Ak: A. klaineanum; AmB: Amphotéricine B; SR: SR: Reference strain ATTCP 37037; Cab: C. ablicans
Isolate; S: Synergy; I: Indifferent; A: Additive; An: Antagonist; FCI: Fractional Inhibitory Concentration; FICI: Fractional Inhibitory
Concentration Index; FIC: Fractional Inhibitory Concentration; MICIE: MIC of individual extracts; MICco: MIC of combinations.
4. Discussion
Cervicovaginal swabs (CVS) were obtained from women attending gynecological
consultations at CHUY. These samples enabled the identification of isolates responsible for genital infections. The isolates obtained were categorized according
to the type of infectious vulvovaginitis. Thus, fifteen CVS samples were diagnosed
as negative for infectious vulvovaginitis, while 35 were positive. The prevalence of
infectious vulvovaginitis or genital infection in the population was 70%, comprising 40% bacterial vaginosis (BV), 30% vulvovaginal candidiasis (VVC), and 0%
vaginal parasitosis (VP) due to Trichomonas vaginalis. This prevalence of bacterial vaginosis closely aligns with that reported in Cameroon (42%) by Koueke [27].
The prevalence of vulvovaginal candidiasis obtained is similar to studies conducted in Tunisia (36.39%) also in Cameroon respectly by Anane et al. [28] and
Okalla et al. [7] in Cameroon (32%). The prevalence of parasitic infections (0%)
in this study differs from data reported by Tibaldi et al. [29] in Turin, where trichomoniasis accounted for 1.6%. Conversely, Okalla et al. [7] found, among 300 paDOI: 10.4236/jbm.2025.136009
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tients, 40.46% bacterial-origin vaginal infections and 51.45% fungal-origin infections, predominantly due to Candida albicans (86.46%). Furthermore, a study
conducted in Pennsylvania, USA, on the effect of reusing vaginal contraceptives
on vaginal microflora and infection risk identified three species among the pathogens: Candida albicans, Escherichia coli and Staphylococcus aureus [30]. These
differences in prevalence may be explained by variations in the studied populations, the number of vaginal samples collected, and the sociodemographic conditions of the different study locations. The predominance of bacterial vaginosis
among these infectious vulvovaginitides could be related to the fact that bacteria
possess more virulence factors compared to yeasts to Candida genus. Moreover,
the vaginal environment is not a selective medium for parasites, which accounts
for the low rate of vaginal parasitosis observed.
In our study, 60% of yeasts involved in vulvovaginal candidiasis (VVC) were
Candida albicans. This high involvement of C. albicans in VVC could be explained
by the strong adhesion of C. albicans to the vaginal mucosa, facilitated by the presence of vaginal cellular receptors for the Candida ligand. This interaction allows
the expression of its virulence factors, germination and transformation from the
saprophytic state in the form of blastospores to the pathogenic filamentous form.
The distribution of different infectious vulvovaginitis types according to the flora
type highlighted an imbalance in the vaginal flora. Type II flora was predominantly found with a rate of 66.66% in VVC, which contradicts the studies conducted by Sylla et al. [31] in Dakar, where type III flora was predominant at 43.8%.
This result supports the hypothesis that candidosis vaginosis is associated with an
imbalance and destruction of the vaginal flora.
Of the 9 Candida albicans isolates obtained, 5 were multidrug-resistant (resistant to at least three antifungal agents), namely Cab2, Cab3, Cab5, Cab8, and
Cab9. These isolates were sensitive to Amphotericin B and Nystatin at rates of
100% and 77.77%, respectively, followed by Econazole and Miconazole, which
showed sensitivity rates of 22.22%. Regarding resistance rates, Fluconazole led
with 88.88%, followed by Econazole and Miconazole at 88.88%, then Nystatin at
22.23%, while Amphotericin B showed 0% resistance. These results are comparable to those reported by Kpongbo et al. [32] in Côte d’Ivoire, who demonstrated
100% sensitivity to Amphotericin B, as well as those of Badiee et al. [33] with
98.6% sensitivity to Nystatin. Conversely, these findings do not corroborate the
work of de Gonsu et al. [34] in Cameroon, who reported a 99% sensitivity rate of
Candida to Miconazole and a 95% resistance rate to Amphotericin B. This discrepancy may be related to the use of different diagnostic methods. The high resistance rates observed for Fluconazole and Miconazole could be attributed to
their long-standing use and widespread self-medication among Cameroonian
populations. A study conducted in the intensive care unit of CHU Grenoble between 2004 and 2009 showed that prior antifungal consumption altered the epidemiology and antifungal susceptibility of Candida species [35]. Furthermore,
strains often acquire mutations in their genes over time, which can impact their
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antifungal susceptibility profiles.
The results obtained in this study demonstrate that all evaluated extracts exhibited antimicrobial activity against the six tested strains of Candida albicans.
Among the three tested extracts, A. cordifolia and A. klaieneanum showed strong
activity with minimum inhibitory concentrations (MICs) ranging from 0.390 to
1.562 mg/mL against the isolates and strains of C. albicans. Numerous authors
have reported the antibacterial, antiparasitic, and antifungal potential of A. cordi-
folia, A. klaieneanum, and C. gabunensis in combating vaginal infections [36][39]. Our results are similar with those of Domfeh et al. [40], who demonstrated
the efficacy of A. cordifolia against C. albicans strains. Additionally, Agyare et al.
[41] showed the anti-infectious properties of A. cordifolia extract on C. albicans
isolates. Also, Amang à Ngnoung et al. [42] revealed the antimicrobial potential
of secondary metabolites from A. klaieneanum on C. ablicans. Conversely, the
extract of C. gabunensis exhibited the lowest activity, with MICs ranging from
0.195 to 6.250 mg/mL. This finding contrasts with the work of Ndjib et al. [16],
who, in their ethnobotanical study of medicinal plants used in Cameroon for
treating vaginal infections, demonstrated that C. gabunensis extract was highly
active against C. albicans. The discrepancy between our results and those of other
authors may be attributed to the extraction methods and drying temperatures
used, which could inhibit certain active principles of the plant. The antifungal efficacy of these plants could be related to their chemical composition, which is rich
in secondary metabolites such as shikimic acid, quercetin, myricetin, quercitrin,
kaempferol, proanthocyanidins, phenolic acids, and flavonoids [43]-[45]. These
secondary metabolites present in the plants are believed to act on the fungal microorganism membranes, inducing destabilization and destruction through turgescence [46].
Therapeutic combinations represent a critical avenue in the search for effective
antimicrobial agents, as synergistic interactions can potentially broaden the spectrum of activity, minimize the emergence of antifungal-resistant microorganisms,
and reduce toxicity and treatment duration (El Baz et al., 2025). According to this
study’s findings, the A. cordifolia-A. klaineanum combination (Ac + Ak, v:v)
demonstrated synergistic effects against Cab2, Cab3, and C. ablicans SR ATTCP
37037, with enhanced antifungal properties and combined minimum inhibitory
concentrations (MICco) ranging from 0.097 to 1.562 mg/mL. Similarly, the A.
cordifolia-Amphotericin B combination (Ac + AmB, v:v) exhibited synergy
against Cab3 and Cab8, with variant MICs of 0.008 - 0.195 mg/mL. The combined
extracts produced larger inhibition zones, indicative of stronger antimicrobial activity and suggesting distinct mechanisms of action. Similar results were reported
by Hlebová et al. [47], who observed synergistic effects of plant extracts on C. al-
bicans, C. glabrata and C. tropicalis isolates. Ghandour et al. [48] also revealed
synergistic activity of medicinal plant combinations against C. albicans isolates.
Furthermore, Adelakun et al. [18] demonstrated synergistic interactions between
T. cordifolia extracts and conventional antifungals (fluconazole) against C. albiDOI: 10.4236/jbm.2025.136009
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cans. The observed synergy between plant-plant and plant-conventional antifungal combinations may stem from bioactive compound diversity, which potentiates
overall inhibitory action on C. albicans isolates. High concentrations of active secondary metabolites in these combinations likely establish a coordinated mechanism that impedes pathogenic microorganisms from developing resistance [49][46].
5. Conclusion
This study focused on isolating resistant Candida albicans isolates and assessing
their susceptibility to conventional antifungals and plant extracts from A. cordi-
folia, A. klaineanum, and C. gabunensis. Nine fungal isolates were obtained, five
of which exhibited resistance to at least two antifungals (Cab2, Cab3, Cab5, Cab8,
Cab9, and reference strain ATCC 37037). All plant extracts and amphotericin B
inhibited C. albicans growth, with minimum inhibitory concentrations (MICs)
ranging from 0.097 to 6.25 mg/mL. Fractional inhibitory concentration index
(FICI) calculations identified two combinations with the most synergistic effects:
A. cordifolia-A. klaineanum extract against Cab2, Cab3, and reference strain
ATCC 37037 (FICI = 0.498, 0.372, and 0.186), and A. cordifolia-amphotericin B
against C. albicans isolates Cab3 and Cab8 (FICI = 0.380 and 0.505). Thus, the
combinations of A. cordifolia-A. klaineanum and A. cordifolia-amphotericin B
can be recommended as alternatives to synthetic antifungals for treating genital
infections caused by C. albicans, provided that their cytotoxicity on vaginal epithelial cells is evaluated in order to establish their safety profile for potential clinical use in topical applications.
Acknowledgments
The authors thank the Yaounde University Hospital Center (CHUY) for the support, technical platform, and provision of the reference strain C. albicans SR
ATCC 37037.
Conflicts of Interest
The authors declare that they have no conflict of interest regarding the publication
of this article.
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