Antifungal Activities of Phytochemically Characterized Hydroethanolic Extracts of Sclerocarya birrea Leaves and Stem Bark against Fluconazole-Resistant Candida albicans Strains

The study evaluated the antifungal activities of the 70% ethanol extracts of Sclerocarya birrea leaves (SBL) and stem bark (SBB) against C. albicans strains and fluconazole-resistant isolates, their antifungal effects in combination with conventional antifungals as well as their effects on the biofilms of the C. albicans strains and isolates. UPLC-QTOF-MS/MS analysis was then carried out to investigate the metabolite profile of the extracts and UPLC fingerprints developed for their routine identification as part of quality control measures. The extracts exhibited considerable antifungal activity with MIC ranging from 12.21 to 97.66 μg/mL and MFC from 12.21 to 390.63 μg/mL against the C. albicans strains and isolates. The antifungal activity of the stem bark extract was higher than the leaf extract. SBL and SBB also significantly inhibited biofilm formation (IC50 = 12.49 to 164.42 μg/mL) and the mature biofilms (IC50 = 91.50 to 685.20 μg/mL) of the strains and isolates of the C. albicans and demonstrated potential for their use in combination therapies with currently used antifungals especially the stem bark extract with nystatin. Metabolite profiling identified the presence of polyphenolic compounds in both leaves and stem bark mostly flavonoids, their derivatives, and proanthocyanidins, which contribute in part to the bioactivity of the plant. Whereas flavonoids like quercetin, myricetin, and their derivatives were abundant in the leaves, epicatechin monomers with their condensed tannins, including procyanidin B2 and procyanidin C, were abundant in the stem bark. Fingerprints of SBL and SBB were developed and validated and could be used as qualitative tools to authenticate the plant. The outcomes of the study show the promise of the leaf and stem bark extracts of S. birrea to be studied further and developed as antifungal agents.


Introduction
Vulvovaginal candidiasis (VVC), the second most common vaginal infection among women of reproductive age, is a disease caused by fungi of the genus Candida [1]. Surveys suggest that about 70-75% of women develop vulvovaginal candidiasis once in their lifetime [2] with Candida albicans, the causative organism in majority of the cases [3], although candidiasis caused by non-C. albicans species especially C. glabrata and C. auris has been on the ascendancy in recent times [4]. Candida albicans is a component of the normal vaginal flora and only becomes an opportunistic pathogen that causes VVC when there is a decline in the body's immunity [5]. VVC causes a lot of physical and emotional discomforts in patients, poses a challenge to healthcare providers, and produces considerable financial strain on patients and their caregivers due to medication costs and hospital visits [6]. Coupled to these untoward implications, the disease has been associated with high risk of complications in pregnancy including congenital cutaneous candidiasis, candida chorioamnionitis, preterm delivery, and abortion [7].
Currently, there are no approved immunotherapies or vaccines against fungal infections. The typical first-line chemotherapy for VVC is with azole-class imidazole and triazole antifungals which can be administered topically or orally [8]. Other commonly used antifungals include the polyenes, mainly nystatin and echinocandins like caspofungin [9]. Although most antifungal medications are available, the choice of treatment by patients especially in sub-Saharan Africa is influenced by their socioeconomic conditions. These oral antifungal medications also possess adverse effects such as gastrointestinal disorders and headaches whereas the topical agents are known to cause hypersensitivity reactions like burning, itching, and erythema [10]. Over the past few years, fluconazole has emerged as the drug of choice for VVC owing to its efficacy, safety, favourable pharmacokinetics, and availability as a generic product [11]. Its extensive use for both acute episodes and maintenance regimen has resulted in fluconazole resistance in the causative organisms particularly C. albicans due to the over exposure of the agent to the Candida species [12]. Similarly, there has been an upward trend in resistance across the various classes of antifungals in the Candida species lately [13]. This emergence of drug-resistant fungi poses a major threat to human health and underscores the urgent demand for the discovery and development of new antifungal agents.
Traditional medicine practice is widely employed by a large populace of the world especially in developing countries for their health and well-being, with medicinal plants as the agents of choice in most traditional medicine practices in treating both infectious and non-infectious diseases [14]. One of such plants used in the treatment of communicable diseases among the indigenous Ghanaian population is Sclerocarya birrea (A. Rich.) Hochst (family: Anacardiaceae). It is a tree usually located in the semi-arid, deciduous, and savannah areas of sub-Saharan Africa and grows in wooded grasslands and bushlands [15]. S. birrea is widely distributed across West and East Africa from Gambia to Sudan [16]. The plant is a single-stemmed, perennial, medium-sized tree that grows up to 13 meters high with stout branchlets and grey fissured bark [17]. Its compound leaves possess 7-13 pairs of leaflets together with a terminal one, crowded near the end of the branches. The leaf is about 60 mm long that tapers abruptly into a narrow end with a dark-green upper surface but lighter underneath [18]. S. birrea bears highly aromatic and fleshy fruits with sweet-sour taste which has become part of the diet of Southern Africa [19].
Various parts of the plant are used extensively in traditional medicine for treating several ailments. The leaves and fruits are used in treating coughs, diabetes, dysentery, scorpion and snake bites, malaria, inflammations, and hypertension [20]. The stem bark decoctions of the plant are taken to treat diarrhoea and dysentery and administered to patients suffering from gangrenous rectitis [21]. S. birrea stem bark is also utilized by South Africans in treating fevers and ulcers whereas the roots are used in the treatment of sore eyes, pharyngitis, goitre, and splenomegaly [22]. Due to the plethora of applications of S. birrea in folk medicine, extracts of the plant have been studied and shown to possess antidiabetic [23], antihypertensive [24], antibacterial [25], antiparasitic [26], antiinflammatory [27], and antioxidant [28] activities. Previous phytochemical investigation of the stem bark of S. birrea led to the isolation of quercetin derivatives such as  [20]. The presence of some of these polyphenolic compounds has also been confirmed through HPLC-MS analysis of extracts of the plant. Whereas flavonoid glycosides and galloylated glycosides of quercetin and kaempferol are prominent in the leaf extracts, galloylated tannins and procyanidins are present in the stem and root barks [29][30][31][32].
Roots of S. birrea are a major component of some antifungal herbal products used in the treatment of candidiasis on the Ghanaian markets. Previous investigations have demonstrated the potent antifungal activity of the ethanolic root extracts of S. birrea against susceptible Candida species [33]. However, the use of the roots of the plant by the herbal industry, who are dependent on the continuous supply of raw materials, is unsustainable and could lead to extinction. Additionally, there is no reported study on the antifungal activity of the plant against resistant strains of the Candida species. Furthermore, the development of chromatographic fingerprints for the unequivocal identification and quality assessment of S. birrea is of paramount importance in the face of adulteration. Consequently, this study sought to investigate the antifungal activity of the more sustainable leaves and stem bark of S. birrea against fluconazoleresistant isolates of C. albicans, assess their inhibitory activity on the biofilms of the resistant C. albicans isolates, and evaluate their effects on the activity of conventional antifungal agents. UPLC-QTOF-MS/MS analysis was carried out to characterize the bioactive phytoconstituents in the extracts and UPLC fingerprints for the purposes of routine identification as part of quality control measures of the leaves and stem bark are also reported. Powdered leaves and stem bark of S. birrea (500 g each) were cold macerated separately with 70% hydro-ethanol (3 x 3 days) at room temperature amid constant shaking with a mechanical shaker. The extracts obtained were combined and lyophilized into solid extracts with a Lyotrap-Ultra freeze dryer (LTE Scientific, United States) [34]. The weight of the extracts obtained was 32.75 g (yield: 6.55%) and 23.39 g (yield: 4.68%) and designated as SBL (leaves) and SBB (stem bark), respectively. C. albicans clinical isolates from pregnant women with VVC were sourced from the Microbiology Laboratory Department, Ho Teaching Hospital, Ghana. Separate fungal colonies were subcultured on SDA supplemented with chloramphenicol and incubated at 37°C for 48 h to ensure pure Candida isolates were obtained. The C. albicans isolates were identified using HiCrome Candida Differential Agar (HiMedia Laboratories, India). Isolates were incubated at 35°C for 48 h, and the colours produced were recorded. C. albicans isolates were identified by their smooth and light green colours. Confirmation was carried out using API ID 32C strips (Biomerieux, France) [35].

Fluconazole Susceptibility Test of the C. albicans
Isolates. The sensitivity of the C. albicans isolates against fluconazole (25 μg) or otherwise was investigated using a disc diffusion method [36] with slight modifications. In brief, isolates of C. albicans from the SDA plates were emulsified with 0.85% sterile saline solution to obtain a suspension of turbidity 0.5 McFarland. Media lawns were then seeded in three dimensions with sterile swabs dipped in the prepared suspension. Fluconazole-loaded disks were thereafter placed on the lawn aseptically before incubating for 24-48 h at 37°C. Zone diameters produced by the fluconazole disks were measured using a ruler. Zone diameters of ≥19 mm were deemed susceptible, 15 to 18 mm dose-dependently sensitive, and ≤14 mm resistant. As such, five fluconazoleresistant C. albicans isolates were selected for study and were assigned as CA-R1, CA-R2, CA-R3, CA-R4, and CA-R5, respectively.

Evaluation of Antifungal
Activity. The antifungal effect of the 70% ethanol extracts of S. birrea leaves (SBL) and stem bark (SBB) was evaluated using the broth microdilution method in accordance with document M27-A3 by the Clinical and Laboratory Standards Institute (CLSI) (2008) [37] with slight modifications. Voriconazole and fluconazole were used as positive controls and the blank media employed as negative control. The Minimum Inhibitory Concentrations (MICs) were determined visually before confirmation using spectrophotometry at 490 nm using a microplate reader. Each experiment was carried out in triplicate.

Determination of Minimum Fungicidal Concentration (MFC).
To assess the fungicidal effect of the extracts, aliquots from each well from the antifungal activity assay were transferred onto SDA plates which were thereafter incubated for 48 h at 37°C. The plates were then analyzed for the presence or absence of growth [39].

Effect of the Extracts in Combination with Clinically Used
Antifungals. The antifungal effect of SBL and SBB when combined with fluconazole, nystatin, or caspofungin, respectively, were determined using the checkerboard assay modified from EUCAST-AFST guidelines reference technique [40]. MICs were determined by visually before confirmation using spectrophotometry at 490 nm using a microplate reader. Each experiment was carried out in triplicate.
The result was analyzed by calculating the Fraction Inhibitory Concentration Indices (FICI) which is a nonparametric model built on the Loewe additivity theory. 2.5. Activity of the Extracts against C. albicans Biofilms. The inhibition of biofilm formation and activity against preformed biofilms of the C. albicans strains of SBL and SBB were determined using the 96-well plates according to methods described below.
2.5.1. Inhibition of Biofilm Formation Assay. Briefly, 50 μL of RPMI 1640 was pipetted into wells of a 96-well microplate together with 50 μL of the extracts in column 1. This was serially diluted till column 10 to obtain concentrations 1000-3.91 μg/mL. Thereafter, 50 μL of fungal inoculum at concentration of 2 × 10 6 cells/mL was added to well of columns 1-11 of the plates and incubated at 37°C for 24 h. After incubation, the media in each well was carefully aspirated to not disrupt the biofilms and the plates washed with 100 μL PBS (thrice) to remove nonadherent and/or planktonic cells that remained in the wells. Afterwards, 100 μL of XTT/menadione reagent was added to the wells and the plates incubated at 37°C for 2 h in the dark. Thereafter, 80 μL of the resulting-coloured supernatant from the wells was transferred into new microplates and the plates measured spectrophotometrically at 490 nm [42].

Inhibition of Preformed Biofilm.
Fungal suspension (100 μL of 1 × 10 6 cells/mL in RPMI 1640) of each C. albicans strain was transferred into wells of a 96-well plate and incubated for 24 h at 37°C to allow for biofilm formation. The media from the wells were then aspirated carefully so not to touch the biofilms formed and washed twice with 100 μL PBS to remove nonadherent and/or planktonic cells.
Dilutions of SBL and SBB were prepared from 1500 to 5.85 μg/mL in another 96-well plate and added to the well plates that had the preformed biofilms. This was further incubated for 24 h at 37°C. Afterwards, the media in the wells were aspirated carefully and the plate washed two times with 100 μL PBS. XTT/menadione solution (100 μL) was added to each well, and the plates were incubated at 37°C for 2 h in the dark. Afterwards, 80 μL of the resulting supernatant from the wells was transferred into a new microplate which was measured at 490 nm on a microplate reader [43].
Percentage inhibitions in both assays were determined as %Inhibition = Absorbance of control -Absorbance of treatment Absorbance of control × 100: The absorbances were analyzed with GraphPad for Windows version 8 (GraphPad Prism Software, San Diego, USA). The experiment was also replicated thrice in both assays.
2.6. Phytochemical Investigations 2.6.1. Characterization of Extracts by UPLC-ESI-QTOF-MS/ MS. The phytochemical characterization of SBL and SBB extracts was carried out following a procedure previously described in the literature with some modifications [44]. The separation was performed with a UHPLC Dionex Ultimate 3000 RS Liquid Chromatography System, on a C18 column (2:1 × 100 mm, 2.2 μm) with a binary gradient (A: water with 0.1% formic acid; B: acetonitrile with 0.1% formic acid) at 0.4 mL/min at an injection volume of 2 μL: from 0 to 0.4 min-isocratic at 5% B; 0.4 to 9.9 min-linear from 5% B to 100% B; 9.9 to 15.0 min-isocratic at 100% B; 15.0 to 15.1 min-linear from 100% B to 5% B; and 15.1 to 20.0 min-isocratic at 5% B.
The eluted compounds were detected with Dionex Ultimate DAD-3000 RS over wavelength of 200-400 nm and Bruker Daltonics micrOTOF-QII time-of-flight mass spec-trometer with an Apollo electrospray ionisation source in a positive mode at 3 Hz over a mass range of m/z 50-1500 using the instrument settings: dry gas nitrogen, 9 L/min, 220°C; nebulizer gas nitrogen, 4 bar; capillary voltage, 4500 V; end plate offset, -500 V; transfer time, 100 μs; collision gas nitrogen; collision energy; and collision RF settings were combined to each single spectrum of 1250 summations as follows: 624 summations with 80 eV collision energy and 130 Vpp + 313 summations with 16 eV collision energy and 130 Vpp + 313 summations with 16 eV collision energy and 130 Vpp. Internal dataset calibration (HPC mode) was done for each analysis with the mass spectrum of a 10 mM solution of sodium formate in 50% isopropanol that was infused during LC reequilibration using a diverter valve equipped with a 20 μL sample loop. Waters Acquity UPLC® HSS T3 (2.1 × 100 mm, 1.8 μm); Empower 3 Software; a binary solvent manager with a flow rate: 0.5 mL/min, and mobile phases: A: H 2 O+ 0.1% formic acid, B: CH 3 CN+ 0.1% formic acid in a gradient elution format. With a run time of 13 minutes, the elution system of SBL was as follows: 0-1 min, 98%-90% A; 1-2 min, 90% A; 2-4 min 90%-85% A; 4-10 min, 85% A; 10-11 min, 85%-0% A; 11-12 min, 0%-98% A; and 12-13 min, 98% A. For SBB, the elution system was also as follows: 0-1 min, 0% A; 1-10 min, 0%-5% A; 10-15 min, 5% A; 15-16 min, 5%-10% A; and 16-22 min, 10% A. The run time for SBB was 22 minutes. The chromatograms of SBL and SBB extracts were recorded at 330 nm and 280 nm, respectively. The compounds present were then confirmed from the corresponding mass spectral data to the peaks observed. For qualitative purposes, the relative retention times (RRT) and relative peak areas (RPA) of the prominent UV-absorbing phytoconstituents observed in the chromatograms were calculated, in reference to internal standards, which also form part of the constituents of the extracts. Peaks corresponding to rutin and gallic acid in SBL and SBB, respectively, were designated as internal standards.
The fingerprints were then validated following the ICH Q2 (R1) guidelines [45]. The parameters considered included specificity, precision, and stability. Specificity was evaluated by identifying the key constituents in the extracts though their mass spectral data generated and spiking with reference compounds. Rutin and isoquercitrin were used as references for SBL extracts, whereas gallic acid and procyanidin B2 were used for SBB. Precision parameters, including repeatability and intermediate precision, were investigated by observing the RRTs and RPAs of five of the prominent peaks from replicate analysis of the extracts on same and different days. The relative standard deviations were then determined. The stability of the fingerprints was determined over a 48-hour period at predetermined time intervals (0, 6, 12, 24, and 48 hours). The percentage change in the relative peak areas of selected marker compounds (SBL-isoquercitrin; SBB-procyanidin B2) was then monitored.

Antifungal Activity of S. Birrea Leaves and Stem Bark
Extracts. The 70% ethanol leaf and stem bark extracts of S. birrea demonstrated moderate to strong antifungal activities against the C. albicans strains with MICs from 12.21 to 97.66 μg/mL and MFCs 12.21 to 390.63 μg/mL. The overall anti-C. albicans activity of the stem bark extract (SBB), however, was higher than the leaf extract (SBL) ( Table 1). Except for the susceptible strains ATCC 90028 and SC5314, all the tested strains of C. albicans showed resistance to fluconazole. Voriconazole demonstrated variable inhibitory activities on the C. albicans strains (MIC = 4-16 μg/mL).

Effect of S. birrea Leaf and Stem Bark Extracts on the
Antifungal Activity of Conventional Antifungal Agents. The activity of fluconazole, nystatin, and caspofungin in combination with SBL or SBB against the C. albicans strains was investigated in the checkerboard assay. As seen in Table 2, after determining the respective FICIs, majority of the combinations of the extracts with the conventional antifungals showed indifference with occasional demonstration of synergism. Generally, SBL exhibited more synergistic interactions with the antifungal agents than SBB. However, SBB demonstrated more synergistic interactions with nystatin against the C. albicans strains.

Effect of S. birrea Leaf and Stem Bark Extracts on the
Biofilms of C. albicans Strains. The activity of S. birrea leaf and stem bark hydroethanolic extracts against the biofilms of the C. albicans strains was examined under two experimental modalities. The first assay evaluated the tendency of the extracts to inhibit biofilm formation whereas the second assessed the activity of the extracts against preformed biofilms. As observed in Table 3, the preformed biofilms were more resistant to the extracts compared to the planktonic cells recording IC 50 ranging from 91.50 to 685.20 μg/ mL. On the other hand, SBL and SBB demonstrated strong antibiofilm formation activity with IC 50 from 12.49 to 164.42 μg/mL. Generally, the SBB demonstrated higher activity against the biofilms of the C. albicans strains than SBL.

Phytochemical Characterization of the Extracts.
The analysis shows the predominance of simple phenolic and polyphenolic compounds in both leaves and stem bark of the plants (Figure 1). SBL was observed to contain flavonoids like rutin, quercetin, isoquercetin, myricetin 3-O-α-L-rhamnopyranoside, and phloretin-c-glucoside. Caffeic acid, ferulic acid, galloylated quinic acid, and dimers of catechins and/or epicatechins were also observed. In the SBB, epicatechin monomers with their condensed tannins, including procyanidin B2, procyanidin C trimer isomer, and procyanidin B2 3-O-gallate, were detected in addition to the flavonoids and others. The phytochemical profiles of ethanolic extracts of SBL and SBB are shown in the supplementary data.

Fingerprint
Profiling of SBL and SBB. The fingerprints of SBL and SBB are shown in Figure 2. SBL fingerprint showed the presence of flavonoids like rutin, isoquercitrin, and myricetin-3-O-α-L-rhamnopyranoside among others. In the fingerprint of SBB, however, gallic acid and dimers and trimers of condensed tannins like procyanidin B2, B5, and C trimer were observed. The identities of these compounds present as peaks in the fingerprint were confirmed from their retention times and their associated UV and mass spectra. The RRTs and RPAs (Table 4) were shown to be precise from both repeatability and intermediate precision analyses (Table 5). The RPAs were also stable beyond 48 hours of standing of the test solutions. These outcomes indicate that the fingerprints developed and validated were suitable preliminary qualitative tools to authenticate the plant and its parts for medicinal use.

Discussion
The current study investigated the antifungal potential of the hydroethanolic extracts of S. birrea leaves (SBL) and stem bark (SBB) against fluconazole-resistant C. albicans strains and clinical isolates recovered from pregnant women with vulvovaginal candidiasis. SBB demonstrated strong antifungal activity (MIC = 12:21-48.83 μg/mL) against the C. albicans strains whereas SBL exhibited strong to moderate activity (MIC = 12:21-97.66 μg/mL). The MFCs of the extracts against the same set of strains were also evaluated. As observed from Table 1, higher concentrations of the extracts (MFC = 48:83 to 390.63 μg/mL) are needed to exert fungicidal activity against the C. albicans strains and isolates. The results, however, are noteworthy as the emergence of resistance has become a significant clinical challenge that limits the successful treatment of Candida infections. Indeed, there has been an increase in the number of patients suffering from recurrent VVC in the last few decades which  [46]. The observed activity of the leaves and stem bark of S. birrea against the fluconazole-resistant strains and isolates, which is being reported for the first time in this study, suggests that the leaves and stem bark of S. birrea are a promising alternative for treating C. albicans infections including those that may fail standard therapy and are potentially great sources of bioactive compounds that can be developed into novel antifungal agents that may overcome the challenge of resistance.
The low MICs recorded for the extracts suggests that they could be used together with conventional antifungals for the development of combinatorial therapies. The advantage being that these plant extracts if used together with current available antifungals, both at lower doses, could result in increased activity coupled with a decrease in their adverse effects. Studies have also shown that plant extracts, particularly those with antifungal activities, require high concentrations to be effective which might prove toxic to human health [47]. Additionally, combining antifungals with different mechanisms of action has been shown to be an innovative approach to overcoming the spread of fungal resistance [48]. Hence, we investigated the antifungal combination activity of SBL and SBB with fluconazole, nystatin, and caspofungin, as representatives of each class of antifungal agents: azoles, polyenes, and echinocandins, by the broth microdilution checkerboard assay. Investigations of the combination of SBL with the antifungals yielded mixed results, depending on the antifungal and the C. albicans strain or isolate tested. The predominant interaction observed in the C. albicans strains was indifference; however, synergism was also observed in some of the C albicans isolates. On the other hand, majority of combinations of SBB with the antifungal drugs demonstrated indifference, with the prominent exemption of the combinations with nystatin, which resulted in synergism in 75% of the tested strains and isolates. It has been hypothesized that synergism in antifungal combinations is expected when the evaluated antifungals have uniquely different mechanisms of action [41]. Thus, SBB may contain compounds which possess a mechanism of antifungal action different from nystatin, which is the disruption of the cell membrane via the binding to ergosterol in the fungal cell wall and the subsequent changes in cell permeability [49]. SBB, as shown from the phytochemical investigations, contained mostly proanthocyanidins, their galloylated derivatives, and flavonoids (Table S2) as compared to predominance of flavonoids in SBL. Flavonoids, such as rutin, quercetin, myricetin, kaempferol, and epigallocatechin gallate among others, have been shown to be effective against Candida species [50]. They are reported to exert this effect by inhibiting efflux pumps and inducing apoptosis, damaging cell walls, and disrupting cell membrane [51].
Similarly, proanthocyanidins and their galloylated derivatives also possess antifungal effects against Candida species [52], by inhibiting NF-кB p65 activation and subsequent phosphorylation of specific signal intracellular kinases [53]. The relatively different mechanisms by which these compounds exert their effect as compared to the conventional drugs may contribute to the synergistic effects observed in some instances. Also, the presence of the proanthocyanidins and their galloylated derivatives in addition to the flavonoids in SBB could be thought to Table 2: Effect of S. birrea leaf and stem bark extracts in combination with fluconazole, nystatin, or caspofungin against C. albicans strains. Combinations  SBL  SBB  FLC  NYS  CSF  FLC  NYS  CSF  FICI  INT  FICI  INT  FICI  INT  FICI  INT  FICI  INT  FICI  INT   ATCC   The ability to form biofilms is critical to the pathogenicity and the development of fungal resistance which can decrease the sensitivity of C. albicans to currently used antifungals up to a thousand times than planktonic cells [54].

Strains
Therefore, the search for anti-C albicans biofilms has become a pressing need. The activity of SBL and SBB against the preformed biofilms as well as their tendencies to inhibit biofilm formation of the C. albicans strains and isolates was evaluated in the study. As expected, greater concentrations (3-14 folds) of the extracts were needed to inhibit the preformed biofilms than those required to inhibit biofilm

7
BioMed Research International formation. Although this is the first report of the activity of S. birrea against Candida biofilms, the plant had previously been shown to exert antibiofilm activity in bacteria. The methanol extract of S. birrea stem bark demonstrated a concentration-dependent antibiofilm formation activity in Pseudomonas aeruginosa with a maximum inhibition of 87.45% at 200 μg/mL [55]. The effects against the biofilm formation as well as disruption of preformed biofilms were also seen to be better in SBB than SBL, and this could also be because of the proanthocyanidins present [52,53].
The observed antifungal activities of S. birrea may therefore be because of flavonoids and proanthocyanidins and their derivatives present in SBL and SBB working synergistically, additively, and/or in a potentiation manner to contribute to the overall activity of the plant.
Whereas Hamza et al. [33] demonstrated that the root bark of the plant has antifungal activity against susceptible strains of Candida species, we, in this study, have shown that the leaves and stem bark of the plant possess antifungal action against resistant strains and isolates of C. albicans, the major causative agent of candidiasis. The use of the leaves and stem bark will promote sustainable use of the plant and would therefore recommend their usage rather than the roots, in traditional preparations and in the herbal industry to conserve the plant.
The proposed analytical conditions reported herein are suitable for the preliminary quality assessment of the leaves and stem bark of the plant either for traditional use or their use in herbal medicine manufacture. While the RRTs provide valuable qualitative information to assess the presence  Figure 2: Representative UPLC fingerprint profiles for SBL (a) and SBB (b) extracts of S. birrea. The fingerprints show the prominent peaks used to identify the extracts together with their internal reference markers. In SBL, the following compounds were identified: galloyl shikimic acid [2], hydroxy-methoxyphenyl-O-galloyl-glucopyranoside [3], myricetin 3-O-α-L-rhamnopyranoside [8], rutin [9], isoquercetin [10], and quercetin 3-O-α-L-rhamnopyranoside [11]. In the SBB extract, the compounds identified included gallic acid [1], procyanidin B2 [4], procyanidin B5 [5], procyanidin B2 3-O-gallate [7], and procyanidin C trimer isomer [8]. 0.5426 * Peak numbers used to illustrate the compounds in the chromatograms for SBL and SBB do not necessarily correspond to similar compounds in the two extracts. αCompound 1 identified as gallic acid was used as an internal reference marker for SBB extract. βCompound 9 identified as rutin was used as an internal reference marker for SBL extract. 8 BioMed Research International of the annotated peaks in the extracts, their RPAs provide semiquantitative information which can be used to estimate the contents of the respective peaks [56]. The outcome of the validation also indicates the reliability of the fingerprints to generate reproducible information. The UPLC fingerprints developed and validated can therefore be used in their entirety or by way of verifiable constituent marker compounds (using their RRTs and RPAs) to verify the authenticity of a sample of either of the parts investigated. However, more UPLC fingerprints should be developed from 70% ethanol extracts of the leaves and stem bark of S. birrea collected from different geographical location and seasons to further confirm the results.

Conclusion
We report, for the first time, the antifungal activity of the leaves and stem bark hydroethanolic extracts of S. birrea against fluconazole-resistant strains and isolates of C. albicans. The extracts demonstrated considerable antifungal activity and significantly inhibited biofilm formation activity of the C. albicans strains and isolates. They also inhibited considerably the activity of preformed biofilms of the resistant strains and isolates and demonstrated potential for their use as combination therapies with currently used antifungals especially the stem bark extract with nystatin. These effects may be due to the presence of flavonoids, proanthocyanidins, and their galloylated derivatives confirmed in the extracts. Additionally, analytical conditions have been proposed for UPLC fingerprint profiling, and this could be used to verify the authenticity of the leaves and stem barks of S. birrea.

Data Availability
All available data are included in the manuscript and supplementary data.

Conflicts of Interest
The authors declare no conflict of interest.

Authors' Contributions
BKH, DN, and AMQ conceived and designed the research study. DN and AMQ were the main field investigators. EO and CDKA were responsible for HPLC characterization and identification of constituents of the extracts. BKH, DN, NAM-G, and MOA assessed the data and prepared the original manuscript. TCF and JJ were involved in manuscript preparation and proof read the final manuscript. All authors read and approved the final version of the manuscript.