https://orcid.org/0000-0001-9271-6927
Abstract
Context
Pseudocedrela kotschyi (Schweinf) Harms (Meliaceae) is an important medicinal plant found in tropical and subtropical countries of Africa. Traditionally, P. kotschyi is used in the treatment of various diseases including diabetes, malaria, abdominal pain and diarrhoea.
Objective
To provide an overview of traditional medicinal claims, pharmacological properties, and phytochemical principles of P. kotschyi as a basis for its clinical applications and further research and development of new drugs.
Methods
Through interpreting already published scientific manuscripts retrieved from different scientific search engines, namely, Medline, PubMed, EMBASE, Science Direct and Google scholar databases, an up-to-date review on the medicinal potentials of P. kotschyi from inception until September, 2020 was compiled. ‘Pseudocedrela kotschyi’, ‘traditional uses’, ‘pharmacological properties’ and ‘chemical constituents’ were used as search words.
Results
At present, more than 30 chemical constituents have been isolated and identified from the root and stem bark of P. kotschyi, among which limonoids and triterpenes are the main active constituents. Based on prior research, P. kotschyi has been reported to possess anti-inflammatory, analgesic, antipyretic, anthelminthic, antimalaria, anti-leishmaniasis, anti-trypanosomiasis, hepatoprotective, antioxidant, antidiabetic, antidiarrheal, antimicrobial, and anticancer effects.
Conclusions
P. kotschyi is reported to be effective in treating a variety of diseases. Current phytochemical and pharmacological studies mainly focus on antimalaria, anti-leishmaniasis, anti-trypanosomiasis and anticancer potential of the root and stem bark of P. kotschyi. Although experimental data support the beneficial medicinal properties of this plant, there is still a paucity of information on its toxicity profile. Nonetheless, this review provides the basis for future research work.
Introduction
Traditional medicinal plants have been an essential source of remedy for various illnesses since ancient times. Preparations of plant materials such as infusion, decoction, powder, or paste have been used in various traditional practices in different parts of the world. People living in Africa and Asia make use of herbal medications to supplement the conventional medicine practice (Ekor Citation2014). There has been an increasing interest in the usage of herbal medicines in recent years. About 80% of the world’s population is using phytotherapeutic medicines (Balekundri and Mannur Citation2020). The WHO estimated that the size of the global market for herbal products was USD 60 billion in the year 2000 and this is expected to grow 7% per annum towards USD 5 trillion by the year 2050 (Tan et al. Citation2020). Several analyses have clearly verified traditional claims of numerous medicinal plants leading to the commercialisation of the many herbal products and their nomination as leads within the development of pharmaceutical medication (Williams Citation2021). Many clinically useful drugs have been discovered based on the knowledge derived from the ethnomedicinal applications of various herbal materials (Balunas and Kinghorn Citation2005).
Pseudocedrela kotschyi (Schweinf.) Harms (Meliaceae) is an important medicinal plant found in the tropical and subtropical countries of Africa. This plant has been extensively used in the African traditional medicine system for the treatment of a variety of diseases, particularly as analgesic, antimicrobial, antimalarial, anthelminthic, and antidiarrheal agents. The main focus of this review was to establish the ethnopharmacological uses and medicinal characteristics of P. kotschyi and highlight its potential as future drug for the treatment of various tropical diseases.
Methodology
Scientific manuscripts on P. kotschyi were retrieved from different scientific search engines. Literature search was carried out on PUBMED using Pseudocedrela kotschyi as key words. Additional literature searches on Medline, EMBASE, Science Direct and Google scholar databases were done using pharmacological activity, chemical constituents and traditional uses of Pseudocedrela kotschyi as search terms. Literature published on the topic in English language from inception until September, 2020 were collected, analysed and an up-to-date review on the medicinal potential of P. kotschyi was compiled.
Geographical distribution
P. kotschyi (common name: dry zone cedar) is a medicinal plant. Other common names of P. kotschyi are Tuna (Hausa) and Emi gbegi in Yoruba. It is found in tropical and subtropical countries of Africa which include Nigeria, Cote d’Ivoire, Senegal, Ghana, Democratic Republic of Congo, and Uganda. The plant often grows as a medium sized tree of about 12–20 ft high (Ayo et al. Citation2010; Alain et al. Citation2014; Alhassan et al. Citation2014). Below is the taxonomical classification of P. kotschyi (Hassler Citation2019).
Classification
Kingdom Plantae
Phylum Tracheophyta
Class Magnoliopsida
Order Sapindales
Family Meliaceae
Genus Pseudocedrela
Species kotschyi
Ethnomedicinal uses
Different parts of P. kotschyi are used in the traditional treatment of various diseases. The root is used in the treatment of leprosy (Pedersen et al. Citation2009), epilepsy, dementia (Kantati et al. Citation2016), diabetes (Salihu Shinkafi et al. Citation2015), malaria, abdominal pain, diarrhoea (Ahua et al. Citation2007), toothache and gingivitis (Tapsoba and Deschamps Citation2006). The root is also used as a chewing stick for tooth cleaning and enhancement of oral health (Wolinsky and Sote Citation1984; Olabanji et al. Citation2007; Adeniyi et al. Citation2010). The leaf is used in the treatment of female infertility (Olabanji et al. Citation2007), intestinal worms (Koné et al. Citation2005) and malaria (Asase et al. Citation2005). The stem bark is used in the treatment of cancer (Saidu et al. Citation2015), infantile dermatitis (Erinoso et al. Citation2016), stomach ache (Asase et al. Citation2005), toothache (Kayode and Sanni Citation2016), high blood-pressure, skin diseases, and haemorrhoids (Nadembega et al. Citation2011).
Phytochemistry
Phytochemical investigations revealed that P. kotschyi contains a variety of pharmacological active secondary metabolites. A total of 32 compounds have so far reported to have been isolated from the plant which mainly include limonoids, triterpenes, and flavonoids.
Limonoids are modified triterpenes which are highly oxygenated and have a typical furanylsteroid as their core structure (Roy and Saraf Citation2006). They are also known as tetraterpenoids. Limonoids are rare natural products which occur mainly in plants of Meliaceae and Rutaceae families and less frequently in the Cneoraceae family (Tan and Luo Citation2011).
Several phragmalin-type limonoid orthoacetates () have reportedly been isolated from the of roots of this plant, namely, kotschyins A–H (1–8) (Hay et al. Citation2007; Dal Piaz et al. Citation2012). These compounds are complex with a very high degree of oxidation and rearrangement as compared to the parent limonoid structure.
Figure 1. Phragmalin-type limonoid orthoacetates isolated from the roots of P. kotschyi.
Other limonoid derivatives () found in the roots and stem bark of P. kotschyi are 7-deacetylgedunin (9), 7-deacetyl-7-oxogedunin (10) (Hay et al. Citation2007), 1α,7α epoxy-gedunin (11), gedunin (12) (Dal Piaz et al. Citation2012), kostchyienones A (13) and B (14), andirobin (15) methylangolensate (16) (Sidjui et al. Citation2018). Additional limonoids derivatives () that were isolated from the P. kotschyi bark include pseudrelones A–C (17–19) (Taylor Citation1979). The pseudrelones also have a phragmalin nucleus with orthoacetate function but they have a lesser degree of oxidation than the kotschyins.
Figure 2. Limonoid derivatives isolated from the roots of P. kotschyi.
Figure 3. Limonoid derivatives isolated from the bark of P. kotschyi.
The steroids isolated from this plant () include odoratone (20), spicatin (21), 11-acetil-odoratol (22) (Dal Piaz et al. Citation2012), β-sitosterol (23), 3-O-β-d-glucopyranosyl β-sitosterol (24) stigmasterol (25), 3-O-β-d-glucopyranosyl stigmasterol (26) betulinic acid (27) (Sidjui et al. Citation2018). Three secotirucallane triterpenes were also isolated from the stem bark of P. kotschyi. These include, 4-hydroxy-3,4-secotirucalla-7,24-dien-3,21-dioic acid (28), 3,4-secotirucalla-4(29),7,24-trien-3,21-dioic acid (29) and 3-methyl ester 3,4-secotirucalla-4(28),7,24-trien-3,21-dioic (30) () (Mambou et al. Citation2018). Two flavonoids, namely, 3,6,8-trihydroxy-2-(3,4-dihydroxylphenyl)-4H-chrom-4-one (31) and quercetin, 3,4′,7-trimethyl ether (32) () have also been isolated from the roots of this plant (Sidjui et al. Citation2018).
Figure 4. Triterpenes and flavonoids isolated from the roots of P. kotschyi.
The GCMS analysis of essential oils from root and stem of P. kotschyi indicated that both oils contain mainly sesquiterpenoids. These include, α-cubebene, α-copaene, β-elemene, β-caryophyllene, trans-α-bergamotene, aromadendrene, (E)-β-farnesene, α-humulene, allo-aromadendrene, γ-muurolene, farnesene, germacrene D, β-selinene, α-selinene, α-muurolene, γ-cadinene, calamenene, δ-cadinene, cadina-1,4-diene, α-calacorene, α-cadinene, β-calacorene, germacrene B, cadalene, epi-cubebol, cubebol, spathulenol, globulol, humulene oxide II, epi-α-cadinol, epi-α-muurolol, α-muurolol, selin-11-en-4-α-ol, α-cadinol and juniper camphor. The stem bark oil was found to comprise largely of sesquiterpene hydrocarbons (79.6%), with δ-cadinene (31.3%) as the major constituents. While the oxygenated sesquiterpenes were found to be abundant in the root with cubebols (32.5%) and cadinols (17.9%) as the major constituents (Boyom et al. Citation2004).
Pharmacological activity
The ethnomedicinal claims for the efficacy of P. kotschyi in the treatment of various diseases have been confirmed by numerous relevant scientific studies. Several pharmacological investigations have been carried out to confirm the traditional medicinal uses of the roots, stem bark, and leaves of P. kotschyi. A wide range of pharmacological activities such as analgesic, antipyretic, anthelminthic, antimalaria, anti-leishmaniasis, hepatoprotective, antioxidant, and antimicrobial, have been reported by researchers so far.
Anti-inflammatory, analgesic and antipyretic activities
Inflammation is an adaptive response that is triggered by noxious stimuli or conditions, such as tissue injury and infection (Medzhitov Citation2008; Ahmed Citation2011). Inflammatory response involves the secretion of several chemical mediators and signalling molecules such as nitric oxide (NO), and proinflammatory cytokines, including tumour necrosis, factor-α (TNF-α), interferon-γ (IFNγ), lipopolysaccharides (LPS) and interleukins (Medzhitov Citation2008). Even though inflammatory response is meant to be a beneficial process of restoring homeostasis, it is often associated with some disorders like pain and pyrexia due to the secretion of the chemical mediators (Bielefeldt et al. Citation2009; Garami et al. Citation2018). Chronic secretion of proinflammatory cytokines is also associated with development of diseases such as cancer and diabetes. Hence, anti-inflammatory agents represent an important class of medicines. Extracts and phytoconstituents of P. kotschyi have been reported to possess anti-inflammatory, analgesic and antipyretic properties.
The administration of methanol crude extract of P. kotschyi stem bark at a dose of 200 mg/kg/day and its butanol and chloroform fractions have been shown to produce significant analgesic activity when evaluated with a mice model. The extracts and fractions decreased the number of writhes by 88–92% during the acetic acid induced writhing assay (Abubakar et al. Citation2016). Akuodor et al. (Citation2013) investigated the antipyretic activity of ethanol extract of P. kotschyi leaves on yeast and amphetamine induced hyperpyrexia in rats. They reported that the leaf extract (50, 100 and 150 mg/kg i.p.) displayed a significant (p < 0.05) dose-dependent decrease in pyrexia.
Scientific investigations have shown that 7-deacetylgedunin (9) had significant anti-inflammatory activity. Compound 9 was reported to significantly inhibit lipopolysaccharide induced nitric oxide in murine macrophage RAW 264.7 cells with an IC50 of 4.9 ± 0.1 μM. It also produced the downregulation of mRNA and protein expression of inducible nitric oxide synthase (iNOS) at a dose of 10 µM (Sarigaputi et al. Citation2015). These findings suggest that compound 9 produces its anti-inflammatory effect through the modulation of NO production. Chen et al. (Citation2017) investigated the anti-inflammatory activity of compound 9 in C57BL/6 mice. Their result showed that its intraperitoneal administration at a dose of 5 mg/kg body weight for two consecutive days significantly decreased LPS-induced mice mortality by 40%. The above findings demonstrate that compound 9 is a promising anti-inflammatory agent from this plant. The anti-inflammatory effect of this compound perhaps accounts for the analgesic and antipyretic properties of the P. kotschyi extracts.
Antiparasitic activity
Parasitic diseases are among the foremost health problems today, especially in tropical countries of Africa and Asia. Diseases such as malaria, leishmaniasis, trypanosomiasis and helminthiasis affect millions of people each year causing high morbidity and mortality, particularly, in developing countries (Hotez and Kamath Citation2009). Hence, there is an urgent need for new drugs to treat and control of these diseases.
Extracts obtained from different parts of P. kotschyi have been reported to possess activity against several human parasites. Ahua et al. (Citation2007) investigated the anti-leishmaniasis activity of P. kotschyi including several other plants against Leishmania major. The dichloromethane extract of P. kotschyi roots (at a dose of 75 µg/mL) exhibited a marked activity (>90% mortality) against the intracellular form of the parasite which is pathogenically significant for humans.
In another study, the anthelminthic activity of an ethanol extract of P. kotschyi roots against Haemonchus contortus (a pathogenic nematode found in small ruminants) was evaluated. The researchers discovered that the ethanol extract possessed larvicidal activity against the helminth with a LC100 of 0.02 µg/mL (Koné et al. Citation2005). The aqueous stem bark extract of this plant (50 mg/mL) has also been demonstrated to exert anthelminthic activity against Lumbricus terrestris with 25.4 min death time (Ukwubile et al. Citation2017).
The antimalarial effect of P. kotschyi on malaria parasite has been reported in several research manuscripts. Christian et al. (Citation2015) investigated the suppressive and curative effect of ethanol extract of P. kotschyi leaves against malaria in Plasmodium berghei berghei infected mice. The results obtained showed that oral administration of the extract (100–400 mg/kg/day) exhibited a significant antimalarial effect which is evident by the suppression of parasitemia and prolong life of infected animals. In an another study, methanol extract of the P. kotschyi leaves at an oral dose of 200 mg/kg/day was found to reduce parasitemia by 90.70% in P. berghei berghei infected mice after four consecutive days of treatment (Dawet and Stephen Citation2014). However, the ethanol and aqueous extracts of the P. kotschyi stem bark exhibited lower activity against the malaria parasite (39.43% and 28.36% reduction in parasitemia, respectively) (Dawet and Yakubu Citation2014).
The limonoid derivatives 9 and 10 were reported to display significant in vitro activity against chloroquine-resistant Plasmodium falciparum with IC50 values of 1.36 and 1.77 µg/mL, respectively (Hay et al. Citation2007). The two compounds also displayed significant antiparasitic activity against Leishmania donovani, Trypanosoma brucei rhodesiense with a low-range IC50 of 0.99–3.4 µg/mL. In contrast, the orthoacetatate kotschyin A was found to be inactive against all the tested parasites (Hay et al. Citation2007). In related work, Sidjui et al. (Citation2018) evaluated the in vitro antiplasmodial activity of 14 compounds isolated from P. kotschyi. Their findings showed that the limonoid derivatives 9, 10, 13, 14 and 15 exhibited very significant activity against both chloroquine-sensitive (Pf3D7) and chloroquine-resistant (PfINDO) strains of genus Plasmodium with IC50 values ranging from 0.75 to 9.05 µg/mL.
Steverding et al. (Citation2020) investigated the trypanocidal and leishmanicidal activities of six limonoids, namely, 9, 10, 13, 14, 15 and 16, against bloodstream forms of Trypanosoma brucei and promastigotes of Leishmania major. All the six compounds showed anti-trypanosomal activity with IC50 values ranging from 3.18 to 14.5 µM. Compounds 9, 10, 13 and 14 also displayed leishmanicidal activity with IC50 of 11.60, 7.63, 2.86 and 14.90 µM, respectively, while 15 and 16 were inactive.
The antiplasmodial, trypanocidal, and leishmanicidal activities of these compounds provide justification for the use of crude extract of P. kotschyi in the traditional treatment of malaria and other parasitic infectious diseases.
Antimicrobial activity
Antimicrobial agents are among the most commonly used medications. The prevalence of antimicrobial resistance in recent years has led to a renewed effort to discover newer antimicrobial agents for the treatment of infectious diseases (Hobson et al. Citation2021). Extracts of P. kotschyi were reported to display appreciable activity against some pathogenic microorganisms.
Ayo et al. (Citation2010) investigated the antimicrobial activity of petroleum ether, ethyl acetate and methanol extracts of the P. kotschyi leaves against Staphylococcus aureus, Salmonella typhi, Streptococcus pyogenes, Candida albicans, and Escherichia coli. The results of the study showed that the ethyl acetate extract exhibited antibacterial activity against all the tested organisms with MIC values of 10–20 mg/mL. In an another similar study, the crude methanol extract of the stem bark of this plant was also shown to exhibit good activity against a panel of pathogenic bacteria and fungi which include methicillin-resistant S. aureus (MRSA), S. aureus, S. pyogenes, Corynebacterium ulcerans, Bacillus subtilis, E. coli, S. typhi, Shigella dysenteriae, Klebsiella pneumoniae, Neisseria gonorrhoeae, Pseudomonas aeruginosa, C. albicans, C. krusei, and C. tropicalis with MIC values of 3.75–10.0 mg/mL (Alhassan et al. Citation2014). The methanol extract of the woody stem was also found to possess antifungal activity against C. krusei ATCC 6825 with an MIC of 6.25 mg/mL (Adeniyi et al. Citation2010).
The secotirucallane triterpenes (compounds 28, 29 and 30) isolated from the bark of P. kotschyi have been reported to possess significant antibacterial activity against Staphylococcus aureus ATCC 25923), Escherichia coli S2(1) and Pseudomonas aeruginosa with MIC ranging from 6 to 64 µg/mL. Compound 29 exhibited the highest antibacterial activity while 30 had the lowest (Mambou et al. Citation2018). The presence of these compounds is likely responsible for the antimicrobial property of P. kotschyi extracts and justify the ethnomedicinal use of this plant as a chewing stick for tooth cleaning and enhancement of oral health.
Antioxidant and hepatoprotective activities
The ethanol extract of P. kotschyi stem bark has been reported to possess DPPH radical scavenging activity with an IC50 of 4 µg/mL (Alain et al. Citation2014).
A study on the hepatoprotective activity of methanol and aqueous extracts of the P. kotschyi leaves revealed that both extracts (at a dose of 750 mg/kg/day) were able to protect the liver against paracetamol induced oxidative damage (Eleha et al. Citation2016). A similar study conducted by Nchouwet et al. (Citation2018) showed that 2 weeks pre-treatment with aqueous and methanol extracts of P. kotschyi stem bark (150 mg/kg/day) significantly suppressed the development of paracetamol induced hepatotoxicity in experimental rats.
Hypoglycaemic and digestive enzyme inhibitory activities
Diabetes mellitus is disorder associated with abnormal glucose metabolism resulting from insulin insufficiency or dysfunction. It is one of the major non-communicable diseases that affect millions of people globally. Scientific investigation has revealed that P. kotschyi extracts possess some antidiabetic properties. Georgewill and Georgewill (Citation2019) investigated the hypoglycaemic effect of aqueous extract of P. kotschyi leaves on alloxan induced diabetic rats. Results of their investigation revealed that oral administration of the extract (200 mg/kg/day for 14 days) caused significant hypoglycaemic effect in the experimental animals. The ethanol extract of roots of this plant was also reported to exhibit inhibitory activity against α-glucosidase (IC50 = 5.0 ± 0.2 μg/mL), an important digestive enzyme targeted in diabetes treatment (Bothon et al. Citation2013).
Antiproliferative activity
Cancer is an important disease that is characterised by the abnormal rapid proliferation of cells that invade and destroy other tissues (Alhassan et al. Citation2018). It is a major public health problem throughout the world. Pharmacological studies have shown that P. kotschyi possesses anticancer potential.
Kassim et al. (Citation2015) investigated the antiproliferative activity and apoptosis induction effect of aqueous extract of P. kotschyi roots against a panel of prostate cancer cell lines, namely, PC3, DU-145, LNCaP and CWR-22 cell lines. Results from the 3-[4,5-dimethylthiazol-2yl]-2,5-diphenyltetrazolium bromide (MTT) assay showed that all four cancer cell lines exhibited a dose-dependent decrease in cell proliferation and viability after treatment with the aqueous extract with IC50 values ranging from 12 to 42 µg/mL. The results obtained also showed that LNCaP, PC3, DU-145, and CWR-22 cell lines had 42, 35, 33 and 24% induced apoptotic cells, respectively, after treatment with the same extract. The results of both the antiproliferative and apoptosis assay indicated that the LNCaP cells were the most sensitive to the P. kotschyi extract.
Heat shock protein 90 (Hsp90) is a molecular chaperone that is involved in the folding, activation and assembly of several proteins including oncoproteins such as HER2, Survivin, EGFR, Akt, Raf-1, mutant p53 (Calderwood et al. Citation2006; Dal Piaz et al. Citation2012). Hsp90 is often overexpressed in cancer cells. It has been demonstrated to play a vital role in tumour progression, malignancy and resistance to chemotherapeutic agents (Zhang et al. Citation2019). Hence, Hsp90 is recently considered as a viable molecular target for development of new anticancer drugs (Gupta et al. Citation2019). Phytoconstituents of P. kotschyi have been shown to possess significant Hsp90 inhibitory activity. Dal Piaz et al. (Citation2012) investigated the Hsp90 binding capability of several compounds using a surface plasmon resonance (SPR) approach. They found that the limonoid orthoacetates (1–6) displayed good binding capability to the protein with compound 4 being the most effective. Compound 4 also exhibited significant anti-proliferative activity against three cancer cell lines, namely, PC-3 (human prostate cancer cells), A2780 (human ovarian carcinoma cells), and MCF-7 (human breast adenocarcinoma cells) with IC50 values of 62 ± 0.4, 38 ± 0.7 and 25 ± 1.2 µM, respectively. These findings suggest that Hsp90 inhibition is a mechanism of action for anti-proliferative effects of the limonoids orthoacetates from P. kotschyi. These findings provide scientific bases for the future development of new anticancer agents from P. kotschyi in the form of a standardised herbal preparation or as a pure chemical entity.
Antidiarrheal activity
Treatment of diarrhoea comes under one of the common ethnomedicinal uses of P. kotschyi. To further verify this claim, Essiet et al. (Citation2016) investigated the antidiarrheal property of ethanol extract of P kotschyi leaves in Wistar albino rats. Diarrhoea was induced in the animals using castor oil. Results of the investigation revealed that oral administration of the extract (100, 200 and 400 mg/kg) produced significant (p < 0.05) dose-dependent inhibition of induced diarrhoea (67–91%). The results also showed that the administered doses of the extract decreased intestinal transit time by 57–66% while intestinal fluid accumulation was decreased by 68–82%. This finding undoubtedly supports the traditional use of this plant in the treatment of diarrhoea.
Toxicity
There is a general perception that plant-based medicinal products are natural and thus, very safe for human consumption. However, this notion is wrong because several plants have been shown to produce wide range of adverse reactions some of which are capable of causing serious injuries, life-threatening conditions, and even death (Ekor Citation2014). Hence, it is of paramount importance to investigate the toxicity profile of traditional medicinal plants as well as their phytoconstituents in order to establish their safety. The study of toxicity is an essential component for new drug development process (Hornberg et al. Citation2014).
Some toxicological studies have been carried out on the extracts of P. kotschyi. Nchouwet et al. (Citation2017) investigated the acute and sub-chronic toxicity of P. kotschyi stem bark aqueous extract in albino rats. For the acute toxicity study, the LD50 was found to be greater than 2000 mg/kg body weight. The sub-chronic administration of the aqueous extract at a dose of 400 mg/kg body weight/day for 28 days, caused significant increase in total protein and HDL-Cholesterol with concomitant decrease in LDL-cholesterol while other biochemical and hematological parameters were found to be within the normal range. However, histological examination revealed the presence of inflammation and necrosis in the kidney and liver tissues of animals treated with 400 mg/kg body weight-/day of extract while tissue samples from animals treated at lower doses remained normal. This implies that the extract may have exhibited some toxic effect on the kidney and liver tissues at 400 mg/kg body weight while it is relatively safe at lower doses.
Kabiru et al. (Citation2015) conducted a sub-chronic toxicity evaluation of a crude methanol extract of leaves in Sprague-Dawley rats at doses of 40, 200 and 1000 mg/kg body weight/day for 4 weeks. They found that the extract did not produce any significant alteration in both hematological and biochemical parameters when compared with standard controls. This implied that the extract was relatively non-toxic at the tested doses. Ezeokpo et al. (Citation2020) also carried out a similar study with an ethanol extract of P. kotschyi leaves in Wistar rats. Their results revealed that the extract (400 mg/kg body weight/day) did not produce any significant derangement in hematological and biochemical parameters after 28 days of treatment. The above findings indicated that methanol and ethanol extracts of P. kotschyi leaves are relatively non-toxic at higher doses compared to the aqueous stem bark extract. However, more detailed research is still required to corroborate this finding. Albeit most of the pharmacological activities and chemical constituents reported on this plant have been obtained from the leaf’s extracts, the toxicity evaluation of ethanol, methanol and chloroform extracts of roots and stem bark of P. kotschy is yet to be carried out and reported. Hence, further toxicity studies on different extracts, fractions and chemical constituents of the root and stem bark of P. kotschyi are still required to ascertain the thorough safety of the plant.
Conclusions
P. kotschyi is an important medicinal plant which is used in the traditional treatment of different ailments. Based on its ethnomedicinal claims, extensive pharmacological and phytochemical investigations have been carried out which led to the isolation and characterisation of several bioactive constituents. Results from the pharmacological investigations on this plant and its phytoconstituents have demonstrated its high therapeutic potential in the treatment of cancer and tropical diseases, particularly malaria, leishmaniasis and trypanosomiasis. Although, experimental data support the beneficial medicinal properties of P. kotschyi, there were no sufficient data on the toxicity and safety profile of the plant. Nonetheless, this review provides the foundation for future work. Considering the amount of knowledge so far obtained on the medicinal properties of P. kotschyi, further studies on this plant should be directed towards establishing its safety profile as well as design and development of drug product either as single chemical entity or as a standardised herbal preparation. Tropical diseases are among the most neglected health problems in the world. The pharmaceutical industries show little research and development interest in this area albeit the devastating effect of such diseases. Therefore, research finding of this nature should be advanced towards the development of useful medicinal products.
Author contributions
Alhassan Muhammad Alhassan developed the concept, conducted literature search while Qamar Uddin Ahmed, Ibrahim Malami and Zainul Amiruddin Zakaria participated in manuscript writing, review, and correction.
Disclosure statement
No potential conflict of interest was reported by the author(s).
References
- Abubakar K, Danjuma MN, Maiha BB, Anuka JA, Yam FM, Bello I, Nasiba US, Zaini MA. 2016. Antinociceptive activity of the crude methanolic extract of Pseudocedrela kotschyi and its chloroform and n-butanol fractions in mice. J Pharm Biomed Sci. 6:158–164.
- Adeniyi CBA, Odumosu B, Ayelaagbe O, Kolude B. 2010. In-vitro antimicrobial activities of methanol extracts of Zanthoxylum xanthoxyloides and Pseudocedrela kotschyi. Afr J Biomed Res. 13:61–68.
- Ahmed AU. 2011. An overview of inflammation: mechanism and consequences. Front Biol. 6(4):274–281.
- Ahua KM, Ioset JR, Ioset KN, Diallo D, Mauël J, Hostettmann K. 2007. Antileishmanial activities associated with plants used in the Malian traditional medicine. J Ethnopharmacol. 110(1):99–104.
- Akuodor GC, Essien AD, Essiet GA, David-Oku E, Akpan JL, Udoh FV. 2013. Evaluation of antipyretic potential of Pseudocedrela kotschyi Schweint. Harms. EJMP. 3(1):105–113.
- Alain KY, Oronce DOL, Boniface Y, Mhudro Y, Pascal ADC. 2014. Free radical scavenging and antibacterial potential of two plants extracts (Khaya senegalensis and Pseudocedrela kotschyi) used in veterinary pharmacopoeia in Benin. Elixir Appl Chem. 76:28720–28726.
- Alhassan AM, Ahmed QU, Latip J, Shah SAA, Khan A'YF, Sarian MN, Wahab RA, Taher M, Abdullahi MI, Khatib A. 2018. Phytoconstituents from Vernonia glaberrima Welw. Ex O. Hoffm. leaves and their cytotoxic activities on a panel of human cancer cell lines. S Afr J Bot. 116:16–24.
- Alhassan AM, Malami I, Abdullahi MI. 2014. Phytochemical screening and antimicrobial evaluation of stem bark extract of Pseudocedrela kotschyi (Schweinf.) Herms. BJPR. 4(16):1937–1944.
- Asase A, Oteng-Yeboah AA, Odamtten GT, Simmonds MSJ. 2005. Ethnobotanical study of some Ghanaian anti-malarial plants. J Ethnopharmacol. 99(2):273–279.
- Ayo RG, Audu OT, Ndukwe GI, Ogunshola AM. 2010. Antimicrobial activity of extracts of leaves of Pseudocedrela kotschyi (Schweinf.) Harms. African J Biotechnol. 9:7733–7737.
- Balekundri A, Mannur V. 2020. Quality control of the traditional herbs and herbal products: a review. Future J Pharm Sci. 6:67–76.
- Balunas MJ, Kinghorn AD. 2005. Drug discovery from medicinal plants. Life Sci. 78(5):431–441.
- Bielefeldt K, Davis B, Binion DG. 2009. Pain and inflammatory bowel disease. Inflamm Bowel Dis. 15(5):778–788.
- Bothon FTD, Debiton E, Avlessi F, Forestier C, Teulade J, Sohounhloue DKC. 2013. In-vitro biological effects of two anti-diabetic medicinal plants used in Benin as folk medicine. Complement Altern Med. 13(1):1–8.
- Boyom FF, Fotio D, Zollo PHA, Agnaniet H, Menut C, Bessière JM. 2004. Aromatic plants of Tropical Central Africa. Part XLIV. Volatile components from Pseudocedrela kotschyi (Schweinf) Harms growing in Cameroon. Flavour Fragr J. 19(1):9–11.
- Calderwood SK, Khaleque MA, Sawyer DB, Ciocca DR. 2006. Heat shock proteins in cancer: chaperones of tumorigenesis. Trends Biochem Sci. 31(3):164–172.
- Chen JY, Zhu GY, Su XH, Wang R, Liu J, Liao K, Ren R, Li T, Liu L. 2017. 7-Deacetylgedunin suppresses inflammatory responses through activation of Keap1/Nrf2/HO-1 signaling. Oncotarget. 8(33):55051–55063.
- Christian AG, Ahunna AG, Nwakaego EM, Chimsorom CK, Chile AE. 2015. Antimalarial potential of the ethanolic leaf extract of Pseudocedrala kotschyi. J Acute Dis. 4(1):23–27.
- Dal Piaz F, Malafronte N, Romano A, Gallotta D, Belisario MA, Bifulco G, Gualtieri MJ, Sanogo R, De Tommasi N, Pisano C. 2012. Structural characterization of tetranortriterpenes from Pseudrocedrela kotschyi and Trichilia emetica and study of their activity towards the chaperone Hsp90. Phytochemistry. 75(1):78–89.
- Dawet A, Stephen S. 2014. The antimalarial activity of the crude leaf extract of Pseudocedrala kotschyi in P. berghei berghei infected mice. Afr J Nat Sci. 17(1):19–27.
- Dawet A, Yakubu P. 2014. Antiplasmodial efficacy of stem bark extracts of Pseudocedrela kotschyi in mice infected with Plasmodium berghei berghei. BJPR. 4(5):594–607.
- Ekor M. 2014. The growing use of herbal medicines: Issues relating to adverse reactions and challenges in monitoring safety. Front Pharmacol. 4:177–186.
- Eleha SI, Ola MA, Oyewole OS, Ganiyu AO, Onaolapo AO, Afodun AM. 2016. Anti-oxidative and hepatoprotective effects of Pseudocedrela kotschyi against paracetamol induced liver damage. A biochemical and histological evaluation in rats. J Adv Med Pharm Sci. 7(3):1–11.
- Erinoso SM, Fawibe OO, Oyelakin AS, Ajiboye AA, Agboola DA. 2016. Herbal recipes used for the traditional management of infantile dermatitis in Odeda, southwestern Nigeria. Afr J Trad Compl Alt Med. 13(3):33–43.
- Essiet GA, Christian AG, Ogbonna AD, Uchenna MA, Azubuike J, Michael NE. 2016. Antidiarrhoeal and antioxidant properties of ethanol leaf extract of Pseudocedrela kotschyi. J App Pharm Sci. 6(3):107–110.
- Ezeokpo BC, Akuodor GC, Owomofoyon O, Erejuwa JLA, Nnolim BI, Ogiji ED, Nwobodo MU, Ezeonu CT. 2020. Assessment of acute and sub-acute toxicity of ethanol extract of Pseudocedrela kotschyi leaf in Wistar rats. J Biol Sci. 3:48–57.
- Garami A, Steiner AA, Romanovsky AA. 2018. Fever and hypothermia in systemic inflammation. Handb Clin Neurol. 157:565–597.
- Georgewill UO, Georgewill OA. 2019. Effect of extract of Pseudocedrela kotschyi on blood glucose concentration of alloxan induced diabetic albino rats. East J Med. 14(1):17–19.
- Gupta SD, Bommaka MK, Banerjee A. 2019. Inhibiting protein-protein interactions of Hsp90 as a novel approach for targeting cancer. Eur J Med Chem. 178:48–63.
- Hassler M. 2019. Pseudocedrela kotschyi (Schweinf.) Harms. World Plants: Synonymic checklists of the vascular plants of the world. [accessed 2020 Sep 20]. Available from https://www.catalogueoflife.org/data/taxon/4NQWM
- Hay A-E, Ioset J-R, Ahua KM, Diallo D, Brun R, Hostettmann K. 2007. Limonoid orthoacetates and antiprotozoal compounds from the roots of Pseudocedrela kotschyi. J Nat Prod. 70(1):9–13.
- Hobson C, Chan AN, Wright GD. 2021. The Antibiotic resistome: a guide for the discovery of natural products as antimicrobial agents. Chem Rev. 121(6):3464–3494.
- Hornberg JJ, Laursen M, Brenden N, Persson M, Thougaard AV, Toft DB, Mow T. 2014. Exploratory toxicology as an integrated part of drug discovery. Part I: why and how. Drug Discov Today. 19(8):1131–1136.
- Hotez PJ, Kamath A. 2009. Neglected tropical diseases in sub-Saharan Africa: review of their prevalence, distribution, and disease burden. PLoS Negl Trop Dis. 3(8):e412.
- Kabiru A, Muhammad DN, Bello MB, Akpojo AJ, Fei YM, Oricha BS, Adlin Y, Yee HS, Ahmad M, Asmawi ZM. 2015. A 28-day oral toxicity study of Pseudocedrela kotschyi methanol extract in Sprague-Dawley rats. EJMP. 10(3):1–11.
- Kantati YT, Kodjo KM, Dogbeavou KS, Vaudry D, Leprince J, Gbeassor M. 2016. Ethnopharmacological survey of plant species used in folk medicine against central nervous system disorders in Togo. J Ethnopharmacol. 181:214–220.
- Kassim OO, Copeland RL, Kenguele HM, Nekhai S, Ako-Nai KA, Kanaan YM. 2015. Antiproliferative activities of Fagara xanthoxyloides and Pseudocedrela kotschyi against prostate cancer cell lines. Anticancer Res. 35(3):1453–1458.
- Kayode J, Sanni P. 2016. Survey of barks used for medicine in the central zone of Lagos State, Nigeria. J Bot Papers. 1(1):1–7.
- Koné WM, Atindehou KK, Dossahoua T, Betschart B. 2005. Anthelmintic activity of medicinal plants used in northern Côte d’Ivoire against intestinal helminthiasis. Pharm Biol. 43(1):72–78.
- Mambou CS, Nono RN, Chouna JR, Tamokou J-d-D, Nkeng-Efouet-Alango P, Sewald N. 2018. Antibacterial secotirucallane triterpenes from the stem bark of Pseudocedrela kotschyi. Z Naturforsch C J Biosci. 73(5–6):241–246.
- Medzhitov R. 2008. Origin and physiological roles of inflammation. Nature. 454(7203):428–435.
- Nadembega P, Boussim JI, Nikiema JB, Poli F, Antognoni F. 2011. Medicinal plants in Baskoure, ethnopharmacological survey of plant species used in folk medicine against central nervous system disorders in Togo Kourittenga Province, Burkina Faso: an ethnobotanical study. J Ethnopharmacol. 133(2):378–395.
- Nchouwet ML, Wansi Ngnokam SL, Kodjio N, Poualeu SK, Nkengeffouet PA, Kamanyi A. 2018. Hepatoprotective and antioxidant effect of stem barks extracts: methanolic and aqueous extracts of Pseudocedrela kotschyi (Meliaceae) on paracetamol-induced hepatic damage in rats. Asian J Biomed Pharm Sci. 7(63):1–9.
- Nchouwet ML, Wansi NS, Oumar MM, Nkeng-Efouet AP, Poualeu KS. 2017. Toxicological evaluation of the aqueous extract of Pseudocedrela kotschyi (Meliaceae) stem bark in albino rats. J Pharm Biol Sci. 5:168–174.
- Olabanji SO, Adesina SK, Ceccato D, Buoso MC, Moschini G. 2007. PIXE analysis of some medicinal plants used in cleaning teeth in southwestern Nigeria. Biol Trace Elem Res. 116(2):171–184.
- Pedersen ME, Vestergaard HT, Hansen SL, Bah S, Diallo D, Jäger AK. 2009. Pharmacological screening of Malian medicinal plants used against epilepsy and convulsions. J Ethnopharmacol. 121(3):472–475.
- Roy A, Saraf S. 2006. Limonoids: overview of significant bioactive triterpenes distributed in plants kingdom. Biol Pharm Bull. 29(2):191–201.
- Saidu IN, Umar KS, Isa MH. 2015. Ethnobotanical survey of anticancer plants in Askira/Uba local government area of Borno State, Nigeria. Afr J Pharm Pharmacol. 9(5):123–130.
- Salihu Shinkafi T, Bello L, Wara Hassan S, Ali S. 2015. An ethnobotanical survey of antidiabetic plants used by Hausa-Fulani tribes in Sokoto, Northwest Nigeria. J Ethnopharmacol. 172(1):91–99.
- Sarigaputi C, Sangpech N, Palaga T, Pudhom K. 2015. Suppression of inducible nitric oxide synthase pathway by 7-deacetylgedunin, a limonoid from Xylocarpus sp. Planta Med. 81(4):312–319.
- Sidjui LS, Nganso YO, Toghueo RMK, Wakeu BNK, Dameue JT, Mkounga P, Adhikari A, Lateef M, Folefoc GN, Ali MS. 2018. Kostchyienones A and B, new antiplasmodial and cytotoxicity of limonoids from the roots of Pseudocedrela kotschyi (Schweinf.) Harms. Zeitschrift für Naturforsch C. (3–4)73:153–160.
- Steverding D, Sidjui LS, Ferreira ÉR, Ngameni B, Folefoc GN, Mahiou-Leddet V, Ollivier E, Stephenson GR, Storr TE, Tyler KM. 2020. Trypanocidal and leishmanicidal activity of six limonoids. J Nat Med. 74(3):606–611.
- Tan TYC, Lee JC, Yusof NAY, Teh BP, Mohamed AFS. 2020. Malaysian herbal monograph development and challenges. J Herb Med. 23:100380–100385.
- Tan QG, Luo XD. 2011. Meliaceous limonoids: chemistry and biological activities. Chem Rev. 111(11):7437–7522.
- Tapsoba H, Deschamps JP. 2006. Use of medicinal plants for the treatment of oral diseases in Burkina Faso. J Ethnopharmacol. 104(1–2):68–78.
- Taylor DAH. 1979. A limonoid, pseudrelone B, from Pseudocedrela kotschyi. Phytochemistry. 18(9):1574–1576.
- Ukwubile CA, Oise IE, Umar SA. 2017. Evaluation of in vitro anthelminthic activity of Pseudocedrela kotschyi Harms. (Meliaceae) a dry zone ceder stem bark aqueous extract. Int Biol Biomed J. 3(1):30–33.
- Williams A. 2021. A concise note on herbal medicine. J Pharma Reports. 5:e107.
- Wolinsky LE, Sote EO. 1984. Isolation of natural plaque-inhibiting substances from ‘Nigerian chewing sticks’. Caries Res. (3)18:216–225.
- Zhang S, Guo S, Li Z, Li D, Zhan Q. 2019. High expression of HSP90 is associated with poor prognosis in patients with colorectal cancer. Peer J. 7:e7946.