Subscribe Now Subscribe Today
Abstract
Fulltext PDF
References
Review Article
 
Ficus deltoidea: Review on Background and Recent Pharmacological Potential



J. Rosnah, M.M. Khandaker and A.N. Boyce
 
ABSTRACT
Ficus deltoidea is a native plant of Malaysia which is very potential plant for varied purposes. It has diversed morphology and was spread throughout Malaysia and adjacent countries. Its great potential had been valued by the old folks and now it is getting famous as more attention given in exploring herbs as an alternative for medicine. Ficus deltoidea is an ultimate source of antioxidant and natural products. It is commercialized as tea and is proposed as a possible supplement for type II diabetes patients. Ficus deltoidea studied for its numerous pharmacological properties such as antioxidant and antidiabetic properties, anti-inflammation and antinociceptive activity, wound healing activity, antiulcerogenic effect, antibacterial, anticancer and also it’s potential as an uterotonic agent. This article review provide more thorough information about F. deltoidea plants in detail in term of plant, origin, morphology, ecology, variety, commercial usage and its pharmacological benefits.
Services
Related Articles in ASCI
Similar Articles in this Journal
Search in Google Scholar
View Citation
Report Citation

 
  How to cite this article:

J. Rosnah, M.M. Khandaker and A.N. Boyce, 2015. Ficus deltoidea: Review on Background and Recent Pharmacological Potential. Journal of Agronomy, 14: 310-318.

DOI: 10.3923/ja.2015.310.318

URL: http://scialert.net/abstract/?doi=ja.2015.310.318
 
Received: September 13, 2015; Accepted: October 28, 2015; Published: November 11, 2015

INTRODUCTION

Ficus deltoidea got its name from the golden spot present on its leaves. It is also known as Mas cotek, telinga beruk and ser apatangin in peninsular Malaysia, sempit-sempit and agoluran in Sabah, Sarawak and Kalimantan Island and tabat barito in Indonesia (Desaku, 2005) and kangkalibang in Africa (Bunawan et al., 2014). Ficus deltoidea is a very potential plant for varied purposes. It famous for its health benefits and medicinal value, that can be used by both male and female (Sulaiman et al., 2008). Ficus deltoidea fruits are traditionally chewed to relieve toothache, cold and headache and the entire Ficus deltoidea plant is also traditionally used as an aphrodisiac tonic and as health tonic by women in Indonesia. Malays in the peninsular Malaysia have been using the powdered root and leaves of F. deltoidea to treat wounds, rheumatism, sores and other ailments for centuries. The decoction of boiled leaves of F. deltoidea is traditionally used as an antidiabetic treatment and an after-birth tonic to contract the uterus and vaginal muscles to treat disorders of the menstrual cycle and also to treat leucorrhoea (Burkill and Haniff, 1930).

The leaves of F. deltoidea have been report to exhibit blood glucose-lowering effects (Farsi et al., 2011), antinociceptive (Sulaiman et al., 2008), ulcer healing (Zahra et al., 2009), antioxidant (Abdullah et al., 2009), anti-inflammatory (Zakaria et al., 2012) and antimelanogenic (Oh et al., 2011) properties. Recent animal studies had shown that the leaves of F. deltoidea possess the antioxidant activity (Hakiman and Maziah, 2009), anti-hyperglycemic (Adam et al., 2011), antinociceptive (Sulaiman et al., 2008) and also able to promote wound healing (Abdulla et al., 2010). All of this ability believed to relate with F. deltoidea leaves nutritional value content. The aim of this review is to provide a details report on pharmaceutical value of Ficus deltoidea plant.

ORIGIN

Lansky and Paavilainen (2010) state that Ficus deltoidea is a native plant of peninsular Malaysia and were distributed elsewhere. Now, it also can be founded in Thailand and Indonesia. The genus Ficus consists of about 750 species worldwide including trees, epiphytes and shrubs in tropical and subtropical regions worldwide (Starr et al., 2003). The scientific classification of F. deltoidea is as follows (Mat et al., 2012; Awang et al., 2013):

Kingdom : Plantae
Division : Magnoliophyta
Class : Magnoliopsida
Order : Rosales
Family : Moraceae
Genus : Ficus
Species : Deltoidea
Binomial name : Ficus deltoidea Jack

ECOLOGY

Ficus deltoidea plant widely spread around Malaysia, form sandy and bushy area to mountain tops and in bogs (Starr et al., 2003). Most variety grows below 1200 m latitude, though some of it is not. Ficus deltoidea var. intermedia can be found in the higher mountain areas above the dipterocarp forest. Ficus deltoidea var. angustifolia grows near by the streams or riversides. In Borneo, the var. motleyana is found in the coastal, peat-swamp and sandy heath forests (Corner, 1969).

Ficus deltoidea var. deltoidea and var. kunstleri are primarily epiphytes, growing on other plants without deriving nutrients from the host plant. Ficus deltoidea var. trengganuensis is primarily terrestrial similar to var. motleyana which grows on the ground. The var. motleyana may grow up as a spindly tree reaching 6 m high while var. angustifolia is the undergrowth shrub (Corner, 1969).

MORPHOLOGY

Leaf morphology of F. deltoidea diversed in nature and make some confusion for direct determination just by look at their morphology. Kochummen and Rusea (2000) reported that the leaf shapes of Ficus deltoidea are of varied shape as deltoid, elliptic, obovate, spathulate or rhomboid. Other variations in the leaf morphology also involved dimension, shape, venation, presence and distribution of waxy glands and length of petiole. Leaf’s lamina are oblong, elliptic, obtriangular, oblanceolate, spathulate, linear and suborbicular (Berg and Corner, 2005).

Two popular variants are Ficus deltoidea var. angustifolia (known as male plant) and Ficus deltoidea var. deltoidea (female plant). They are of different variant but often discriminate as a same variant by the traditional farmers. Arifin (2005) define Ficus deltoidea var. angustifolia as having small leaves with parallel vein while Ficus deltoidea var. deltoidea as having big leaves with ramified vein. The difference between male and female plant is that the male plant is having black dots on its leaves while red dots can only be seen on female leaves (Hakiman and Maziah, 2009). Mohammad et al. (2012) reported that there is leaf heterophyll in F. deltoidea variety that was measured based on leaf shape and leaf apex.

All members of the genus Ficus share the distinctive inflorescence (syconium), where pollination occurs through mutualism interaction with fig wasps of the subfamily Agaonidae (Cook and Rasplus, 2003). Syconium or fruit of Mas cotek range 7 mm in diameter, up to 0.2 cm thick and can be yellow, orange or red when ripening (Berg and Corner, 2005), placed along the twigs on short stalks. Syconia usually come in pairs or solitary, axillary, oblong, globose or ellipsoid, 0.3-2×0.2-1.2 cm and strongly umbonate at apex. It has 3-4 tepals red in color, glabrous, also ovate to lanceolate in shape (Kochummen and Rusea, 2000). The fruits are tiny, convoluted, with numerous seeds and flowers inside the fruits. It is term as fig. Fig has thin and delicate skin, allowing the wasps to burrow, mate and leaving the eggs there for hatching (Lansky and Paavilainen, 2010).

VARIETY

There were 15 recognizes varieties of Ficus deltoidea, eight of it from originate from Sabah and Sarawak (Kochummen and Rusea, 2000). Bunawan et al. (2014) added the one more variety make it into 16 which are var. arenaria Corner, var. borneensis Corner, with subhirsuta Corner, var. lutescens (Desf) Corner, with forma longipedunculata Corner and forma subsesssilis (Miq.) Corner, var. peltata Corner var. recurvata Kochummen and var. oligoneura (Miq.) Corner.

Those seven varieties of Ficus deltoidea originated form peninsular Malaysia are var. deltoidea, var. angustifolia, var. trengganuensis, var. bilobata, var. intermedia, var. kunstleri and var. motleyana (Turner, 1995). Nur Fatihah et al. (2014) further classified these seven varieties morphologically and it nested into two clades, clade subspecies deltoidea (var. deltoidea, var. bilobata, var. angustifolia, var. kunstleri and var. trengganuensis) and clade subspecies motleyana (var. intermedia and var. motleyana). Some morphological differences among the varieties of F. deltoidea are given in Fig. 1 and 2.

Fig. 1(a-g):
Photograph showing the morphological differences among the varieties of F. deltoidea (a) Ficus deltoidea var. angustifolia, (b) Ficus deltoidea var. bilobata, (c) Ficus deltoidea var. trengganuensis, (d) Ficus deltoidea var. deltoidea, (e) Ficus deltoidea var. kunstleri, (f) Ficus deltoidea var. intermedia and (g) Ficus deltoidea var. motleyana

Fig. 2(a-c):
Photograph showing syconium characteristics of different F. deltoidea varieties (a) Syconium of Ficus deltoidea var. deltoidea, (b) Syconium of Ficus deltoidea var. intermedia and (c) Cross section of syconium of Ficus species

POLLINATION

Ficus deltoidea flowers are completely obscured within the fig with hundreds of petite florets lining the inside of a central cavity. Fig trees in general are depend solely on tiny wasps, only a couple of millimeters long for their propagation and survival (Simon, 2004). Each species of fig tree is usually pollinated by one fig wasp species that is only associated with that fig species, although increasing number of concessions have been reported (Lopez-Vaamonde et al., 2002). Formerly, no specific wasps has been claimed to be specific to Ficus deltoidea plant, which is actually crucial for better understandings of this plants and its reproduction in natural habitat.

Figs are produced throughout the year and are cross pollinated by the female wasp. When the syconium receptive to wasp allowing it to penetrate through ostiole, tiny bract-lined opening at the apex of the fig. Female wasps will lay eggs in the ovule of the florets, also pollinate the stigma. Larvae will feed on endosperm of fruits ovary, once maturing will also chewing up of fruits to find their ways out. Once the female fig wasps have left the fig, it will ripens and exhibit other ripening characteristics to attract the animals. Male wasp only involves in mating and chewing of figs to allow female escape and they will die soon after that (Lansky and Paavilainen, 2010).

PROPAGATION

Mas cotek in natural habitat commonly associated with Rhodomyrtus tomentosa (kemunting) which might be caused by the same dispenser such as bird that eat the fruit and dispense the seeds at the same area. Ficus deltoidea have low germination rate of its seeds. This makes the vegetative propagation a better choice in its commercialization (Jamilah et al., 2005). Generally, all Ficus species propagate from seed, also cutting or trees can begin life as epiphytes on other trees (Ronsted et al., 2008).

It is suggested that the application of the rooting hormone during the propagation of Ficus stem cutting as it might enhance root production (Balakrishna and BhattacHarjee, 1991). Hassanein (2013) demonstrated that Indole Acetic Acid (IAA) was more effective than treatment by either Indole Butyric Acid (IBA) or Naphthyl Acetic Acid (NAA) on rooting of Ficus hawaii as woody tree and Chrysanthemum morifolium. Chitosan also significantly shown to improve rooting rate of Ficus triangularis, Ficus microcarpa and Ficus benjamina compared to Naphthalic Acetic Acid (NAA) (Gamlath et al., 2010).

COMMERCIAL USAGE

Tea: Mohammad et al. (2012) states that the leaves of F. deltoidea var deltoidea have high amount of magnesium, manganese and potassium in addition to other minerals such as potassium, sodium, iron and zinc. They suggest that the tea made of this leaves can be served as a good source of mineral for human consumption. Therefore, tea beverages of F. deltoidea leaves may act as a suitable source of elements intake for human body. Regular consumption of this type of tea will contribute to adequate amount of manganese and magnesium which have functional role in physiological process in human body. The recommended consumption is 2-3 cups of this tea (each cup 50 mL) as it contained very high magnesium and manganese value compared to our recommended daily dietary intake. This is parallel to the consumption of Ficus racemosa bark as nutra tea due to its mineral content (Ahmed et al., 2010).

Smilkstein et al. (1988) reported that excessive consumption of Mas cotek tea, daily more than one litre may lead to hypermagnesemia and manganese toxicity. The symptoms of hypermagnesemia are hypotension, nausea, vomiting, central nervous depression, respiratory depression also severe cardiac arrest. Manganese toxicity may lead to neurogenerative disorder characterized by both central nervous system abnormalities and neuropsychiatric disturbances (Santamaria, 2008). This is opposed to studies by Farsi et al. (2013) that demonstrated that mammalian toxicity of F. deltoidea extract is low and that its use in traditional medicine presents no genotoxic risks to human.

Woon et al. (2014) reported that water extract for F. deltoidea var. angustifolia and var. deltoidea had higher cytotoxicity to 3T3-L1 preadipocytes than methanol extract of this plant. This shown by maximum non-toxic level of var. deltoidea in methanol extract was 300.0±28.3 μg mL–1 and in aqueous extract was 225.0±21.2 μg mL–1. In var. angustifolia, maximum non-toxic dose was report as 60.0±2.0 μg mL–1 in methanol extract while in aqueous extract was 8.0±1.0 μg mL–1. Higher cytotoxicity in aqueous extract may be caused by the presence of high amounts of phenolic compounds, such as flavonoids. Thus, consuming this tea will need a proper control and right dose not to exceed the maximum non-toxic dose for human consumption to obtain optimum benefit.

Food: Draman et al. (2012) proposed F. deltoidea as a possible supplement for type II diabetes patient. Although the study did not give significant result, there were still some advantages of this plant over other herbs medicinal plants. This plant consumption in human with diabetes were able to reducing diabetes complications such as reducing edema and lethargic, increase HDL level and decrease LDL blood level. This study also observed improved sexual life of the patients. Fortunately, the patients did not show any negative impacts form the plant consumption. Author did suggest that F. deltoidea is better plant instead of cinnamon in term of its medicinal value as a supplement for diabetic patient. Now-a-days, customers could consume them in capsule form (Misbah et al., 2013).

In China, figs commercialized as wine when mix with either grape, rice, or powder of dried ganoderma lucidum as it believed to promoted health due to their nutritional content, while at the same time endowed tasty unique flavored (Lansky and Paavilainen, 2010).

Serio-Silva et al. (2002) reported that Ficus species among the most important food for Mexican howler monkeys which contributed to 64.2% of their meals. This study was supported by Felton et al. (2008) when he recorded Ateles chamek monkey spent up to 50% their meals on Ficus species although on season of high overall food availability. Ficus species obviously is an important source of food to human and animal.

PHARMACOLOGICAL PROPERTIES

Antioxidant and antidiabetic properties: Studies revealed that antioxidants play a key role in reducing diabetic complications (Rahimi et al., 2005; Tchinda et al., 2008). Antioxidant is a part of our complex defense system that will protect our body from oxidative damage of free radicals form internal or external sources. Previous study by Zino et al. (1997) shows the ability of antioxidant to improve immune system functions and in delaying some effects of aging. Aris et al. (2009) demonstrates F. deltoidea fruit extract var. angustifolia as a good source of antioxidant. The fruits of F. deltoidea extract by using 3 different solvent; hexane, chloroform and methanol able to reduce the amount of peroxide better than vitamin E. The highest antioxidant activity could be found in hexane extract.

Phenolic compounds and its derivatives are strongly correlated with its antioxidant activities (Maisuthisakul et al., 2007). This statement was parallel with the study carried by Hakiman and Maziah (2009). They found out that plant extract with high antioxidant activities also have high antioxidant compounds. Cocoa also has high antioxidant activities with the presence of high total phenolic and flavonoid content (Lee et al., 2003). On the other hands, Misbah et al. (2013) reported that there was no correlation between antioxidant activities and the amounts of flavonoids in the extracts or fractions of F. deltoidea fruits although there was a positive correlation between plants phenolic and its antioxidant activities. This deviation of result might be caused by different parts of plants that had been used in each study.

Hakiman and Maziah (2009) states that antioxidant compounds that can be found in F. deltoidea leaves extract were polyphenol, phenolic acid and flavonoid, also said as non-enzymatic antioxidant. On the other hands, enzymatic antioxidants that can be found in F. deltoidea leaves extract were ascorbate oxidase, peroxidase, catalase and ascorbate peroxidase. However, the enzymes activities are not stable and did not provide consistent result in test done. A study conducted by Maizatul et al. (2011) proposed that 85% of the total antioxidant activity of the aqueous F. deltoidea distillation was attributable to the flavan-3-ol monomers, proanthocyanidins and C-linked flavone glycosides.

Recently, more research done to provide scientific explanation to the traditional practices of consuming F. deltoidea as an antidiabetic medicine. Adam et al. (2011) suggest that the aqueous extract of F. deltoidea leaves might contain water-soluble insulin-secreting constituents which give better effects than glibenclamide. Misbah et al. (2013) reported that F. deltoidea fruits have the potential in reducing blood glucose level. Her study shows the presence of phenolic and flavonoid of F. deltoidea fruits were positively correlated between the phenolic compounds of plants and their effective antidiabetic properties. She also suggests the glucose-lowering property of F. deltoidea is achieved through inactivation of α-glucosidase but not via α-amylase inhibition.

Another study conducted by Adam et al. (2011) to evaluate the ethanolic effect of F. deltoidea on glucose levels in normal rats showed that all doses introduced to the rats were able to reduce fasting blood glucose, especially after 6 h of administration. Adam et al. (2012) also evaluated extracts of F. deltoidea for hyperglycemia effects at different prandial states. The study found that hot aqueous extracts of F. deltoidea stimulate insulin secretion and show a high magnitude of stimulation and the extract induced the usage of intracellular Ca2 to initiate release of insulin. It was also observed that ethanolic and methanolic extract of F. deltoidea increased basal and insulin-mediated glucose uptake into adipocytes cells (liver cell line), with ethanolic extract having the highest insulin mimetic activity. Kalman et al. (2013) reported that F. deltoidea has significant effect on reducing glucose and lipid levels in human adults with prediabetes.

In addition, Misbah et al. (2013) proposed that antidiabetic properties of F. deltoidea extract was caused by the low molecular mass protein at peaks 3360 and 4400 Da may be involved in the significant activity of antidiabetic properties of F. deltoidea fruit extracts var. angustifolia and kunstleri. He proposed this as she found out that there was no correlation between α-glucosidase inhibitory activities and both phenolic and flavonoid content.

Anti-inflammation and antinociceptive activity: Anti-inflammation is defined as a natural response of human body as a part of immune system to remove harmful stimuli such as damaged cells, irritants or stimulants. The signs of acute inflammation are swelling, pain, heat, redness and loss of function. Zunoliza et al. (2009) reported that the leaves extract of F. deltoidea have significant anti-inflammatory properties after being evaluate by using three in vitro assays: lipoxygenase, hyaluronidase and TPA-induced edema. This proved the potential of F. deltoidea leaves as a functional reagent in relieving pain and reducing inflammatory effect. This study was parallel to study by Zakaria et al. (2012), that the leaf of F. deltoidea significantly possesses anti-inflammatory activity against acute and chronic inflammatory responses and against pain-associated inflammatory response due to dose response effect on animal trials. F. deltoidea also is an important agent in prevent or reducing nociception, the sensation of pain. Sulaiman et al. (2008) observed that F. deltoidea leaves significantly affected on reducing nociception as it produced significant dose-dependent antinociceptive effect in all the models used.

Wound healing activity: Abdulla et al. (2010) shows that the extract of F. deltoidea significantly enhanced wound healing activity in rats by enhancing wound enclosure and fibroblast proliferation, which contributed to angiogenesis. Bonte et al. (1994) suggest that this wound enclosure activities may be caused by the regulation of collagen 1, also an increase in tensile strength of the wounds (Suguna et al., 1996). Suarez et al. (1996) reported that the presence of flavonoid in F. deltoidea extract might contribute to this wound healing process as flavonoid was report to be able to promote wound healing and protect tissues form the oxidative damage.

Antiulcerogenic effect: In developed countries, peptic ulcer was report as the most common gastrointestinal disorder that was caused by the disruptions of gastric mucosal defense and repair system (Grossman, 1981). As a popular herbs used by the old folks, F. deltoidea plant pharmacological properties to cure ulcer was investigated. Zahra et al. (2009) in his study in anti-ulcerogonic activity of aqueous extract of F. deltoidea whole plant towards gastric walls of rats shows the ability of F. deltoidea to cure ulcer by decreasing the ulcer area, inhibit submucosal edema and leucocytes infiltration of submucosal layer. Ficus deltoidea extract was significantly reduce effect of ulcer induced by ethanol at 500 mg kg–1 dose, as the same effect observed in omeprazole, a type of common drug to reduce the amount of acid produce in the stomach. The potential of F. deltoidea as antiulcerogenic agent was constant with studies by Gregory et al. (2009) where Ficus arnottiana Miq. also posses anti-ulcer properties.

Antibacterial activity: Ficus deltoidea plants said contains flavonoid, which normally related to antioxidant activity of the plant. Besides, flavonoid also gives the yellow pigmentation. This yellow pigmentation acts as a natural protection of this plant in helping the plant to protect itself from microorganism and insects. Any herbs that contain flavonoid could also have the ability to act as anti-allergy, anti-inflammatory, antimicrobial and anti-cancer agent (Xiao et al., 2011). Dzolin et al. (2015) reported the positive correlation was observed between flavonoid constituents present and radical scavenging activities of the aqueous extracts of four types of F. deltoidea.

Suryati et al. (2011) reported that lupeol (C30H50O), an antibacterial compound found in Ficus deltoidea leaves inhibit growth of E. coli, B. subtilis and S. aureus at 150, 220 and 130 μg mL–1 at minimum inhibition concentration. Lee et al. (2003) also shows the potential of Ficus deltoidea leaves extract to inhibit up to 30% of all bacterial isolates ranged from 31.26-125 mg L–1. It proved that methanol extract of F. deltoidea significantly inhibited the growth of S. aureus at lowest Minimum Inhibitory Concentration (MIC) value (3.125 mg mL–1), while the other extract act as good antibacterial and antifungal against fungus, gram-positive and gram-negative bacteria strains tested on this study.

Anticancer effect: Shafaei et al. (2014) in his study shows that standardized leaf extract of F. deltoidea have the anticancer potential. In his study, the leaf extract have the ability as antiangiogenic towards animal cells. Antiangiogenic is the potential to inhibit the formation of new blood vessels. This potential plays a critical role in pathogenesis of various disease related to blood. The highlight is that the extract was non-toxic towards HUVECs, while showing potent cytotoxicity towards hormone-resistant breast cancer (MDA-MB-231) and colon cancer cells (HCT 116). He suggest that this antiangiogenic activity caused by the presence of high concentration of antioxidant such as phenolic and flavonoid in addition to ursolic acid which famous for its pharmacological properties. This selective antiangiogenic property makes extract of F. deltoidea leaves as a potential sources of new anticancer agent.

This statement was supported by Akhir et al. (2011) on human ovarian carcinoma cell line states when this plant extract could cause apoptosis at 1000 μg mL–1, with faster apoptosis effect in ethanolic extract than aqueous extract. Both extract effects differently towards cancer cell growth, DNA fragmentation and cell morphology. Aqueous extract of F. deltoidea tend to promote cell detachment while the ethanolic extract prompted to stop cells form cell proliferation through DNA fragmentation as DNA fragmentation was found in cells treated with ethanolic extract at around 200 Kbp. This apoptosis effect make it possible for suppressing the growth of uncontrolled cell especially in human.

Uterotonic agent: Study by Amiera et al. (2014) revealed potential of F. deltoidea var. deltoidea and var. angustifolia as natural uterotonic agent to induce labor also to be used for post-partum hemorrhage as this study demonstrated the contractile effects of this leaves extract on uterine contraction of rats. This study showed that these two varieties and oxytocin induced dose-related intensification in force of contraction of rats. Salleh and Ahmad (2013) suggested that uterotonic effects of F. deltoidea aqueous extracts act via muscarinic, oxytocin and PGF2α receptors and is dependent on the extracellular Ca2. Author also proposed that degree of uterus contraction highest via oxytocin receptor, followed by PGF2α and muscarinic receptor with least degree of contraction. The uterotonic effects also observed in other Ficus species such as Ficus exasperata Vahl (Bafor et al., 2010) and Ficus asperifolia (Watcho et al., 2011).

Anti-adipogenic agent: Recently, Woon et al. (2014) report the anti-adipogenic effects of F. deltoidea extract. Treatment of methanol and aqueous extract of F. deltoidea var. deltoidea and var. angustifolia on 3T3-L1 preadipocytes shows the potency of F. deltoidea extract as potential anti-obesity effects. Methanol extract of both extract and water extract of var. angustifolia were significantly proved to inhibit the maturation of preadipocytes at maximum non-toxic dose and half maximum non-toxic dose. More significant result was demonstrated in methanol extract of var. deltoidea than var. angustifolia. This study was a support to Ong et al. (2011) that previously relate anti-adipogenic activity of F. deltoidea with the flavonoid and quercetin that present in significant amount in this plant. The potential anti-adipogenic compounds should be further examined for better understanding of the compound and its potential as a slimming aid.

CONCLUSION

Ficus deltoidea is a valuable medicinal plant. It had been used by the old folks for multiple purposes in our daily life. As it getting more concerned, there was scientific study to prove its functions in pharmacological purpose especially. Previous study related the presence of its bioactive compound such as phenolic and flavonoid to its pharmacological properties. Its ability in aid for further fertility for both sexes should be explored due to its possibility to be used by both sexes. Not only research in pharmacological side, its agronomy and propagation needs more study to provide a good foundation for further understanding of this valuable plant also in preparation for its commercialization. It is also a good step for introducing this plant for better promotion and appreciation for its medicinal value.

ACKNOWLEDGMENT

This research was supported by a PRPUM grant from the University of Malaya, 50603, Kuala Lampur and University Sultan Zainal Abidin, Tembila campus, 22200 Besut, Terengganu, Malaysia (Project No. Cg012-2014).

REFERENCES
Abdulla, M.A., K.A.A. Ahmed, F.M. Abu-Luhoom and M. Muhanid, 2010. Role of Ficus deltoidea extract in the enhancement of wound healing in experimental rats. Biomed. Res., 21: 241-245.
Direct Link  |  

Abdullah, Z., K. Hussain, Z. Ismail and R.M. Ali, 2009. Anti-inflammatory activity of standardised extracts of leaves of three varieties of Ficus deltoidea. Int. J. Pharmaceut. Clin. Res., 1: 100-105.
Direct Link  |  

Adam, Z., A. Ismail, S. Khamis, M.H.M. Mokhtar and M. Hamid, 2011. Antihyperglycemic activity of F. deltoidea ethanolic extract in normal rats. Sains Malaysiana, 40: 489-495.
Direct Link  |  

Adam, Z., S. Khamis, A. Ismail and M. Hamid, 2012. Ficus deltoidea: A potential alternative medicine for diabetes mellitus. Evidence-Based Complement. Altern. Med. 10.1155/2012/632763

Ahmed, F., M.R. Asha, A. Urooj and K.K. Bhat, 2010. Ficus racemosa bark: Nutrient composition, physicochemical properties and its utilization as nutra tea. Int. J. Nutr. Metab., 2: 33-39.
Direct Link  |  

Akhir, N.A.M., L.S. Chua, F.A.A. Majid and M.R. Sarmidi, 2011. Cytotoxicity of aqueous and ethanolic extracts of Ficus deltoidea on human ovarian carcinoma cell line. Br. J. Med. Med. Res., 1: 397-409.
CrossRef  |  Direct Link  |  

Amiera, Z.U.R., M. Nihayah, I.F. Wahida and N.F. Rajab, 2014. Phytochemical characteristic and uterotonic effect of aqueous extract of Ficus deltoidea leaves in rats uterus. Pak. J. Biol. Sci., 17: 1046-1051.
CrossRef  |  Direct Link  |  

Arifin, N., 2005. Penyembuhan Semula Jadi Dengan Herba [Natural Healing with Herbs]. PTS Publications & Distributors Sdn. Bhd., Malaysia, ISBN-13: 9789833372294, pp: 1-3, (In Malay).

Aris, S.R.S., S. Mustafa, N. Ahmat, F.M. Jaafar and R. Ahmad, 2009. Phenolic content and antioxidant activity of fruits of Ficus deltoidea var angustifolia sp. Malaysian J. Anal. Sci., 13: 146-150.
Direct Link  |  

Awang, N.A., S.M.Z. Hasan and M.S.B. Shafie, 2013. Morphological study of Ficus deltoidea jack in Malaysia. J. Agric. Sci. Technol. B, 3: 144-150.
Direct Link  |  

Bafor, E.E., E.K.I. Omogbai and R.I. Ozolua, 2010. In vitro determination of the uterine stimulatory effect of the aqueous leaf extract of Ficus exasperata. J. Ethnopharmacol., 127: 502-507.
CrossRef  |  PubMed  |  Direct Link  |  

Balakrishna, M. and S.K. BhattacHarjee, 1991. Studies on propagation of ornamental trees, through stem cuttings. Indian J. Horticult., 48: 87-94.
Direct Link  |  

Berg, C.C. and E.J.H. Corner, 2005. Moraceae (Ficus). Flora Malesiana, Series I (seed plants). Flora Malesiana, 17: 17-29.

Bonte, F., M. Dumas, C. Chaudagne and A. Meybeck, 1994. Influence of asiatic acid, madecassic acid and asiaticoside on human collagen I synthesis. Planta Medica, 60: 133-135.
CrossRef  |  PubMed  |  Direct Link  |  

Bunawan, H., N.M. Amin, S.N. Bunawan, S.N. Baharum and N.M. Noor, 2014. Ficus deltoidea jack: A review on its phytochemical and pharmacological importance. Evidence-Based Complement. Altern. Med. 10.1155/2014/902734

Burkill, I.H. and M. Haniff, 1930. Malay village medicine. Garden's Bull., 6: 167-332.

Cook, J.M.C. and J.Y. Rasplus, 2003. Mutualists with attitude: Coevolving fig wasps and figs. Trends Ecol. Evol., 18: 241-248.
CrossRef  |  Direct Link  |  

Corner, E.J.H., 1969. The complex of Ficus deltoidea; A recent invasion of the Sunda Shelf. Philosoph. Trans. R. Soc. London, 256: 281-317.
CrossRef  |  Direct Link  |  

Desaku, 2005. Mas cotek/Ficus deltoidea mistletoe fig (Moraceae). http://www.bio-asli.com/Herba/e_Herba/e_mascotek.asp.

Draman, S., M.A.M. Aris, Razman, S.F.U. Akter and H. Azlina et al., 2012. Mas cotek (Ficus deltoidea): A possible supplement for type II diabetes: (A pilot study). Pertanika J. Trop. Agric. Sci., 35: 93-102.
Direct Link  |  

Dzolin, S., R. Ahmad, M.M. Zain and M.I. Ismail, 2015. Flavonoid distribution in four varieties of Ficus deltoidea (Jack). J. Med. Plant Herbal Theraphy Res., 3: 1-9.
Direct Link  |  

Farsi, E., A. Shafaei, S.Y. Hor, M.B.K. Ahamed, M.F. Yam, M.Z. Asmawi and Z. Ismail, 2013. Genotoxicity and acute and subchronic toxicity studies of a standardized methanolic extract of Ficus deltoidea leaves. Clinics, 68: 865-875.
CrossRef  |  Direct Link  |  

Farsi, E., A. Shafaei, S.Y. Hor, M.K. Ahamed and M.F. Yam et al., 2011. Correlation between enzymes inhibitory effects and antioxidant activities of standardized fractions of methanolic extract obtained from Ficus deltoidea leaves. Afr. J. Biotechnol., 10: 15184-15194.
Direct Link  |  

Felton, A.M., A. Felton, J.T. Wood and D.B. Lindenmayer, 2008. Diet and feeding ecology of Ateles chamek in a Bolivian Semihumid forest: The importance of Ficus as a staple food resource. Int. J. Primatol., 29: 379-403.
CrossRef  |  Direct Link  |  

Gamlath, M., K. Abeywickrama and S. Wickramarachchi, 2010. Root growth promotion of Ficus species during air-layering. Cey. J. Sci. (Bio. Sci.), 39: 45-51.
Direct Link  |  

Gregory, M., K.P. Vithalrao, G. Franklin and V. Kalaichelavan, 2009. Anti-Ulcer (Ulcer-Preventive) activity of Ficus arnottiana Miq. (Moraceae) leaf methanolic extract. Am. J. Pharmacol. Toxicol., 4: 89-93.
CrossRef  |  Direct Link  |  

Grossman, M.I., 1981. Peptic Ulcer: A Guide for the Practicing Physician. Year Book Medical Publishers, Chicago, USA., ISBN: 0815140096, pp: 1-35.

Hakiman, M. and M. Maziah, 2009. Non enzymatic and enzymatic antioxidant activities in aqueous extract of different Ficus deltoidea accessions. J. Med. Plant Res., 3: 120-131.
Direct Link  |  

Hassanein, A.M.A., 2013. Factors influencing plant propagation efficiency via stem cuttings. J. Hortic. Sci. Ornamental Plants, 5: 171-176.
Direct Link  |  

Jamilah, M.S., N. Ismalia and N. Elyani, 2005. Ecological notes on Ficus deltoidea jack. on heath vegetation of BRIS soil of Terengganu. Proceedings of the 8th Symposium of Applied Biology, June 22-23, 2005, Marriot Putrajaya Hotel, Putrajaya, Malaysia -.

Kalman, D.S.,H.I. Schwartz, S. Feldman,and D.R. Krieger, 2013. Efficacy and safety of Elaeis guineensis and Ficus deltoidea leaf extracts in adults with pre-diabetes. Nutr. J., Vol. 12.

Kochummen, K.M. and G. Rusea, 2000. Moraceae. Tree Flora Sabah Sarawak, 3: 181-334.

Lansky, E.P. and H.M. Paavilainen, 2010. Figs: The Genus Ficus. CRC Press, Boca Raton, FL., ISBN-13: 9781420089677, pp: 1-4.

Lee, K.W., Y.J. Kim, H.J. Lee and C.Y. Lee, 2003. Cocoa has more phenolic phytochemicals and a higher antioxidant capacity than teas and red wine. J. Agric. Food Chem., 51: 7292-7295.
CrossRef  |  Direct Link  |  

Lopez-Vaamonde, C., D.J. Dixon, J.M. Cook and J.Y. Rasplus, 2002. Revision of the Australian species of Pleistodontes (Hymenoptera: Agaonidae) fig-pollinating wasps and their host-plant associations. Zool. J. Linnean Soc., 136: 637-683.
CrossRef  |  Direct Link  |  

Maisuthisakul, P., M. Suttajit and R. Pongsawatmanit, 2007. Assessment of phenolic content and free radical-scavenging capacity of some thai indigenous plants. Food Chem., 100: 1409-1418.
CrossRef  |  Direct Link  |  

Maizatul, H.O., W. Mullen and A. Crozier, 2011. Identification of proanthocyanidin dimers and trimers, flavone C-Glycosides and antioxidants in Ficus deltoidea, a Malaysian herbal tea. J. Agric. Food Chem., 59: 1363-1369.
CrossRef  |  Direct Link  |  

Mat, N., N.A. Rosni, N.Z. Ab Rashid, N. Haron and Z.M. Nor, et al., 2012. Leaf morphological variations and heterophylly in Ficus deltoidea Jack (Moraceae). Sains Malaysiana, 41: 527-538.
Direct Link  |  

Misbah, H., A.A. Aziz and N. Aminudin, 2013. Antidiabetic and antioxidant properties of Ficus deltoidea fruit extracts and fractions. BMC Complement. Altern. Med., Vol. 13. 10.1186/1472-6882-13-118

Mohammad, N., Y.K. Wei and N.F.A. Bakar, 2012. Determination of mineral content in the Ficus deltoidea leaves. J. Sains Kesihatan Malaysia, 10: 25-29.
Direct Link  |  

Nur Fatihah, H.N., M. Nashriyah, A.R. Nor Zaimah, M. Khairil and A.M. Ali, 2014. Leaf morphology and anatomy of 7 varieties of Ficus deltoidea (Moraceae). Turk. J. Bot., 38: 677-685.
CrossRef  |  Direct Link  |  

Oh, M.J., M. Abdul Hamid, S. Ngadiran, Y.K. Seo, M.R. Sarmidi and C.S. Park, 2011. Ficus deltoidea (Mas cotek) extract exerted anti-melanogenic activity by preventing tyrosinase activity in vitro and by suppressing tyrosinase gene expression in B16F1 melanoma cells. Arch. Dermatol. Res., 303: 161-170.
CrossRef  |  Direct Link  |  

Ong, S.L., A.P.K. Ling, R. Poospooragi and S. Moosa, 2011. Production of flavonoid compounds in cell cultures of Ficus deltoidea as influenced by medium composition. Int. J. Med. Arom. Plants, 1: 62-74.
Direct Link  |  

Rahimi, R., S. Nikfar, B. Larijani and M. Abdollahi, 2005. A review on the role of antioxidants in the management of diabetes and its complications. Biomed. Pharmacother., 59: 365-373.
PubMed  |  Direct Link  |  

Ronsted, N., G.D. Weiblen, W.L. Clement, N.J.C. Zerega and V. Savolainen, 2008. Reconstructing the phylogeny of figs (Ficus, Moraceae) to reveal the history of the fig pollination mutualism. Symbiosis, 45: 45-55.
Direct Link  |  

Salleh, N. and V.N. Ahmad, 2013. In-vitro effect of Ficus deltoidea on the contraction of isolated rat's uteri is mediated via multiple receptors binding and is dependent on extracellular calcium. BMC Compl. Altern. Med., Vol. 13. 10.1186/1472-6882-13-359

Santamaria, A.B., 2008. Manganese exposure, essentiality and toxicity. Indian J. Med. Res., 128: 484-500.
Direct Link  |  

Serio-Silva, J.C., V. Rico-Gray, L.T. Hernandez-Salazar and R. Espinosa-Gomez, 2002. The role of Ficus (Moraceae) in the diet and nutrition of a troop of Mexican howler monkeys, Alouatta palliata mexicana, released on an island in southern Veracruz, Mexico. J. Trop. Ecol., 18: 913-928.
CrossRef  |  Direct Link  |  

Shafaei, A., N.S. Muslim, Z.D. Nassar, A.F.A. Aisha, A.M.S.A. Majid and Z. Ismail, 2014. Antiangiogenic effect of Ficus deltoidea Jack standardised leaf extracts. Trop. J. Pharm. Res., 13: 761-768.
Direct Link  |  

Simon, V.N., 2004. The ultimate challenge how fig trees are pollinated. Veld and Flora, South Africa, USA., March 2004, pp: 13-15.

Smilkstein, M.J., S.C. Smolinske, K.W. Kulig and B.H. Rumack, 1988. Severe hypermagnesemia due to multiple-dose cathartic therapy. West J. Med., 148: 208-211.
Direct Link  |  

Starr, F., K. Starr and L. Loope, 2003. Mistletoe fig, Moraceae. Ficus Deltoidea, 2: 1-5.

Suarez, J., M.D. Herrera and E. Marhuenda, 1996. Hesperidin and neohesperidin dihydrochalcone on different experimental models of induced gastric ulcer. Phytother. Res., 10: 616-618.
CrossRef  |  Direct Link  |  

Suguna, L., P. Sivakumar and G. Chandrakasan, 1996. Effects of Centella asiatica extract on dermal wound healing in rats. Indian J. Exp. Biol., 34: 1208-1211.
PubMed  |  Direct Link  |  

Sulaiman, M.R., M.K. Hussain, Z.A. Zakaria, M.N. Somchit, S. Moin, A.S. Mohamad and D.A. Israf, 2008. Evaluation of the antinociceptive activity of Ficus deltoidea aqueous extract. Fitoterapia, 79: 557-561.
CrossRef  |  PubMed  |  Direct Link  |  

Suryati, S., H. Nurdin, D. Dachriyanus and M.N.H. Lajis, 2011. Structure elucidation of antibacterial compound from Ficus deltoidea jack leaves. Indonesian J. Chem., 11: 67-70.
Direct Link  |  

Tchinda, A.T., M.H. Tchuendem, S.N. Khan, I. Omar, F. Ngandeu, E.A.N. Pepin and I.M. Choudhary, 2008. Antioxidant activity of the crude extract of the fruits of Pycnanthus angolensis and α-glucosidase inhibitory activity of its constituents. Pharmacologyonline, 1: 422-431.
Direct Link  |  

Turner, I.M., 1995. A catalogue of the vascular plants of Malaya. Gardens Bull. Singapore, 47: 1-5.
Direct Link  |  

Watcho, P., E. Ngadjui, P.A. Nkeng-Efouet, T.B. Nguelefack and A. Kamanyi, 2011. Evaluation of in vitro uterotonic activities of fruit extracts of Ficus asperifolia in rats. Evid. Based Compl. Alternat. Med.

Woon, S.M., Y.W. Seng, A.P.K. Ling, S.M. Chye and R.Y. Koh, 2014. Anti-adipogenic effects of extracts of Ficus deltoidea var. deltoidea and var. angustifolia on 3T3-L1 adipocytes. J. Zhejiang Univ. Sci. B, 15: 295-302.
CrossRef  |  Direct Link  |  

Xiao, Z.P., Z.Y. Peng, M.J. Peng, W.B. Yan, Y.Z. Ouyang and H.L. Zhu, 2011. Flavonoids health benefits and their molecular mechanism. Mini-Rev. Med. Chem., 11: 169-177.
Direct Link  |  

Zahra, M.A.S.F., A.A. Mahmood, M.A. Hapipah, M.N. Suzita and I. Salmah, 2009. Anti-ulcerogenic activity of aqueous extract of Ficus deltoidea against ethanol-induced gastric mucosal injury in rats. Res. J. Med. Sci., 3: 42-46.
Direct Link  |  

Zakaria, Z.A., M.K. Hussain, A.S. Mohamad, F.C. Abdullah and M.R. Sulaiman, 2012. Anti-inflammatory activity of aqueous extract of Ficus deltoidea. Biol. Res. Nurs., 14: 90-97.
CrossRef  |  Direct Link  |  

Zino, S., M. Skeaff, S. Williams and J. Mann, 1997. Randomised controlled trial of effect of fruit and vegetable consumption on plasma concentrations of lipids and antioxidants. Br. Med. J., 314: 1787-1791.
CrossRef  |  PubMed  |  Direct Link  |  

Zunoliza, A., S. Khalid, I. Zhari, M.A. Rasadah, P. Mazura, J. Fadzureena and S. Rohana, 2009. Evaluation of extracts of leaf of three Ficus deltoidea varieties for antioxidant activities and secondary metabolites. Pharmacog. Res., 4: 216-223.
Direct Link  |  

©  2017 Science Alert. All Rights Reserved
Fulltext PDF References Abstract