Abstract
Bintaro is a tropical mangrove plant often used as a shade tree found in Asia, Australia, Madagascar, and the Islands of the Western Pacific Ocean. The word Bintaro is also often pinned to its closest relative species, the Cerbera odollam. Flower color is one of the distinguishing features between these two species. Human poisoning with the cardiotoxic plant Bintaro is common in Southeast Asia because it bears a fruit that yields a powerful poison that has been used for suicide and homicide, hence it is also called the “Indian suicide tree”. The seeds of Bintaro contain Cerberin, a cardiac glycoside toxin of the heart that blocks the calcium ion channels in heart muscles, resulting in disruption of the heartbeat most often fatally. The bio-active compound in the kernels of Bintaro varies due to which plant possesses other properties as well. The plant may also be used for medicinal purposes as it shows many pharmaceutical properties. The seeds of the plant have auspicious anticancer properties through apoptotic activity and the leaf extract of the plant was screened for its antioxidant activities. In addition, it is also used as an insecticide, pesticide, or antifungal agent. This review highlights the Pharmaceutical, toxicological, and environmentally friendly approaches of Bintaro.
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Introduction
Bintaro (Cerbera odollam and Cerbera manghas) is a dicotyledonous Angiosperm, a plant species, belonging to the poisonous Apocynaceae family (Wermuth et al. 2018). The plant is known by several names such as a pong-pong tree, Mango Laut, Blind rhino, Babuto, and Wood octopus (Ruekert et al. 2019; Sukmawati 2016). It occupies coastal and marshy areas (wet areas) along the seashores and rivers of the tropic including Southern India, Southeast Asia, Madagascar, and Australia (Shankar and Rai 2009). Due to its deadly toxic seeds, the genus name is derived from Cerberus, the hell dog from Greek mythology hence indicating the toxicity of the seeds. It is extensively unknown to the western world. Bintaro tree has a resilient nature and speedy growing so generally used to shadow the road. Typically, this tree has a height of up to 12–15 m tall, has shiny dark green leaves, is ovoid with delicate white and yellow flowers, and has a fragrance of Jasmine (Gaillard et al. 2004). It is a non-meal plant as it contains toxins in almost all parts inclusive of the trunk, flower, seed, and fruit. The plant has an extended history, In Madagascar, the seeds were utilized in sentence rituals to punish Kings and Queens (Sukmawati 2016). The plant bears a fruit, softball-sized, similar to that of the green mango called Othalanga, which turns into bright red at maturity (Maharana 2021). Each fruit contains one poisonous seed, these seeds are comprised of an alkaloid (cerberine, nitritolin, and theven) steroids, terpenoids, and saponins which are toxic and cause heart attack and sudden death (Musdja and Djajanegara 2019). The difficulty of finding cerberin in autopsies and the ability of strong spices to hide its flavor make it an ideal lethal weapon. In the South Indian state of Kerala, India, it accounts for half of all cases of plant poisoning, a condition that is the cause of a significant number of deaths, hence, it acts as a suicide and homicide agent (Sahoo and Marar 2018). The scientific exploitation of plans revealed due to the presence of the natural bio-active compound in a plant shows multiple biological effects including anticancer, anti-inflammatory, analgesic, antibacterial properties, etc. The plant’s leaves have been shown cytotoxic activity against various types of cancer. It is well-known that the prevention of cancer and chemotherapy, which are based on natural ingredients, is less harmful than any other treatments (Harlev et al. 2012). Botanists, microbiologists, and chemist are trying their best to find a cure for various diseases, where, plant like Bintaro comprises numerous phytochemicals which includes alkaloids, terpenoids, and tannin that have been reported to have antimicrobial and analgesic properties (Aziz et al. 2021). Therefore, Bintaro as a medical herb can be introduced into medication therapy to achieve better outcomes. Various studies have also highlighted its potential aspects as bioinsecticide and pesticide in the agricultural field. It has a unique agent that drives away or kills insect pests and inhibits pest feeding activity. The leaf and fruit extract of the plant has antifungal properties that have the potential to kill or inhibit the growth of any fungus. Thus, this clearly indicates that it has the potential of being a bio fungicide that could be employed as an alternative to synthetic fungicide. Organic plant-based pesticides and fungicides against insects and fungus respectively, not only be effective but also safer and eco-friendly. Bintaro has non-edible vegetable oil in its seeds, therefore it can also act as a raw material for the production of biodiesel (Zikri et al. 2020). As this plant has tremendous benefits, thus it has various applications and therefore can be utilized in adverse fields.
Significant phytochemical constituents
Phytochemicals are the chemicals produced through the plant via primary and secondary metabolism (Table 1). They are most often involved in the biological activity of the plants, and may also play a role in plant growth and defense against a pathogen, or predator (Chu et al. 2015). Some phytochemical has been used as poisons and others as conventional remedy. They typically help the plant to withstand bacteria, fungi and plant virus infections as well as the consumption by insects and other animals. Various essential phytochemicals have been reported to be found in Bintaro, such as steroids, tannins, terpenoids, flavonoids, phenol, saponins, cardiac glycosides, lignans, and iridoids in different parts of the plants such as leaves, stem, and root (Maharana 2021). Steroids, tannins, and terpenoids are believed to have antifungal and antimicrobial properties in a plant (Chu et al. 2015). Phenolic acids are accountable for antioxidant activities (Piazzon et al. 2012). Besides these, cardiac glycoside exhibits cytotoxic activity against carcinogenic cell that acts as an anticancer agent (Cheenpracha et al. 2004).
Toxicology of Bintaro
One complete Ingestion of a single seed of Bintaro can lead to a fatal heart attack (Wermuth et al. 2018). In the plant, the seed is the most toxic part and belongs to several Cardiac glycosides, including Cerberin, the most poisonous ingredient among other components (Tsai et al. 2008). Apart from Cerberin, there is a mixture of other bioactive components such as Odollin, Neriifolin, and Cerberoside (Misek et al. 2018). Due to its violent cardiotoxic nature, it is used for the purpose of suicide and as a Homicidal agent. According to various studies, the bioactive compound in Bintaro can lead to the death of insects. The higher the concentration of the chemical compound, the higher the mortality rate of the insects (Sholahuddin et al. 2018); thus, it may also be used as a natural pesticide for pest management by inhibiting the feeding activity of the pest on the plant. Animal Studies have shown that the consumption of a very small amount of kernel could lead to death. The minimum fatal dose is found in half of the kernel. It can be 1.8 mg/kg and 3.8 mg/kg in dogs and cats respectively. So, ingesting half or a whole kernel would be enough to cause death. The lethal period after the ingestion can occur either in 3–6 h or within 1–2 days (Menezes et al. 2018). Cardiac glycosides like Cerberin and Neriifolin cause heart failure by binding and blocking with Na + K + ATPase pump (Hossan et al. 2019). This will leads to the accumulation or increase in the concentration of Na + inside the cell and prevent K + influx which will lead to a decrease in the concentration of K + outside the cell and causes an electrolyte imbalance as shown in Fig. 1.
Mechanism of the active component (Cerberin) of Bintaro Blocking the Na + K + pump and causing an electrolytic imbalance
It stimulates the sarcoplasmic reticulum to open its Ca2 + channels, leading to Ca2 + accumulation in the cells causing the production of lactic acid, which in turn leads to academia, myocardial contractility, and, ultimately, death. Ingestion of a single seed from the plant in the biological systems of the human body causes different biological effects. The most common effects of toxicity that are observed in the human body are nausea, vomiting, irregular heartbeat, dysfunction of organelles, myocardial infarction, thrombocytopenia, dilated pupils, and bradycardia (Bernshteyn et al. 2020). The route of administration of Bintaro in the human body and its biological effects are represented in Fig. 2.
The Biological effects of Bintaro’s seed targeting various bodily biological systems
Pharmaceuticals applications
Pharmaceutical is the term that is used for the substances that are used in the diagnosis, treatment, or prevention of diseases. Bintaro is one of the plants that have many pharmaceutical properties like anti-cancer, anti-bacterial, analgesic, anti-inflammatory, and many more. The plant’s anticancer capabilities have been examined extensively in terms of its preventative, protective, tumor-suppressing, immunomodulatory, and apoptotic actions against a variety of cancers. Similarly, some specific secondary metabolites of the plant show analgesic effect and are able to lower the pain. Due to the presence of its therapeutic potential diseases such as rheumatism, dysuria and ringworm may be treated (Fig. 3).
Illustration of pharmaceuticals applications of Bintaro
Anti-cancer properties
In this century, cancer has become one of the leading causes of death and disease. In the medical field of cancer treatment, several types of new drugs and synthetic therapies have emerged, including radiation therapy, chemotherapy, and immunotherapy. However, they are still subject to negative side effects (Das et al. 2015). Researchers and botanists recommend paying special attention to plants as the primary source for safe and effective cancer treatment. Plants like Bintaro, which are compared to artificial drugs are an amazing source for the development and manufacture of effective, well tolerated, and safe anti-cancer drugs. The phytochemicals contained in a Bintaro can inhibit the growth, colony formation, and migration of cancer cells. Numerous subsequent in vitro and in vivo studies confirmed that few cardiac glycosides appear to be selective in killing cancer cells, including human lung, pancreatic, and skin cancer cells (Mutalip et al. 2014). The new findings showed that digoxin, digitoxin, and ouabin are known to be involved in a complex cellular signaling mechanism that leads to selective tumor control but not normal cell proliferation (Syarifah et al. 2011). It is typically believed that the formation of growth-promoting oxidants (reactive oxygen species ROS) is a prime catalyst in the stages of neoplasm promotion and progression. The prooxidant enzymes are evoked or activated by varied tumor promoters for example cyclooxygenases (COX) and lipoxygenases (LOX). flavonoids are significantly effective at inhibiting COX and LOX and thus inhibit tumor cell proliferation (Ren et al. 2003). Bintaro leaf extract has been investigated to be able to strongly suppress MCF7 and T47D cells. The leaf extract was also tested against breast cancer (MCF7 and T47D), and ovarian cancer (SKOV3 and CAOV3) (Syarifah et al. 2011). Cardenolide and 17β-Neriifolin from Bintaro roots have an antiproliferative effect against human CO12 colon cancer cells (Chang et al. 2000). Cardenolide glycoside of 2′-o-acetylacerlasid A, 17α Neriifolin, 17β-Neriifolin, Cerberin, 7,8—Dehydrocerberin, Deacetyltanghinin, and Tanghinin isolated from Bintaro are cytotoxic to human oral cancer cells (KB), human breast cancer cells (BC) and the human lung NCI-H187 Carcinogenic cells (Cheenpracha et al. 2004; Laphookhieo et al. 2004). Tanghiiegnin reduces the activity of HL-60 promyelocytic leukemia cells with an IC50 in a time and dose-based manner (Wang et al. 2010). Neriifolin from the leaf and fruit of the plant is effective against stomach cancer as it reduces the viability of HepG2 cells of human hepatocellular carcinoma and also induces the arrest of the S and G2/M phases of the cell cycle (Zhao et al. 2011).
Figure 4 shows that the flavonoids that have been isolated from the leaf of the plant using scientific techniques are an efficient treatment for carcinoma cells because they induce cell death and inhibit the further proliferation of the cell.
Illustration of leaf extract of Bintaro (flavonoids) on carcinoma cells
Antioxidant and Analgesic Properties
Bintaro, from a family of Apocynaceae, could be a robust supply of antioxidants and analgesic, mainly, flavonoids, tannins, and phenolic compounds, indicating its potential use in pharmacological products designed to improve individual standards (Iqbal et al. 2017). The chloroform and carbon tetrachloride fractions from the trunk bark of the plant showed the strongest antioxidant activity (Wong et al. 2013). To predict the antioxidant activity of the plant, A DPPH assay was performed in which the ethanol extract converted the free radical DPPH into a stable form of DPPHH by donating electrons or hydrogen radicals (Monjur-Al-Hossain et al. 2013). The extract showed a concentration-dependent DPPH radical scavenger activity due to the presence of phenols, and flavonoids which were comparable to that of the standard antioxidant ascorbic acid (Iqbal et al. 2017; Monjur-Al-Hossain et al. 2013).
Bintaro’s methanolic extract was found to reduce sleepiness and potentiate pentobarbital-induced sleep time in mice, suggesting its central depressant activity, thus indicating a probable sedative action (Ahmed et al. 2006). Also, the leaf extract contains cerberin, which decreases the duration of action of pentylenetetrazole-induced tonic seizures and mortality and creates a hypnotic effect (Tripathi 2021). The extract may have the ability to inhibit the release of prostaglandins to relieve pain (Monjur-Al-Hossain et al. 2013). The peripheral analgesic effects of the plant extract can be linked to the inhibition of cyclooxygenases and/or lipoxygenases, while the central analgesic effect of the extract can be interfered with by the inhibition of central pain receptors (Hossain et al. 2013). Quercetin (a flavonoid) showed an analgesic effect and was able to lower the pain threshold in the hot plate test (the application of heat stimulates the mice to pain) at a dose of 3.5 mg/kg (Xiao et al. 2016). The effective doses of quercetin (60–200 mg/kg) in various models of animals have an analgesic effect equivalent to that of aspirin (100 mg/kg) or morphine (2 mg/kg) (Xiao et al. 2016). The extract yields mild writhing inhibition similar to the conventional drug Diclofenac sodium which suggests large analgesic activity (Hossain et al. 2013).
Anti-bacterial and anti-viral properties
The combination of Bintaro’s antibacterial and antiviral properties due to the presence of significant Phytochemicals represents a doubtless path-breaking interference to lessen the spread of disease-causing pathogens. Tests/experiments were carried out to determine the antibacterial activity of the ethanolic extract of the Bintaro flower using a in vitro well diffusion technique. The researchers observed that the ethanolic extract from Bintaro flowers indicates an antibacterial effect against Staphylococcus aureus (Lestari et al. 2017). This approach is extensively applicable and suitable for the initial screening of substances for their antibacterial properties (Lestari et al. 2017; Ahmed et al. 2008). The results of the tests of antibacterial activity showed that the zone of inhibition value 21 already had an antibacterial activity of 30.53 mm at a concentration of 10%. It also shows an increase in concentration also increases the zone of inhibition of Streptococcus aureus (Lestari et al. 2017). A similar test was performed against Streptococcus pyogenes, Salmonella typhi, Shigella flexneri, and Shigella dysenteriae. The Bintaros seed extract was found to have moderate antibacterial activity against Staphylococcus pyogenes and Salmonella typhi, while it had mild antibacterial activity against Shigella flexneri and Shigella dysenteriae (Ahmed et al. 2008). According to studies, butanol and hexane extract from Bintaro leaves have a sufficiently strong antibacterial effect on K. pneumonia, while butanol extract from Bintaro leaves has a greater effect than Bintaro hexane extract (Musdja et al. 2018). Bintaro leaf ethyl acetate and dichloromethane extract also have an antibacterial effect against gram-positive (S. aureus) and gram-negative (E. coli) bacteria (Musdja and Djajanegara 2019). Antiviral and cytotoxic activity was also observed in Bintaro, showing selective antiviral activity towards Viruses of vesicular stomatitis (VSV) (Kemal et al. 2015). Bintaro fruit ethanol extract was evaluated for antiviral properties, 0.0050.1 mg/ml against herpes simplex virus (HSV). A crude extract from the fruit of Bintaro can inhibit the growth of HSV (Manoharan and Kaur 2013). According to these studies, it can be concluded that Bintaro can be used as a medicinal plant to deal with fever, malaria, diabetes and gastrointestinal problems, and other infectious diseases (Musdja and Djajanegara 2019). Bintaro cardiac glycoside antiviral activities can effectively suppress viral protein translation, interrupt previous viral mRNA splicing, to inhibit various viral diseases such as HIV, HMV, Ebola, Chikungunya, and coronavirus (Reddy et al. 2020).
Anti-inflammatory properties
Inflammation occurs with any form of physical injury. Under ordinary situations it is auto-limited however can turn into persistent and chronic inflammatory disorder would possibly develop. Symptoms of inflammation include redness, swelling from heat, and pain (Ferrero Miliani et al. 2007). There are two forms of inflammation acute and chronic. Acute inflammation is speedy and transient while chronic inflammation is constant and has an extended healing time (Byeon et al. 2012). Bintaro is a medicative herb historically used to improve the clinical symptoms of inflammation or inflammatory disorders due to the presence of flavonoids that act as anti-inflammatory agents (Yi et al. 2016). In-vitro research of anti-inflammatory impact on mouse model through methanol extract of Bintaro towards LPS stimulated macrophages inducing hepatitis and peritonitis shows the anti-inflammatory properties of Bintaro (Yi et al. 2016). The activated inflammatory cells keep their inflammatory impact by generating histamines, prostaglandins, reactive oxygen species (ROS), and nitrogen reactive species which include Nitric oxide (NO) (Massarotti, 2008). Other inflammatory mediators like Src play a vital role in sustaining this cellular response. It is a tyrosine-protein kinase that is involved in the functional activation of the macrophage-mediated inflammatory response (Byeon et al. 2012). Kaempferol is an active flavonoid found in Bintaro methanol extract and plays a crucial role in its auspicious anti-inflammatory properties by inhibiting the route of Syk/Src and exerting an anti-inflammatory response (Jeong et al. 2014). In recent studies, it has been found that the administration of kaempferol also shows anti-inflammatory effects against HCl-induced gastric lesions and LPS-induced pancreatitis. The efficiency of kaempferol evaluating with the performance of well-known capsules which include ranitidine and indomethacin appears to signify its capacity and possible use as anti-inflammatory remedy or agent (Kim et al. 2015). Likewise, Quercetin, another surprising flavonoid, has been reported to have potent and persistent anti-inflammatory effects. It inhibits the production and blocks the pathway of inflammation-producing enzymes namely, COX and LOX (Li et al. 2016). Therefore, Bintaro can be used as a medication remedy for treating various diseases such as Alzheimer’s, Rheumatoid arthritis, Diabetes, Osteoporosis, etc. (Kaur et al. 2013).
Figure 5 shows the enzymes COX and LOX cause inflammation by releasing archednoic acid, which is a precursor to prostaglandins that cause an inflammatory response. The inhibition of these enzymes by quercetin reduces the release of archednoic acid and prevents inflammation.
Illustration of the anti-inflammatory mechanism of Quercetin
Neuropharmacological Properties
Neuroprotection means the mechanism which is capable of battling down the nervous system towards neural harm due to numerous neurodegenerative issues which include Alzheimer’s disorder, Anxiety, Parkinson’s disorder, etc. Bintaro has been stated for its herbal neuroprotective activities (Kumar et al. 2015). Bintaro’s phytochemicals, including triterpenoids, alkaloids, flavonoids, saponins, etc., are found in a wide variety of plant components that can alter the neurotransmitters and can change one’s behavior, mood, and mental state in living organisms (Kumar et al. 2015; Yunilla 2016). Various neuropharmacological properties of Bintaro are summarized in Fig. 5.
Anxiety
Anxiety disorders are major problems of mental health that may have a negative impact on a person’s day-to-day existence. It was reported that intake of Betulinic acid produces anti-anxiety activity in animals. Prescription drugs containing betulinic acid have been emphasized as a means of remedy for preventing or treating anxiety (Gangwal 2013). Sedation and hypnotics researchers have studied that the administration of beta-amyrin potentiates the anesthetic effect in test animals (mice), so α/β-amyrin (triterpenoid) was known for its sedative effect (Otimenyin 2022) (Fig. 6).
Illustration of various neuropharmacological properties
Memory
Studies have discovered that the combination of triterpenoid and saponins (Escin) extracted from the plant that has been confirmed to enhance learning and memory recovery and decrease hippocampal injury in cerberal ischemic mice (Zhang et al. 2010a, b).
Neuroprotective activities
Asiatic acid has been studied for its neuroprotective effects by neutralizing reactive species of elements. Various efforts have been made to get anti-Alzheimer agents from herbal resources. Cannabinoids found to act as anti-Alzheimer agents (Gangwal 2013).
Pain and Nociception
Studies stated that triterpenoids perform a crucial function in the remedy of pain (Gangwal 2013). Researchers have investigated the anti-nociceptive effect of euphol towards nociceptive reaction caused by ligature of the sciatic nerve (Scott et al. 2004). In animal models, oleanolic acid has inhibitory effects on the acute nociception induced by capsaicin (Maia et al. 2006).
Depression
A condition that affects mental health and is defined by an ongoing sad mood or a lack of enthusiasm in tasks, both of which cause severe damage in day-to-day living. There are many first-line medications available for the therapy of such mental disorders; however, these medications may also have some undesirable side effects. The discovery of anxiolytic or depressive pharmaceuticals derived from plants offers a number of advantages over more conventional treatments. β amyrin and norepinephrine are additionally determined to act as an antidepressant (Otimenyin 2022). Flavonoids are also reported as an antidepressant (Kumar et al. 2015).
Eco-friendly applications
To be earth-friendly or not detrimental to the ecosystem is the precise meaning of the term "eco-friendly." The applications which support the ecosystem and environment and do not harm are called eco-friendly applications. A tropical mangrove plant Bintaro is considered as an eco-friendly plant as it has three major eco-friendly applications as shown in Fig. 7 below. The below applications can be considered as an innovative approach towards sustainable development as it has great economic and cultural importance and potential.
Illustration of eco-friendly applications of Bintaro
Biodiesel production
Environmental issues arising from the continuous consumption and depletion of energy fuels, stimulate studies into alternative energy sources (Husin et al. 2018). Many scientists are researching for new alternative energy sources where Bintaro oil is one of the alternative energy sources for future biodiesel Production (Bhikuning and Hafnan 2019; Rizki et al. 2018). It is the non-edible vegetable oil that can surely replace fossil diesel (Rizki et al. 2018; Marlinda et al. 2016). It is defined as the long chain of mono-alkyl esters of fatty acids derived from vegetable oil with or without a catalyst (Rizki et al. 2018). Various studies and strategies have been followed for the production of biodiesel, the most preferred process for biodiesel production is two-step esterification and transesterification to reduce impurities and the acid value of the oil in order to convert it into biodiesel (Rizki et al. 2018) that can be made on a huge scale and also the mentioned process of the manufacturing process is extremely simple and quick. According to studies, Bintaro seeds contain a large proportion of 46–64% of oil thus, they can be utilized as a raw material for the production of biodiesel (Sutapa and Ropa 2019). Biofuel can be mixed with conventional fuel in any percentage. Biodiesel mixed with diesel contributes many valuable properties to the diesel engine (Noor et al. 2018). The combination of Diesel fuel and biodiesel emits fewer harmful gases than diesel fuel (Patel and Sankhavara 2017). The best thing about Bintaro biodiesel is that its physical and chemical properties such as density, viscosity, flash point, etc. meet the standard values of ASTM, D6751, and EN14214 (Ong et al. 2014; Lie et al. 2018). The other advantages of using biodiesel over petroleum diesel are biodegradable, highly energy-efficient, non-toxic, low-combustion, easily available, renewable, and environmentally friendly fuel (Noor et al. 2018). These efforts can reduce reliance on petroleum-derived fuels and provide a more environmentally friendly fuel (Ong et al. 2014).
Bio-insecticide and larvicidal activities
The Bintaro plant comprises of active phytochemicals that can be used as organic bioinsecticidal, pesticides, and for larvicidal effects, and thus, the use of natural insecticides and pesticides in agricultural fields can suppress the growth of insects, reduce damage to crops and increase crop production (Haryanta et al. 2020). It was found that the extract from the Bintaro plant possesses an inhibitory and lethal effect on the development of Riptortus linearis, a pod-sucking pest that infects soybean plants and can affect plant production both qualitatively and quantitatively (Haryanta et al. 2020; Krisnawati and Adie 2018). Bintaro is also reported to have biological activity against insects as a growth inhibitor, food deterrent, etc. Oleic acid extracted from Bintaro seeds indicates insecticidal activity against the Subterranean termite Coptotermmes gestroi and the drywood termite Cryptotermes cynocephalus (Tarmadi et al. 2014). Another active biocompound called flavonoid (quercetin), which is widely distributed in Bintaro, could be useful as a termite control agent. Flavonoids are said to be associated with resistance to insect infestation and also to have an anti-feedant effect against C. formosanus (Ohmura et al. 2000). The Bintaro fruit extract has been shown to have anti-termite and larvicidal effects. In the bioassay test of a sample of Bintaro fruit and subsequent extraction with the maceration method using methanol, it was found that the hexane fraction of the Bintaro fruit has the highest mortality rate against S. oryzae (Guswenrivo et al. 2013). The methanol flower extract also showed high potential in terms of termite mortality, termite decay, and soil burial decay against C. Optotermes gestroi (Hashim et al. 2009). Mosquitoes act as vectors of dangerous human diseases and are one of the major public health problems. Aedes aegypti is a vector of dengue. Chemical treatment is an effective however unsafe method for the environment, so it is important to develop and increase plant-based treatment to eliminate these problems (Tarmadi et al. 2018). Various studies and experiments have been carried out to eliminate mosquito larvae naturally. It was found that the crude extract from Bintaro seeds and leaves has a significant impact on larval mortality and inhibited the development of larvae in pupae. The higher the concentration of Bintaro seed and leaf extract, the faster it kills the insects (Tarmadi et al. 2018; Wahyuni et al. 2018). Another pathogenic vector is Culex quinquefasciatus, which is responsible for the spread of the Arbovirus. Bintaro seed extract using ethyl acetate and n-hexane shows high larvicidal activity against Culex quinquefasciatus, indicating that Bintaro could be used for larval control (Meisyara et al. 2020).
Biofungicides
The intensive use of fungicides in the agriculture field has resulted in environmental pollution that poses a significant risk to human health, so there is a need to develop natural plant-based biofungicides (Chu et al. 2015). The antifungal bioassay of the ethanolic extract from leaves and fruits was done through Kirby-Bauer disk diffusion test method, it was found that the extract from Bintaro leaves shows an antifungal effect of killing fungi like Aspergillus niger, Fusarium oxysporum and Penicillium citrum (Chu et al. 2015). Methanol leaf extract of Bintaro shows the presence of antifungal effect higher than the preferred standard antifungal drug fluconazole, as the leaf extract possesses a fantastic ability to apply as an antifungal agent against fungus like Saccharomyces cerevisiae and C. Albicans (Sahoo and Marar 2018). Studies have also shown that phytochemicals from Bintaro seeds also have an antifungal effect against C. Albicans (Sukmawati 2016). In antifungal paper disk assay, methanol wood extract of Bintaro was reported to have an antifungal effect against Trametes Versicolor, Pcynoporus sanguineus, and Schizophyllum commune (Hashim et al. 2009). Penicillium digitatum is one of the most common pathogens causing post-harvest rot in fruits (Singh et al. 2015). Tannins, a significant secondary plant metabolite in Bintaro, acted against Penicillium digitatum by inhibiting mycelial growth and reproductive structure (spore) germination (Zhu et al. 2019). Flavonoids have also been tested as antifungal agents against the genus Aspergillus (Gizaw et al. 2022). The antifungal activity of triterpenoid and saponins with oleanolic acid has been studied in vitro using the Agar dilution method and has been found to have a high rate of performance against yeast and dermatophyte species (Heng et al. 2014). Similarly, Phenols also show strong antifungal activity against a broad range of fungi, including Pseudomonas aeruginosa, and Staphylococcus aureus (Rao et al. 2010).
Bintaro: current progress and future perspective
The phytochemical, pharmacological, and eco-friendly characteristics of the Bintaro plant are addressed in this article. The use of this plant in traditional folk medicine includes that of an analgesic, an anticonvulsant, a cardiotonic, and for action that lowers blood pressure. Secondary metabolites found in this plant include saponins, terpenoids, and alkaloids. Additionally, this plant contains phenolic acids, flavonoids, cardiac glycosides, steroids, iridoids, lignans, and other chemicals (Maharana 2021). In terms of importance, cardiac glycosides are the most important phytochemical substances, followed by phenolic and terpenoid acids. Again, the leaf contains a wider variety of phytochemicals as well as a bigger amount of them, followed either by fruit, the seed, the stem, and the root. The plant has a wide range of pharmacological properties, including antioxidant, antitumor, anti-inflammatory, and antibacterial properties. This study may be of use to researchers who want to pursue future researches along similar lines (Maharana 2021).
The barks, leaves, fruits, and seeds of Bintaro trees all include components that may be used in the production of organic insecticides. It has been shown that the use of natural pesticides in agricultural settings may lower the populations, lessen the amount of damage done to crops, and raise the amount of food produced from such crops. An investigation on the effects of Grayak caterpillar feeding on Bintaro fruit is being carried out from the Research Institute of Rawa Land (Balittra) in Banjar Baru, in the province of South Kalimantan. The findings of a study that was carried out in 2008 revealed that as many as thirty percent of the grayak caterpillar’s colony perished within twenty-four hours after ingesting dips in Bintaro. After sixty to seventy-two hours after receiving this medication, the death rate increased to ninety to ninety-five percent (Purwanti et al. 2021).
According to the findings of a study conducted by Faperta IPB, bintaro fruit has the potential to be utilized as an alternative fuel. Even taking into account the findings of toxicity tests conducted on the secretion of the fruits, it can be concluded that Bintaro oil is appropriate for utilization as a fuel since it has an odor, smoke, as well as other remnants which are considered to be harmless (Hendra et al. 2016).
In Madagascar, heart problems are traditionally treated using seeds as part of the country’s traditional medicine. Bark has a number of medicinal applications, including laxative, antipyretic, and therapy for dysuria and ringworm. Rheumatism may be treated by rubbing fresh red fruit on affected areas of the legs. Oil, when massaged onto the skin, may relieve itching. Thus, focus of the researchers should be more towards medical field, economic field, and agricultural field that can help the different sectors worldwide.
Conclusion
Bintaro (Cerbera odollam, Cerbera manghas) is a widely distributed plant. The geographic range of Bintaro is in tropical, subtropical Southeast Asia. Although Bintaro is generally known to be extremely toxic, but the other constituents of plants have been described with various biological and pharmaceutical properties of medicinal importance due to the presence of significant secondary metabolites. Most types of phytochemicals are found in stems, leaves, fruit, seeds, etc. Several in vitro and in vivo studies and experiments have reported that Bintaro has amazing therapeutic potential that includes anti-cancer, antimicrobial, antioxidant, analgesic, and neuropharmacological activities that could improve an individual’s standard of living, so it could be a new way to alleviate human suffering. Various studies have also highlighted its potential as a bio- insecticide and bio fungicide in the agricultural sector as it has unique agents that could repel or kill insects and fungi respectively, clearly suggesting its potential to be a future bio-insecticide and fungicide that could be used as an alternative to synthetic ones. Also, Bintaro oil is one of the potential inedible oil that could be used as an alternative to petroleum for future biodiesel production. This is not only effective, but also safe and Environmental-friendly.
Data availability
Not applicable.
References
Abe F, Yamauchi T (1977) Studies on Cerbera I Cardiac glycosides in the seeds, bark, and leaves of Cerbera manghas L. Chem Pharmaceutical Bull 25(10):2744–2748
Ahmed F, Amin R, Shahid IZ, Sobhani MME (2008) Antibacterial, cytotoxic and neuropharmacological activities of Cerbera odollam seeds. Orient Pharm Exp Med 8(4):323–328. https://doi.org/10.3742/OPEM.2008.8.4.323
Ahmed F, Hossain MH, Rahman AA, Shahid IZ (2006) Antinociceptive and sedative effects of the bark of Cerbera odollam Gaertn. Adv Tradit Med 6(4):344–348. https://doi.org/10.3742/OPEM.2006.6.4.344
Aziz A, Sahknan R, Khayan K, Wradoyo S (2021) Comparative biochemical effects of seeds extract Cerbera manghas and leaves Carica papaya the vector of Aedes aegypti mosquitos. J Entomol Res 45(3):453–460. https://doi.org/10.5958/0974-4576.2021.00071.2
Bernshteyn M, Adams SH, Gada K (2020) A case of attempted suicide by Cerbera odollam seed ingestion. Case Rep Crit Care. https://doi.org/10.1155/2020/7367191
Bhikuning A, Hafnan M (2019) Biodiesel production from Cerbera manghas using different catalyst; NaOH and zeolite. J Clean Energy Technol 7(2). https://doi.org/10.18178/JOCET.2019.7.2.502
Byeon SE, Yi YS, Oh J, Yoo BC, Hong S, Cho JY (2012) The role of Src kinase in macrophage-mediated inflammatory responses. Mediators Inflamm. https://doi.org/10.1155/2012/512926
Cao LL, Tian HY, Wang YS, Zhou XF, Jiang RW, Liu YH (2013) Chemical Constituents in Fruits of Mangrove Plant Cerbera manghas L. Chin Pharm J 48(13):1052–1056
Chan EWC, Wong SK, Chan HT, Baba S, Kezuka M (2015) Cerbera are coastal trees with promising anticancer properties but lethal toxicity: A short review. 中国药学 (英文版) 25(3):161–169
Chang LC, Gills JJ, Bhat KP, Luyengi L, Farnsworth NR, Pezzuto JM, Kinghorn AD (2000) Activity-guided isolation of constituents of Cerbera manghas with antiproliferative and antiestrogenic activities. Bioorg Med Chem Lett 10(21):2431–2434. https://doi.org/10.1016/S0960-894X(00)00477-7
Cheenpracha S, Karalai C, Ponglimanont C, Chantrapromma K (2004) New cytotoxic cardenolide glycoside from the seeds of Cerbera manghas. Chem Pharm Bull 52(8):1023–1025. https://doi.org/10.1248/cpb.52.1023
Chu SY, Singh H, Ahmad MS, Mamat AS, Lee BB (2015) Phytochemical screening of antifungal biocompounds from fruits and leaves extract of Cerbera odollam Gaertn. Malays Appl Biol 44(3):75–79
Das G, Gouda S, Mohanta YK, Patra JK (2015) Mangrove plants: a potential source for anticancer drugs. http://nopr.niscair.res.in/handle/123456789/34788
Ferrero Miliani L, Nielsen OH, Andersen PS, Girardin SE (2007) Chronic inflammation: importance of NOD2 and NALP3 in interleukin-1β generation. Clin Exp Immunol 147(2):227–235. https://doi.org/10.1111/j.1365-2249.2006.03261.x
Gaillard Y, Krishnamoorthy A, Bevalot F (2004) Cerbera odollam: a ‘suicide tree’and cause of death in the state of Kerala India. J Ethnopharmacol 95(2–3):123–126. https://doi.org/10.1016/j.jep.2004.08.004
Gangwal A (2013) Neuropharmacological effects of triterpenoids. Phytopharmacology 4:354–372
Gizaw A, Marami LM, Teshome I, Sarba EJ, Admasu P, Babele DA, Dilba GM, Bune WM, Bayu MD, Tadesse M, Abdisa K (2022) Phytochemical Screening and In Vitro Antifungal Activity of Selected Medicinal Plants against Candida albicans and Aspergillus niger in West Shewa Zone, Ethiopia. Adv Pharmacol Pharmaceutical Sci. https://doi.org/10.1155/2022/3299146
Guswenrivo I, Tarmadi D, Yusuf S (2013) Insecticide Activity of Cerbera manghas Fruit Exstract to Sitophilus oryzae (Coleoptera: Curculionidae). Jurnal Ilmu dan Teknologi Kayu Tropis 11(1):82–89. https://doi.org/10.51850/jitkt.v11i1.107
Harlev E, Nevo E, Lansky EP, Lansky S, Bishayee A (2012) Anticancer attributes of desert plants: a review. Anticancer Drugs 23(3):255–271. https://doi.org/10.1097/CAD.0b013e32834f968c
Haryanta D, Susilo A, Sa’adah, TT (2020) Repelence of Bintaro Plant Extract (Cerbera manghas) against pod-sucking insects (Riptortus linearis) (Hemiptera). Int J Biol Biomed Eng 14:229–238. https://doi.org/10.46300/91011.2020.14.30
Hashim R, Boon JG, Sulaiman O, Kawamura F, Lee CY (2009) Evaluation of the decay resistance properties of Cerbera odollam extracts and their influence on properties of particleboard. Int Biodeterior Biodegradation 63(8):1013–1017. https://doi.org/10.1016/j.ibiod.2009.07.002
Hendra D, Wibowo S, Hastuti N, Wibisono HS (2016) Characteristics of biodiesel of Bintaro seed (Cerbera manghas L) by modification process. Jurnal Penelitian Hasil Hutan 34(1):11–21. https://doi.org/10.20886/jphh.2016.34.1.11-21
Heng W, Ling Z, Na W, Youzhi G, Zhen W, Zhiyong S, Deping X, Yunfei X, Weirong Y (2014) Analysis of the bioactive components of Sapindus saponins. Industrial Crops Prod 61:422–429. https://doi.org/10.1016/j.indcrop.2014.07.026
Hossain MA, Islam MA, Sarker S, Rahman M, Siraj MA (2013) Assessment of phytochemical and pharmacological properties of ethanolic extract of Cerbera manghas L. leaves. Int Res J Pharm 4(5):120–123
Hossan MS, Chan ZY, Collins HM, Shipton FN, Butler MS, Rahmatullah M, ..., Bradshaw TD (2019) Cardiac glycoside cerberin exerts anticancer activity through PI3K/AKT/mTOR signal transduction inhibition. Cancer Lett 453:57-73.https://doi.org/10.1016/j.canlet.2019.03.034
Husin H, Abubakar A, Ramadhani S, Sijabat CFB, Hasfita F (2018) Coconut husk ash as heterogenous catalyst for biodiesel production from Cerbera manghas seed oil. In: MATEC web of conferences, vol 197. EDP Sciences, p 09008. https://doi.org/10.1051/matecconf/201819709008
Iqbal ZAHRA, Iqbal MS, Mishra KUMKUM (2017) Screening of antioxidant property in medicinal plants belonging to the family Apocynaceae. Screening 10:12
Jeong HY, Sung GH, Kim JH, Yoon JY, Yang Y, Park JG, ..., Cho JY (2014) Syk and Src are major pharmacological targets of a Cerbera manghas methanol extract with kaempferol-based anti-inflammatory activity. J Ethnopharmacol 151(2):960-969.https://doi.org/10.1016/j.jep.2013.12.009
Kaur M, Singh M, Silakari O (2013) Inhibitors of switch kinase ‘spleen tyrosine kinase’in inflammation and immune-mediated disorders: a review. Eur J Med Chem 67:434–446. https://doi.org/10.1016/j.ejmech.2013.04.070
Kemal RA, Yulita A, Nufadianti G, Rosadi I, Muthmainah SI (2015) Plants in Indonesia’ s urban cities: Biotechnological values and diversity projection in 2050. InProsiding Seminar Nasional Masyarakat Biodiversitas Indonesia 1(8):1836–1841. https://doi.org/10.13057/psnmbi/m010814
Kim SH, Park JG, Sung GH, Yang S, Yang WS, Kim E, ..., Cho JY (2015) Kaempferol, a dietary flavonoid, ameliorates acute inflammatory and nociceptive symptoms in gastritis, pancreatitis, and abdominal pain. Mol Nutr Food Res 59(7):1400-1405.https://doi.org/10.1002/mnfr.201400820
Krisnawati A, Adie MM (2018) Evaluation of Soybean Resistance to Pod-Sucking Bug, Riptortus linearis F. and Performance of its Agronomic Characters. Biosaintifika: J Biol Biol Educ 10(1):213–222. https://doi.org/10.15294/biosaintifika.v10i1.12806
Kumar GP, Anilakumar KR, Naveen S (2015) Phytochemicals Having Neuroprotective Properties from Dietary Sources and Medicinal Herbs. Pharmacogn J 7(1)
Laphookhieo S, Cheenpracha S, Karalai C, Chantrapromma S, Ponglimanont C, Chantrapromma K (2004) Cytotoxic cardenolide glycoside from the seeds of Cerbera odollam. Phytochemistry 65(4):507–510. https://doi.org/10.1016/j.phytochem.2003.10.019
Lestari DRS, Soegianto L, Hermanu LS (2017) Antibacterial and antibiofilm potential of ethanolic extract from bintaro flower (Cerbera odollam) against Staphylococcus aureus ATCC 6538. In: UNEJ e-Proceeding, pp 17–19. https://jurnal.unej.ac.id/index.php/prosiding/article/view/3880
Lie J, Rizkiana MB, Soetaredjo FE, Ju YH, Ismadji S (2018) Production of biodiesel from sea mango (Cerbera odollam) seed using in situ subcritical methanol–water under a non-catalytic process. Int J Ind Chem 9(1):53–59. https://doi.org/10.1007/s40090-018-0138-3
Li Y, Yao J, Han C, Yang J, Chaudhry MT, Wang S, ..., Yin Y (2016) Quercetin, inflammation and immunity. Nutrients 8(3):167.https://doi.org/10.3390/nu8030167
Maharana PK (2021) Ethnobotanical, phytochemical, and pharmacological properties of Cerbera manghas L. J Biosci 46(1):1–8. https://doi.org/10.1007/s12038-021-00146-6
Maia JL, Lima-Júnior RC, Melo CM, David JP, David JM, Campos AR, ..., Rao VS (2006) Oleanolic acid, a pentacyclic triterpene attenuates capsaicin-induced nociception in mice: possible mechanisms. Pharmacol Res 54(4):282-286.https://doi.org/10.1016/j.phrs.2006.06.003
Manoharan S, Kaur J (2013) Anticancer, antiviral, antidiabetic, antifungal and phytochemical constituents of medicinal plants. Am J PharmTech Res 3:149–169
Marlinda L, Al Muttaqii M, Roesyadi A, Prajitno DH (2016) Production of biofuel by hydrocracking of cerbera manghas oil using Co-Ni/HZSM-5 catalyst: Effect of reaction temperature. J Pure Appl Chem Res 5(3):189
Massarotti EM (2008) Clinical and patient-reported outcomes in clinical trials of abatacept in the treatment of rheumatoid arthritis. Clin Ther 30(3):429–442. https://doi.org/10.1016/j.clinthera.2008.03.002
Meisyara D, Tarmadi D, Zulfitri A, Fajar A, Ismayati M, Himmi SK, ..., Yusuf S (2020) Larvicidal Activity of Bintaro (Cerbera odollam) against Culex quinquefasciatus. In IOP Conference Series: Earth and Environmental Science 591(1):012010). IOP Publishing
Menezes RG, Usman MS, Hussain SA, Madadin M, Siddiqi TJ, Fatima H, ..., Luis SA (2018) Cerbera odollam toxicity: A review. J Forensic Legal Med 58:113-116.https://doi.org/10.1016/j.jflm.2018.05.007
Misek R, Allen G, LeComte V, Mazur N (2018) Fatality following intentional ingestion of Cerbera odollam seeds. Clin Pract Cases Emerg Med 2(3):223. https://doi.org/10.5811/2Fcpcem.2018.5.38345
Monjur-Al-Hossain ASM, Sarkar S, Saha S, Lokman Hossain Md MHM (2013) Biological assessment on Cerbera manghas (linn.). Pharmacology Online Archives 1:155-160
Mutalip SSM, Yunos NM, Abdul-Rahman PSA, Jauri MH, Osman A, Adenan MI (2014) Mechanisms of action of 17βH-neriifolin on its anticancer effect in SKOV-3 ovarian cancer cell line. Anticancer Res 34(8):4141–4151
Musdja MY, Djajanegara I (2019) Antibacterial activity of dichloromethane and ethyl acetate extracts of bintaro leaf (Cerbera manghas, linn) against Staphylococcus aureus and Escherichia coli. https://repository.uinjkt.ac.id/dspace/handle/123456789/47501
Musdja MY, Aeni M, Djajanegara I (2018) Comparison of antibacterial activities leaves extracts of Cerbera manghas and leaves extracts of Azadirachta indica against Klebsiella pneumoniae. Asian J Pharm Clin Res 11:51–55. https://doi.org/10.22159/ajpcr.2018.v11s3.30030
Noor MM, Suprianto FD, Lesmana LA, Gotama GJ, Setiyawan A (2018) Effect of Cerbera manghas biodiesel on diesel engine performance. Doctoral dissertation, Petra Christian University. http://repository.petra.ac.id/id/eprint/18025
Ong HC, Silitonga AS, Mahlia TMI, Masjuki HH, Chong WT (2014) Investigation of biodiesel production from Cerbera manghas biofuel sources. Energy Procedia 61:436–439. https://doi.org/10.1016/j.egypro.2014.11.1143
Ohmura W, Doi S, Aoyama M, Ohara S (2000) Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus Shiraki. J Wood Sci 46(2):149–153. https://doi.org/10.1007/BF00777362
Otimenyin S (2022) Herbal biomolecules acting on central nervous system. InHerbal Biomolecules in Healthcare Applications (pp. 475–523). Academic Press. https://doi.org/10.1016/B978-0-323-85852-6.00030-5
Patel RL, Sankhavara CD (2017) Biodiesel production from Karanja oil and its use in diesel engine: A review. Renew Sustain Energy Rev 71:464–474. https://doi.org/10.1016/j.rser.2016.12.075
Piazzon A, Vrhovsek U, Masuero D, Mattivi F, Mandoj F, Nardini M (2012) Antioxidant activity of phenolic acids and their metabolites: synthesis and antioxidant properties of the sulfate derivatives of ferulic and caffeic acids and of the acyl glucuronide of ferulic acid. J Agric Food Chem 60(50):12312–12323. https://doi.org/10.1021/jf304076z
Purwanti S, Hidayati S, Ali M, Rahayu A (2021) The Effect Concentration Plant Extracts Bintaro (CarberaManghas) Against Mortality Hama armyworm (Spodopteralitura). Agric Sci 4(2):166–177
Rao A, Zhang Y, Muend S, Rao R (2010) Mechanism of antifungal activity of terpenoid phenols resembles calcium stress and inhibition of the TOR pathway. Antimicrob Agents Chemother 54(12):5062–5069. https://doi.org/10.1128/AAC.01050-10
Reddy D, Kumavath R, Barh D, Azevedo V, Ghosh P (2020) Anticancer and Antiviral Properties of Cardiac Glycosides: A Review to Explore the Mechanism of Actions. Molecules 25(16):3596. https://doi.org/10.3390/molecules25163596
Ren W, Qiao Z, Wang H, Zhu L, Zhang L (2003) Flavonoids: promising anticancer agents. Med Res Rev 23(4):519–534. https://doi.org/10.1002/med.10033
Rizki A, Silitonga AS, Masjuki HH, Mahlia TMI (2018) The potential biodiesel production from Cerbera odollam oil (Bintaro) in Aceh. In MATEC Web of Conferences 159:01049. EDP Sciences
Ruekert LF, Cunningham EA, Naqvi H (2019) Cerbera odollam: a case report of attempted suicide by pong pong. J Psychiatr Pract® 25(3):219–221. https://doi.org/10.1097/PRA.0000000000000391
Sahoo A, Marar T (2018) Phytochemical analysis, antioxidant assay and antimicrobial activity in leaf extracts of Cerbera odollam Gaertn. Pharmacogn J 10(2). https://doi.org/10.5530/pj.2018.2.50
Scott DA, Wright CE, Angus JA (2004) Evidence that CB-1 and CB-2 cannabinoid receptors mediate antinociception in neuropathic pain in the rat. Pain 109(1–2):124–131. https://doi.org/10.1016/j.pain.2004.01.020
Shankar SG, Rai S (2009) (2009) Can cerbera odollam fruit extract serve as an anti-microbial ingredient in deodorants? Ethnobotanical Leaflets 4:5
Sholahuddin AH, Subchan W, Prihatin J (2018) Toxicity of granules of bintaro leaf extract (Cerbera odollam Gaertn.) on armyworm (Spodoptera litura Fab.). Bioedukasi 15–21. https://doi.org/10.19184/bioedu.v16i1.7717
Singh H, Yin-Chu S, Al-Samarrai G, Syarhabil M (2015) Potential of Cerbera odollam as a bio-fungicide for post-harvest pathogen Penicilium digitatum. In AIP Conference Proceedings (Vol. 1660, No. 1, p. 070084). AIP Publishing LLC. https://doi.org/10.1063/1.4915802
Sukmawati D (2016) Antagonism mechanism of fungal contamination animal feed using phylloplane yeasts isolated from the bintaro plant (Cerbera manghas) Bekasi in Java, Indonesia. Int J Curr Microbiol App Sci 5(5):63–74
Sutapa IW, Ropa H (2019) Non-edible Oil of Cerbera manghas L Seed From Seram Island-Maluku as Oil Source of Biodiesel Production. J Phys: Conf Ser 1341(3):032001. https://doi.org/10.1088/1742-6596/1341/3/032001 (IOP Publishing)
Syarifah MS, Nurhanan MY, Haffiz JM, Ilham AM, Getha K, Asiah O et al (2011) Potential anticancer compound from Cerbera odollam. J Trop For Sci:89–96. https://www.jstor.org/stable/23616884
Tarmadi D, Gunandini DJ, Yusuf S (2018) Larvicidal Activity of Cerbera odollam Gaertn Against a Dengue Vector, Aedes aegypti (Diptera: Culicidae). In Sustainable Future for Human Security (pp. 175–188) Springer,Singapore. https://doi.org/10.1007/978-981-10-5430-3_14
Tarmadi D, Himmi SK, Yusuf S (2014) The efficacy of the oleic acid isolated from Cerbera manghas L. seed against a subterranean termite, Coptotermes gestroi Wasmann and a drywood termite, Cryptotermes cynocephalus Light. Procedia Environ Sci 20:772–777. https://doi.org/10.1007/978-981-10-5430-3_14
Tripathi P (2021) The adverse effect of toxic plant constituent found in India: forensic approach. Pharm Innov 10(3):35–44. https://doi.org/10.22271/tpi.2021.v10.i3a.6072
Tsai YC, Chen CY, Yang NI, Yang CC (2008) Cardiac glycoside poisoning following suicidal ingestion of Cerbera manghas. Clin Toxicol 46(4):340–341. https://doi.org/10.1080/15563650701291766
Wahyuni D, Jasril J, Makomulamin M, Sari NP (2018) Carbera manghas Leaf Extract as Larvacide in Controlling Aedes aegypti. Prosiding CELSciTech 3:92–101
Wang GF, Guo YW, Feng B, Li L, Huang CG, Jiao BH (2010) Tanghinigenin from seeds of Cerbera manghas L. induces apoptosis in human promyelocytic leukemia HL-60 cells. Environ Toxicol Pharmacol 30(1):31–36. https://doi.org/10.1016/j.etap.2010.03.012
Wermuth ME, Vohra R, Bowman N, Furbee RB, Rusyniak DE (2018) Cardiac toxicity from intentional ingestion of pong-pong seeds (Cerbera odollam). J Emerg Med 55(4):507–511. https://doi.org/10.1016/j.jemermed.2018.05.021
Wong SK, Lim YY, Chan EWC (2013) Botany, uses, phytochemistry and pharmacology of selected Apocynaceae species: a review. Pharmacogn Commun 3(3):2–11. https://doi.org/10.5530/pc.2013.3.2
Zhang X-P, Pei Y-H, Liu M-S, Kang S-L, Zhang J-Q (2011) Triterpenoids from the leaves of Cerbera manghas. Nat Prod Res Dev 23(3)
Xiao X, Wang X, Gui X, Chen L, Huang B (2016) Natural flavonoids as promising analgesic candidates: a systematic review. Chem Biodivers 13(11):1427–1440. https://doi.org/10.1002/cbdv.201600060
Yi YS, Cho JY, Kim D (2016) Cerbera manghas methanol extract exerts anti-inflammatory activity by targeting c-Jun N-terminal kinase in the AP-1 pathway. J Ethnopharmacol 193:387–396. https://doi.org/10.1016/j.jep.2016.08.033
Yunilla I (2016) Kajian aktivitas dan stabilitas antibakteri ekstrak daun bintaro (Cerbera odollam Gaert.) Doctoral dissertation, Universitas Pelita Harapan. http://repository.uph.edu/id/eprint/1742
Zikri A, Sutini PL, Agus M, Fathona S (2020) Biodiesel Production from Bintaro (Cerbera Manghas L) Seeds with Potassium Hydroxide as Catalyst. J Phys: Conf Ser 1500(1):012084. https://doi.org/10.1088/1742-6596/1500/1/012084 (IOP Publishing)
Zhang L, Fu F, Zhang X, Zhu M, Wang T, Fan H (2010a) Escin attenuates cognitive deficits and hippocampal injury after transient global cerebral ischemia in mice via regulating certain inflammatory genes. Neurochem Int 57(2):119–127. https://doi.org/10.1016/j.neuint.2010.05.001
Zhang XP, Liu MS, Zhang JQ, Kang SL, Pei YH (2009) Chemical constituents from the bark of Cerbera manghas. J Asian Nat Prod Res 11(1):75–78. https://doi.org/10.1080/10286020802514531
Zhang XP, Pei YH, Liu MS, Kang SL, Zhang JQ (2010b) Chemical constituents from the leaves of Cerbera manghas. Asian Pac J Trop Med 3(2):109–111. http://www.airitilibrary.com/Publication/alDetailedMesh?DocID=P20090708003-2010b04-2010b02010b023-201002010023-109-111
Zhao Q, Guo Y, Feng B, Li L, Huang C, Jiao B (2011) Neriifolin from seeds of Cerbera manghas L. induces cell cycle arrest and apoptosis in human hepatocellular carcinoma HepG2 cells. Fitoterapia 82(5):735–741. https://doi.org/10.1016/j.fitote.2011.03.004
Zhu C, Lei M, Andargie M, Zeng J, Li J (2019) Antifungal activity and mechanism of action of tannic acid against Penicillium digitatum. Physiol Mol Plant Pathol 107:46–50. https://doi.org/10.1016/j.pmpp.2019.04.009
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Conceptualization, Mansi Saxena and Ekta B Jadhav; methodology, Mahipal Singh Sankhla and Muskan Singhal; software, Kapil Parihar; data curation, Mansi Saxena; validation, Kumud Kant Awasthi and Garima Awasthi; formal analysis, Mahipal Singh Sankhla and Ekta B Jadhav; writing-original draft preparation, Mansi Saxena and Muskan Singhal; writing-review editing, Kapil Parihar and Kumud Kant Awasthi; supervision, Mahipal Singh Sankhla, and Garima Awasthi; project administration, Mansi Saxena and Ekta B Jadhav; all the authors have read and agreed to the published version of the manuscript.
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Saxena, M., Jadhav, E.B., Sankhla, M.S. et al. Bintaro (Cerbera odollam and Cerbera manghas): an overview of its eco-friendly use, pharmacology, and toxicology. Environ Sci Pollut Res 30, 71970–71983 (2023). https://doi.org/10.1007/s11356-022-22585-w
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DOI: https://doi.org/10.1007/s11356-022-22585-w