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Terminalia arjuna

Terminalia arjuna is a medium to large or semi-evergreen tree in the family , native to the and commonly known as arjuna, reaching heights of 20–30 meters with a buttressed trunk, spreading crown, and distinctive pinkish-gray bark that peels in horizontal flakes. It features oblong or elliptic leaves arranged sub-oppositely, small white sessile flowers in axillary spikes, and ovoid, winged fruits that aid in wind dispersal. The tree thrives in humid, fertile soils along riverbanks, streams, and wetlands in regions such as , , , and , preferring full sun and annual rainfall of 1,000–1,500 mm. For over 3,000 years, Terminalia arjuna has been a cornerstone of Ayurvedic medicine, with its stem bark primarily used as a cardioprotective agent to treat conditions like , , , and through decoctions often mixed with or . Modern pharmacological studies confirm its , anti-ischemic, hypolipidemic, , and antiatherogenic effects, attributed to bioactive compounds including triterpenoids (e.g., arjunic acid, arjunolic acid), (e.g., , ), glycosides (e.g., arjunetin), and . These properties have led to its inclusion in over-the-counter supplements and clinical trials for stable and ischemic heart disease, though further large-scale human studies are recommended. Beyond cardiovascular applications, the , leaves, fruits, and seeds exhibit , gastroprotective, and anticarcinogenic activities, supporting traditional uses for , , and ear infections. Ecologically, T. arjuna serves as a valuable timber for and shade, with its yielding 20–24% for processing.

Taxonomy and description

Taxonomy

Terminalia arjuna is classified within the kingdom Plantae, phylum Tracheophyta, class Magnoliopsida, order Myrtales, family Combretaceae, genus Terminalia, and species arjuna (Roxb. ex DC.) Wight & Arn.. It belongs to a diverse genus comprising around 250 species distributed primarily in tropical regions, many of which share similar floral and ecological traits within the Combretaceae family. Several botanical synonyms have been recorded for Terminalia arjuna, including Terminalia elliptica Willd., Terminalia glabra Wight & Arn., and the basionym Pentaptera arjuna Roxb. ex DC.. The genus name Terminalia originates from the Latin word terminus, meaning "end" or "boundary," which refers to the characteristic clustering of leaves at the tips of shoots. The specific epithet arjuna derives from , where it signifies "bright" or "shining," a description apt for the tree's smooth, silvery-gray bark. The species was first described by under the name Pentaptera arjuna, with the description validated and published by in 1828, before being formally transferred to the genus Terminalia by Robert Wight and George Arnott in 1834.

Morphological characteristics

Terminalia arjuna is a to semi-evergreen belonging to the family, typically reaching heights of 20–30 m with a buttressed up to 2–2.5 m in and a spreading canopy featuring drooping branches supported by a shallow, radial . The overall form is that of a large, fluted with horizontally spreading or drooping branches that contribute to its distinctive silhouette along riverbanks and in moist forests. The is smooth and grey to pinkish-green on the exterior, thick and exfoliating in thin, irregular sheets, while the inner is reddish-brown and often used in traditional preparations. Leaves are simple, subopposite to opposite, oblong or elliptic-oblong in shape, measuring 5–15 cm in length and 4–9 cm in width, with a glossy upper surface, pale underside, crenulate margins, and short petioles of 2–4 cm; they are glabrous, coriaceous, and often inequilateral at the base. Flowers are small, sessile, bisexual or polygamous, and pale yellow to creamy white, arranged in short axillary spikes or terminal panicles measuring 5–13 cm long, with a scent and cup-shaped corollas. The fruit is an indehiscent, obovoid-oblong , 2–5 cm long and 1.8–2.8 cm wide, initially green and turning yellowish-brown at maturity, featuring five to seven thick, narrow, stiff wings with striated, upward-curved veins for dispersal. The tree shows susceptibility to certain fungal diseases, including caused by Phyllactinia terminalae, which affects leaves, and white fibrous rot due to Polystictus affinis, impacting the wood; additionally, it can suffer defoliation from insect larvae such as those of Gelasma goniaria and root damage from pests. Seedlings are particularly vulnerable to fire, drought, frost, and heavy shade, which may lead to forking, bushy growth, or die-back.

Distribution and ecology

Geographic distribution

Terminalia arjuna is native to the including , where it occurs primarily in the Indo-Gangetic plains and the . In , it is distributed across regions including , , , , , and , as well as parts of and . also forms part of its native range. The species has been introduced and planted in several other regions for ornamental, roadside, and purposes. These include , , , , and other parts of , as well as and . Historical records of T. arjuna date back to ancient Indian texts, such as the and , where it is documented for its medicinal value, indicating long-standing presence in the subcontinent. Modern cultivation has expanded since the mid-20th century, driven by demands for timber and medicinal uses, leading to planted populations beyond its native areas. Currently, populations in are often fragmented along riverine zones, reflecting its preference for such habitats.

Habitat requirements

Terminalia arjuna thrives in tropical to subtropical climates, with mean annual temperatures ranging from 20–30°C, though it can tolerate extremes between 5–47°C. It prefers regions with annual rainfall of 750–1900 mm, accommodating seasonal droughts but benefiting from flooding in its natural settings along riverbanks. The species grows best in fertile, well-drained alluvial, loamy, or sandy soils with a pH of 6.5–7.0, commonly found on floodplains, dry river beds, and stream margins. It forms vesicular-arbuscular mycorrhizal associations that enhance nutrient uptake, particularly in nutrient-poor riparian environments. Terminalia arjuna is a fast-growing after an initial slow phase, reaching 2–3 m in height within three years and attaining maturity in 10–15 years, with full canopy development supporting ecological functions. It occurs naturally up to elevations of 1200 m in the . Ecologically, Terminalia arjuna plays a crucial role in stabilizing riverbanks against erosion through its extensive , while providing riparian that supports diverse wildlife in ecosystems.

Reproduction and

Terminalia arjuna exhibits bisexual flowers arranged in axillary spikes, which are primarily pollinated by such as honeybees ( spp.), flies (Diptera), , wasps, and . The flowers are self-compatible, allowing both self- and cross-pollination, though is facilitated by the insect visitors to promote . Natural fruit set under open typically ranges from 40-50%, reflecting effective despite occasional limitations from availability. The species produces winged, indehiscent fruits that facilitate dispersal primarily through anemochory (wind) and hydrochory (), particularly in its riparian habitats where fruits can float and travel along streams or rivers. viability remains high for 6-12 months when stored under dry conditions (4.5-8.2% moisture in airtight containers at 15 to -20°C), but declines rapidly in humid environments without proper treatment. rates of 50-70% are achievable following to overcome physical caused by the hard seed coat, with wet heat treatments (e.g., soaking in hot ) enhancing uniformity and speed of emergence, often completing within 8-12 days. Natural regeneration of T. arjuna is generally poor in the wild, with low seedling establishment due to seed dormancy and competition, though coppicing from root suckers contributes to population persistence in disturbed areas. Seed dormancy, primarily physical, is effectively broken by wet heat or chemical scarification, promoting higher survival rates in suitable moist soils. Propagation of T. arjuna is commonly achieved through , either by direct sowing in prepared beds during early summer or in nurseries where treated yield robust seedlings within 7-8 weeks. Vegetative propagation via semi-hardwood stem cuttings treated with (IBA) at concentrations of 0.5-1.0 mM achieves rooting success rates of 40-60%, depending on cutting age and environmental conditions. techniques, developed since the 1990s, utilize nodal explants from mature trees on supplemented with cytokinins like benzyladenine (BA) for shoot multiplication, followed by IBA pulse treatments for rooting, yielding 80-100% success in elite genotypes. Key challenges in propagation include reduced seed viability under prolonged dry storage without desiccation, leading to erratic germination below 20% in untreated lots, and genotype-specific responses in vitro, where certain accessions show up to 100% bud break while others exhibit somaclonal variation or lower rooting efficiency. These factors necessitate selection of superior seed sources and optimized protocols tailored to regional populations for reliable multiplication.

Uses and cultural significance

Medicinal applications

Terminalia arjuna has been utilized in Ayurvedic medicine for over 3,000 years, primarily as a to address heart ailments such as and , as well as . In classical texts like the , it is recommended for kaphaja hridroga (capha-type heart disorders) in avaleha formulations and for , while the describes its use in managing cardiac bleeding and digestive issues like atisara. The therapeutic effects of Terminalia arjuna are attributed to its rich of bioactive compounds, including the triterpenoid arjunolic , which offers neuroprotective and cardioprotective activity; tannins such as punicalagin and casuarinin, which promote synthesis and hypotensive effects; flavonoids like arjunarin, , and , which inhibit LDL oxidation and exhibit anti-atherogenic properties; and other triterpenoids such as arjungenin, contributing to overall cardiotonic and free radical scavenging capabilities. Contemporary pharmacological investigations, particularly from the 2000s onward, have substantiated these traditional applications through in vitro, animal, and limited human studies focused on cardiovascular benefits. In vitro assays demonstrate inhibition of lipid peroxidation and HMG-CoA reductase activity by bark extracts, while animal models show increased coronary blood flow and reduced triglycerides in hyperlipidemic rats treated with ethanolic fractions. Human clinical trials, such as one involving 500 mg of bark powder administered three times daily for three months, have reported reduced frequency and severity of angina episodes, improved ECG changes, and lipid-lowering effects including decreased total cholesterol and LDL levels alongside elevated HDL in patients with coronary heart disease. Another trial in chronic heart failure patients using 750 mg twice daily bark extract over 12 weeks noted enhancements in functional capacity and antioxidant status, though left ventricular ejection fraction improvements were inconsistent. More recent studies as of 2025 include a randomized double-blind trial in hypertensive geriatric patients showing blood pressure reduction and improved antioxidant status after 12 weeks of supplementation, a randomized controlled study demonstrating improved cardiac function with Terminalia arjuna as add-on therapy in coronary artery disease patients, and an observational trial indicating symptom reduction and ulcer healing in chronic venous insufficiency. Terminalia arjuna is incorporated into Ayurvedic formulations like , a fermented preparation of with and flowers, traditionally used for cardiac toning. Recommended dosages typically range from 500 mg to 2 g of powder daily, divided into two or three doses, often with or , for up to three months under medical supervision. The herb is generally considered safe for short-term oral use at standard doses, with no serious adverse effects reported in clinical settings; however, high doses exceeding 3 g per day may induce , as evidenced by elevated liver enzymes in . It may also interact with anticoagulants or antiplatelet drugs by slowing blood clotting, potentially increasing bruising or risks. Overall, evidence for Terminalia arjuna's cardiovascular applications is robust in and animal models, demonstrating anti-ischemic, hypolipidemic, and mechanisms, but human trials remain limited in scale and duration, yielding promising yet preliminary results for conditions like ischemic and .

Economic and industrial uses

Terminalia arjuna provides hard and durable timber valued for , furniture, and boat-building applications due to its strength and to . The wood has a ranging from 680 to 840 /m³, contributing to its utility in heavy . Additionally, it serves as an important fuelwood source with a calorific value of 21.63 /, supporting rural needs. The tree is a primary host plant for the tasar silkworm (Antheraea mylitta), facilitating production in India's non-mulberry industry. Leaves yield 3.79–5.56 kg per plant, enabling plantations to support significant silkworm rearing capacities. T. arjuna contributes substantially to India's tasar output, which accounts for about 95% of global non-mulberry production. Bark extracts from T. arjuna contain 12–13.76% , used in processes. The and fruits also yield natural dyes producing yellow-brown hues for applications. Leaves serve as for during lean seasons, offering 9–11% crude protein content. Exploitation of T. arjuna for timber, , and bark supports rural livelihoods in , with the tasar silk sector generating foreign exchange earnings of 15–40 rupees annually as of 2020. These uses enhance economic viability in systems, particularly in central and eastern .

Ecological and cultural roles

Terminalia arjuna serves as a in riparian ecosystems, particularly along riverbanks in , where it dominates landscapes and provides essential for diverse and . Its extensive stabilizes in flood-prone areas, preventing erosion and maintaining , while its canopy supports a variety of wildlife, including nesting sites for the critically endangered (Gyps bengalensis) and the Malabar giant squirrel (Ratufa indica). These interactions enhance biodiversity by offering shelter and resources, with the tree also hosting lac insects (Kerria lacca), which feed on its twigs to produce lac resin, and serving as a vital nesting site for bees and bats that contribute to and . Additionally, its flowers provide a significant and source for dwarf honeybees (Apis florea) during spring, supporting apiculture in seasonal forage-scarce regions. The tree plays a crucial role in , with riparian plantations demonstrating high efficiency; for instance, T. arjuna can account for up to 60% of total CO₂ sequestration in riverine systems, accumulating substantial carbon stocks estimated at 11-13 tons per annually in optimized conditions. This capacity underscores its importance in mitigating while fostering ecosystem resilience in tropical and subtropical zones. Culturally, Terminalia arjuna holds profound significance in , revered as a symbolizing strength, purity, and protection, often planted near temples and used in religious rituals for its purifying properties. Its name derives from the epic , where the hero —embodying valor and devotion—is mythologically linked to the tree, enhancing its spiritual aura in Indian traditions. In practices, it aids by binding riverine soils and reducing , promoting sustainable land use in agricultural landscapes. Beyond these roles, T. arjuna functions as an effective in agroecosystems, its dense foliage shielding crops from winds, and is valued for ornamental planting due to its attractive canopy and fragrant flowers, commonly featured in gardens and avenues. During famines, its fruits serve as an edible resource in , providing a supplementary source when other options are scarce.

Conservation

Status and threats

Terminalia arjuna has not yet been globally assessed for the of , indicating a lack of comprehensive international evaluation as of recent records. However, in specific regions of , such as , it is classified as Near Threatened due to localized pressures on medicinal plant populations. Locally, the species faces significant threats in areas like the valley within the Mudumalai Tiger Reserve, where it serves as a supporting . Recent surveys as of November 2025 confirm over 10,000 thriving trees in the area. Population trends for Terminalia arjuna remain stable overall in wild habitats across its native range, though fragmentation is evident due to human activities, leading to isolated stands along riverine areas. In surveyed riparian forests of the valley, a total of 10,127 trees were documented, with approximately 7% (712 individuals) recorded as dead, reflecting localized mortality rates that could contribute to broader declines if unchecked. Extraction pressures have been associated with reductions in some regional populations, particularly where medicinal harvesting is intense, though exact figures vary by site. Key threats to Terminalia arjuna include driven by , which fragments riparian habitats essential for the . Overharvesting of bark for medicinal purposes often involves destructive practices, depleting mature trees and hindering regeneration in natural populations. Habitat loss from and infrastructure development reduces tree viability in affected valleys. Waterlogging from soil and water conservation structures has led to elevated tree death in like Konamasipatti (44.20% mortality). Additionally, exacerbates risks through shifting monsoon patterns that disrupt hydrological cycles in riverine ecosystems, while like compete for resources and contribute to higher mortality in invaded areas. Specific impacts of these threats include diminished regeneration rates in zones with altered river flows. Loss of Terminalia arjuna stands also indirectly threatens associated wildlife, such as the critically endangered White-rumped Vulture, which relies on these trees for 56 documented nesting sites in the Moyar valley, contributing to broader declines in vulture populations linked to habitat degradation.

Protection and cultivation

Terminalia arjuna is protected within several Indian wildlife reserves, particularly in riparian habitats where it serves as a keystone species. In the Mudumalai Tiger Reserve in Tamil Nadu, the tree is conserved along the Moyar River valley through habitat protection measures that address tree mortality factors such as flooding and herbivory, ensuring the maintenance of associated biodiversity including the grizzled giant squirrel. The species is not listed under the CITES appendices, but its bark trade is regulated in India under the Wildlife (Protection) Act, 1972, requiring permits from divisional forest officers for collection and transit to prevent overexploitation. Cultivation of Terminalia arjuna has expanded through systems in , with over 3,000 hectares of plantations established since the on wastelands to support both and generation. These efforts utilize the tree's adaptability to dry forests and riverine areas, often integrating it into taungya systems where it provides shade and alongside agricultural crops. Propagation for relies on seed collection and techniques, with protocols developed using nodal explants to produce disease-free planting material at scale. Sustainable harvesting practices emphasize bark removal from only one-fourth to one-third of the trunk girth, allowing renewal every two years to minimize tree stress and mortality. Key initiatives include programs by the National Medicinal Plants Board (NMPB), which funds conservation, cultivation, and post-harvest management projects for Terminalia arjuna as a priority medicinal species. NMPB supports state-level boards and subsidies for herbal parks and to promote large-scale planting. Community-based projects, such as the Livelihoods-Arjuna initiative by PRADAN, integrate Terminalia arjuna plantations with tasar silk production, training over 1,200 households in sustainable rearing on host trees to enhance and income while reducing pressure on wild populations. Looking ahead, focuses on developing , drought-tolerant accessions through agro-climatic assessments and biochemical screening, offering potential for climate-resilient varieties amid changing environmental conditions. Ongoing monitoring draws from IUCN frameworks, though the remains unassessed globally, highlighting the need for updated threat evaluations to guide long-term .