Fact-checked by Grok 2 weeks ago

Phyllostachys edulis

Phyllostachys edulis, commonly known as Moso bamboo, is a temperate species of giant timber in the family , native to central, southern, and eastern as well as . It features erect, woody culms that can reach up to 20 meters in height and 20 centimeters in diameter, with internodes initially white-powdery and densely puberulent, measuring up to 40 centimeters long. The culm sheaths are yellow-brown or purple-brown, often spotted with dark brown and densely hairy, while the leaves occur 2–4 per ultimate branch, with blades 4–11 cm long and 0.5–1.2 cm wide. This grows from running rhizomes in woodland and mountain slope habitats below 1,600 meters elevation, and it has been introduced to regions including , , the , , and parts of . As the most economically important bamboo species in China, P. edulis covers approximately 5.3 million hectares there and serves as a major raw material for the global industry, valued at around $70 billion as of 2025. It is widely cultivated for its versatile culms, used in , furniture, production, and crafts, as well as for its delicious young shoots, which are harvested in . The species exhibits remarkable rapid growth, with shoots emerging in April and completing height growth to over 20 meters in 45–60 days at rates up to 114.5 centimeters per day, driven by extensive internode elongation. Additionally, it has medicinal applications, such as using leaves for treatment and stem sheaths for relief, and it contributes to environmental through sustainable land restoration. Notable cultivars include 'Heterocycla' (Tortoise-shell bamboo), prized for ornamental value, and the plant's diploid number is 2n = 48, with flowering occurring sporadically from May to August. While primarily in , its invasive potential in non-native areas stems from aggressive spread, competing with native vegetation. Overall, P. edulis exemplifies the ecological and economic significance of s as fast-renewing, multipurpose resources in temperate and subtropical regions.

Taxonomy

Classification

Phyllostachys edulis is a species of bamboo classified within the kingdom Plantae, phylum Tracheophyta, class Liliopsida, order Poales, family Poaceae, subfamily Bambusoideae, tribe Arundinarieae, genus Phyllostachys, and species edulis. The accepted binomial name is Phyllostachys edulis (Carrière) J. Houz., with the parenthetical authority indicating transfer from the basionym Bambusa edulis Carrière, originally described in 1866 in Revue Horticole (Paris), volume 38, page 380. The combination into Phyllostachys was made by J. Houzeau de Lehaie in 1906 in Le Bambou, volume 1, page 39. Phylogenetically, P. edulis is placed among the temperate woody bamboos of tribe Arundinarieae, a diverse group characterized by monopodial rhizomes and temperate distributions. Within the genus Phyllostachys, which comprises approximately 40–50 East Asian species, P. edulis forms part of a closely related to other timber bamboos such as P. aurea (golden bamboo) and P. bambusoides (Japanese timber bamboo), sharing derived traits like elongated culm sheaths and adapted to temperate climates.

Synonyms and etymology

The binomial name Phyllostachys edulis derives from the genus Phyllostachys, coined from the Greek words phyllon () and stachys ( or of ), alluding to the leafy arrangement of the . The specific edulis comes from the Latin adjective meaning "," referencing the plant's young shoots, which are harvested for . Accepted synonyms for Phyllostachys edulis (Carrière) J.Houz. include several names originally placed in related genera, reflecting early taxonomic confusion among bamboos. Key synonyms are: Bambos moosoo Siebold, Bambusa edulis Carrière, Bambusa heterocycla Carrière, Bambusa mitis Carrière, Bambusa pubescens Carrière, and Phyllostachys pubescens (Pradelle) Mazel ex J.Houz. These reflect variations in morphological interpretations, such as pubescence or culm patterns, but modern nomenclature consolidates them under the accepted name. The species was first described in European botany as Bambusa edulis by Élie-Abel Carrière in 1866, based on specimens from Chinese introductions. Earlier, Philipp Franz von Siebold named it Bambos moosoo in 1830, drawing from Japanese cultivation records. In 1906, Jean Houzeau de Lehaie transferred it to Phyllostachys, aligning it with the genus's defining features like the sulcate culms and branch complement, a classification upheld in contemporary floras such as the . This shift marked the transition from broad assignments to more precise generic distinctions in temperate bamboos.

Description

Morphology

Phyllostachys edulis is characterized by tall, robust culms that can reach heights of up to 20 meters or more, with diameters up to 18-20 cm at the base. The culms are straight and cylindrical, initially covered in a white powdery bloom and fine hairs when young, maturing to a green or yellowish hue, often with a white ring below the nodes. Internodes are long, up to 40 cm or more, with basal ones shorter and thicker, and walls approximately 1 cm thick; nodal ridges are inconspicuous except at branching nodes. The leaves are arranged in 2-4 per ultimate branch, with narrow-lanceolate blades measuring 4-11 long and 0.5-1.2 wide, thin-textured and abaxially pubescent along the midrib near the base. Culm leaf sheaths are yellow-brown or purple-brown, often spotted with dark brown, and densely covered in brown hairs; they feature small auricles, strongly developed oral setae, and an arcuate with long cilia. Foliage leaf auricles are inconspicuous with present oral setae and a prominent , contributing to the plant's elegant, feathery appearance. The is supported by leptomorph (running) rhizomes, which are elongated and , extending several meters underground and producing new culms at some distance from existing ones. These rhizomes form a monopodial network, with roots penetrating up to 40 cm deep, enabling aggressive spread and dense thicket formation. Inflorescence in P. edulis is rare, occurring sporadically after long intervals, and consists of paniculate structures with spicate flowering branchlets 5-6 cm long, featuring 1-3 pseudospikelets per spathe, each containing a single floret. The spikelets are subtended by scaly bracts and produce insignificant white flowers, with caryopses narrowly elliptic.

Growth habits

Phyllostachys edulis exhibits a remarkable growth pattern characterized by rapid culm elongation during its first year, with shoots emerging from underground rhizomes in and achieving full height within approximately 60 days. Under optimal conditions, individual culms can elongate at rates up to 114.5 cm per day, driven by high rates of and nutrient mobilization from established rhizomes. This explosive growth phase is followed by gradual thickening and hardening of the culm walls over the subsequent 2-3 years, during which the plant reaches structural maturity and begins contributing significantly to the stand's . As a running bamboo species, P. edulis propagates through leptomorph (monopodial) rhizomes that spread horizontally underground, forming expansive, dense stands over time rather than tight clumps. New culms emerge annually from these rhizomes during the flush, typically from to May in temperate regions, allowing the plant to progressively fill available space and create a thicket-like structure. This spreading habit enables rapid colonization but requires management to prevent uncontrolled expansion. The species thrives in well-drained, humus-rich soils with a range of 5.5-7.0, tolerating a variety of textures from loamy to sandy but performing best with consistent moisture without waterlogging. It prefers full sun to partial , with optimal growth in areas receiving at least 4-6 hours of direct daily, though it can adapt to dappled in established groves. P. edulis is hardy in USDA zones 7-10, demonstrating frost tolerance down to approximately -15°C, beyond which young shoots may suffer damage but mature culms remain resilient. Culms typically reach peak productivity and structural integrity around 3-5 years of age, after which begins, marked by gradual yellowing of the outer tissues and reduced . Individual culms have a lifespan of 10-12 years, during which they transition from vibrant green to faded yellow or gray before dying back, with natural attrition maintaining stand vigor through ongoing rhizome-derived recruitment.

Distribution and habitat

Native distribution

Phyllostachys edulis is native to central, southern, and eastern , with its primary range encompassing provinces such as , , , , , and , as well as . This distribution occurs at elevations ranging from 100 to 1,600 meters, where the species naturally colonizes subtropical regions before extensive human intervention. In its native habitats, P. edulis grows in subtropical forests, particularly on slopes and in river valleys, often within mixed and coniferous woodlands. These environments provide the well-drained, fertile soils essential for its establishment and spread. The prefers humid subtropical climates characterized by annual rainfall of 1,000–2,000 mm and average annual temperatures between 15°C and 25°C. Such conditions support its rapid growth and persistence in the pre-cultivation historical extent across East Asian woodlands.

Introduced ranges

Phyllostachys edulis was first introduced outside its native range to around 1736 from , where it has since become widely naturalized and cultivated. It reached in the late , with introductions to France around 1877 and the in 1893, initially for ornamental and experimental purposes. In , the species arrived in the United States around 1890–1893, primarily through botanical imports for . Today, it is established in over 20 countries worldwide, reflecting its appeal for timber production, , and . The species has spread to temperate and subtropical regions across continents, including southern and central Europe (such as , , and the ), where it grows in mild coastal and inland areas. In , it is prominent in the , particularly in states like , , and , with scattered plantings further north. Introductions extend to , notably Brazil's southern and southeastern regions, as well as and parts of like the and . Establishment outside native habitats succeeds in climates mirroring its subtropical origins, with optimal growth in USDA hardiness zones 7–10, where warm summers and moderate winters support rapid culm development up to 20 meters. However, severe winter frosts below -15°C limit expansion in northern temperate zones, such as parts of and the midwestern , often confining it to protected or southern exposures. Due to its leptomorphic (running) system, P. edulis exhibits potential for aggressive spread, forming dense thickets that can outcompete native vegetation in suitable habitats. It is considered invasive in localized areas, such as expanding stands in broadleaf forests and southeastern woodlands, yet it is not federally listed as a in most countries, including the and member states, though local management is recommended to prevent uncontrolled proliferation.

Ecology

Reproduction

Phyllostachys edulis primarily reproduces asexually through an extensive network of underground rhizomes, which produce new culms clonally from lateral buds on the basal internodes. This mechanism enables rapid clonal expansion, with rhizomes extending up to 1-2 meters per year in suitable environments. As a result of this propagative strategy, populations within a clone display high genetic uniformity, contributing to synchronized growth patterns. Sexual reproduction is infrequent and manifests in gregarious flowering events occurring every 60-120 years across populations. These episodes produce abundant but often culminate in the death of flowering culms, consistent with the species' nature. Seeds exhibit short viability, typically lasting only months, and demand moist, warm conditions around 23-28°C for , achieving low success rates in wild settings. Flowering is commonly induced by stressors such as or advancing plant age, which disrupt the prolonged vegetative phase.

Ecological interactions

Phyllostachys edulis, commonly known as Moso bamboo, significantly influences soil and nutrient dynamics in ecosystems where it expands. Its invasion alters phosphorus and nitrogen cycles by elevating soil pH, which enhances phosphorus bioavailability while modifying nitrogen components such as ammonium and nitrate levels. Recent research as of 2025 indicates that nitrogen-transforming soil microorganisms may facilitate this invasion by enhancing nitrogen availability in invaded forests. These changes stem from the species' dense litter input and root activity, which accelerate nutrient turnover in invaded soils. Additionally, Moso bamboo exhibits high carbon sequestration potential, with annual rates ranging from 6 to 13 Mg C ha⁻¹, contributing substantially to soil organic carbon accumulation in subtropical forests. A 2025 field-based study across China estimated average carbon densities in Moso bamboo forests, supporting its role in carbon storage. Regarding biodiversity effects, the expansion of P. edulis often displaces native understory plants, leading to reduced species richness and the formation of dense monocultures that suppress herbaceous and shrub layers in broadleaf forests. In adjacent coniferous stands, bamboo invasion decreases tree diameter at breast height and height, potentially hindering overall forest regeneration through competition for light and resources. However, in some mixed forests, it may preserve diversity at lower trophic levels by maintaining shrub and herb communities. P. edulis is considered invasive in various regions, forming expansive stands that disrupt native ecosystems. In , particularly in karst regions like the Lijiang River basin, it invades adjacent planted forests, altering microbial communities and threatening . In , such as introduced plantations in , it poses risks through rapid spread, while in the United States, it is assessed as having high invasion potential, especially in the Southeast. These invasions create monocultures that diminish wildlife habitat quality by reducing structural complexity. Despite its invasive tendencies, P. edulis offers positive ecological roles, particularly in native ranges. It provides effective on slopes through its extensive network, stabilizing soil and preventing landslides in subtropical hilly areas. In these habitats, bamboo stands serve as refuges for and , supporting pollinators and avifauna adapted to vegetation. Furthermore, the species forms mycorrhizal associations, primarily with arbuscular mycorrhizal fungi, which enhance uptake and contribute to its role in .

Cultivation

History

Phyllostachys edulis, commonly known as Moso bamboo, has a long history of utilization in , where bamboo species were first documented around 4,000–5,000 years ago for crafting tools such as arrowheads. By the (206 BCE–220 CE), bamboo materials, including those from species like P. edulis, were integral to and , exemplified by the development of hydraulic systems for deep wells in province. These early applications highlight the plant's role in ancient infrastructure, leveraging its strength and abundance in subtropical regions. Cultivation of P. edulis expanded across , with the species introduced to in 1736 via the , where it was valued for timber and edible shoots. In , large-scale plantations emerged prominently in the , driven by demand for industrial resources; by the late 1900s, Moso bamboo covered approximately 3 million hectares, constituting a major portion of the nation's forests. This growth reflected broader agricultural intensification, positioning P. edulis as a key economic species in southern provinces along the River basin. The plant reached the West in the late , first entering around 1880 and the circa 1890, initially for ornamental and experimental purposes before gaining traction in forestry trials. Post-World War II, renewed interest in sustainable materials spurred further cultivation in both regions, aligning with industrial needs for lightweight, renewable resources. In recent decades, scientific advancements have advanced understanding of the species; notably, a draft sequence was published in 2013, revealing mechanisms behind its rapid growth and aiding breeding efforts. By the 2020s, focus has shifted toward sustainable , with P. edulis promoted for land restoration and to meet global environmental goals.

Propagation and management

Phyllostachys edulis is primarily propagated vegetatively through division, the most reliable and commonly used method for establishing new plantings. Healthy , typically 50-60 cm long with 10-15 nodes and attached roots, are excavated during the dormant season from to March and immediately replanted or rooted in a well-drained composed of a 3:1 soil-to-sand mixture, spaced 25 cm apart at a depth of 10-15 cm. This approach ensures high survival rates and clonal uniformity, though it requires careful selection of young rhizomes (≤3 years old) to avoid reduced vigor. Seed propagation is rarely employed due to the species' gregarious flowering events, which occur at intervals of 60-120 years, producing short-lived seeds that are difficult to germinate and store. For large-scale commercial production, methods using explants from young shoots or leaves on supplemented with auxins and cytokinins have shown promise, achieving multiplication rates up to 5-fold per subculture cycle. Site preparation for planting P. edulis emphasizes well-drained, loamy soils with a range of 5.5-7.0 to support optimal root establishment and growth. The site should be cleared of weeds and debris, with mounds created in heavier soils to improve and prevent waterlogging, followed by incorporation of if the native soil is nutrient-poor. Plants are spaced 4-6 meters apart to accommodate mature culm heights of up to 20 meters and allow for rhizome expansion without competition, with closer spacing (3-5 meters) suitable for screen plantings but requiring more intensive management. is critical during the first year after planting, providing 2.5-5 cm of water weekly to promote root development, though established plants exhibit moderate once rooted. Ongoing management focuses on controlling the species' aggressive rhizomatous spread while promoting culm quality and yield. Rhizome barriers, typically 60-90 cm deep sheets of or metal installed around the planting area, are essential to prevent unwanted invasion into adjacent spaces, with annual inspections and edging to sever escaping . Fertilization with nitrogen-rich formulations (e.g., 20-5-10 N-P-K ratio) applied 2-3 times during the spring and summer at rates of 0.5-1 kg N per 100 m² enhances production and culm diameter, but over-application should be avoided to prevent excessive vegetative growth. Culms are harvested selectively at 3-5 years of age, when they reach peak strength and diameter, by cutting at ground level to maintain stand health and allow regeneration from the system. Recent research as of 2025 suggests that managing stand density by retaining 2000-3000 culms per hectare can increase production while maintaining culm quality. P. edulis shows general resistance to pests and diseases but can be affected by (Schizotetranychus celarius), which cause and on leaves, and (e.g., Takecallis spp.), leading to excretion and . In humid environments, fungal leaf spots from pathogens like may occur, manifesting as brown lesions during wet periods. Control measures include regular pruning of infested culms to improve air circulation, horticultural oils or insecticidal soaps for and outbreaks, and avoiding overhead to reduce fungal risks; chemical pesticides are rarely needed due to the plant's . In unmanaged settings, its rapid spread can pose invasive risks, necessitating barriers in .

Cultivars

Several cultivars of Phyllostachys edulis have been developed through and natural variation, primarily originating in with some long-cultivated in , to enhance traits such as culm structure for timber production or distinctive appearances for ornamental use. Notable examples include 'Heterocycla' (also known as 'Kikko-chiku' or tortoise-shell ), characterized by its culms that create a humped, decorative pattern, making it prized for ornamental landscapes; this form features diagonal joints near the base, alternating scars, and has been cultivated since at least the late after introduction from . Another is f. pachyloen ('Pachyloen'), selected for its thicker culm walls and higher , which improve timber quality and shoot production, contributing to greater strength and flexibility in applications like manufacturing. The f. bicolor variety exhibits green-striped culms, adding aesthetic appeal for garden settings, while f. obliquinoda shows oblique nodes that enhance visual interest. Selection criteria for these cultivars emphasize faster growth rates, improved shoot tenderness for culinary use, and ornamental value through unique culm colors or shapes, alongside timber suitability via denser cell structures; for instance, varieties like the standard 'Moso' and f. pachyloen are chosen for their superior length and wall thickness, which boost mechanical properties without compromising overall vigor. Breeding efforts, initiated in the 1950s in , have relied on and limited hybridization due to the species' infrequent flowering cycle (60-120 years), with recent advances incorporating molecular techniques like transcriptome analysis to target genes for enhanced disease resistance, such as PeC3H74 for and . These cultivars are widely available through specialized nurseries across temperate regions worldwide, supporting both plantations and ornamental plantings, though some modern selections like 'BSM-002'—noted for its rigorous and straight culms—are protected by to preserve proprietary traits.

Uses

Industrial applications

Phyllostachys edulis, commonly known as Moso bamboo, serves as a key resource in timber and industries owing to its robust mechanical properties and rapid . The culms, which can reach diameters of up to 20 cm and heights exceeding 20 m, are harvested for use in , where their high compressive and tensile strengths support heavy loads in building projects, particularly in . In and furniture production, processed culms are laminated or engineered into durable panels and boards, offering a sustainable alternative to with bending strengths often surpassing those of . The tensile strength of Moso bamboo culms typically ranges from 126 to 225 , enabling applications in structural elements like beams and trusses. In the pulp and paper sector, is a primary in , where it constitutes the majority of the approximately 4.43 million hectares of bamboo forests dedicated to industrial production. Its high cellulose content (around 40-50%) makes it ideal for kraft pulping processes, yielding fibers suitable for high-quality , , and textiles. Annual bamboo output in exceeds 2 million tons, with Moso species driving much of this capacity due to their abundance and processability. Beyond structural and fibrous uses, Moso bamboo supports bioenergy production through biomass conversion into biofuels like bioethanol and , as well as for amendment. It is also processed into via and chemical activation, achieving surface areas up to 1790 m²/g for applications in and gas adsorption. The global bamboo industry, heavily reliant on species like Moso, generated a of approximately USD 67 billion in 2024. The of Moso in contexts stems from its fast , with culms reaching harvestable maturity in 4-7 years without requiring replanting, as the system regenerates new shoots annually. This short rotation—compared to 20-50 years for timber trees—reduces pressure on forests and supports , with plantations absorbing CO₂ at rates up to 12 tons per yearly. Such attributes position Moso as an eco-friendly material in global supply chains.

Culinary and medicinal uses

The young shoots of Phyllostachys edulis, known as Moso bamboo, are a staple in , harvested when tender and typically prepared by boiling or fermenting to mitigate natural bitterness and toxins. In cooking, they feature prominently in stir-fries, adding a crisp to vegetable and meat dishes, while in , they are incorporated into takikomi-gohan, a flavorful mixed rice prepared with broth, mushrooms, and carrots. Processing methods such as and further extend and reduce anti-nutritional factors like , which can cause bitterness and potential health issues if unprocessed; alone can decrease oxalate content by up to 58%. , the primary producer, harvests approximately 1 million tons of bamboo shoots annually (1.03 million tons as of 2023), with P. edulis contributing the majority due to its prevalence in cultivation. Nutritionally, fresh P. edulis shoots are low in calories at about 27 kcal per 100 g, providing high (around 2 g per 100 g) that supports , along with notable levels of (533 mg per 100 g), , and . In , P. edulis shoots and extracts have been used for and purposes, often in decoctions to treat respiratory disorders and wounds. Modern research supports these applications, highlighting antioxidant properties from compounds like in the leaves and shoots, which exhibit free radical scavenging and reduce inflammation in cellular models.

Biochemistry

Chemical composition

Phyllostachys edulis, commonly known as moso bamboo, exhibits a dominated by structural polymers in its culms, which provide mechanical strength and rigidity. constitutes 40-48% of the dry weight, forming the primary microfibrillar framework, while accounts for 22-27%, contributing to cell wall flexibility through its branched such as glucuronoarabinoxylans. , comprising 25-30%, is embedded within these matrices, enhancing resistance to microbial degradation and environmental stress. These proportions can vary slightly with plant age and environmental conditions, with younger culms showing marginally lower content. Silica, primarily as opal phytoliths, accumulates notably in the leaves of P. edulis, reaching up to 4% of dry weight, which aids in and against herbivores. This biogenic silica is deposited in epidermal cells and contributes to the plant's overall silica cycling in ecosystems. Secondary metabolites in P. edulis include and phenolic acids, which serve defensive roles against and pathogens. such as orientin and isoorientin are prevalent in leaves, while phenolic acids like derivatives exhibit properties. Terpenoids, including sesquiterpenes, are found in essential oils extracted from leaves and culms, contributing to volatile compounds with effects. Chemical composition varies across plant parts, reflecting functional adaptations. Edible shoots are rich in , containing up to 17-18 types including essential ones like and , which support rapid growth and nutritional value. In contrast, rhizomes store high levels of , with comprising 67-76% of carbohydrates, serving as an energy reserve for shoot emergence. Analytical studies of P. edulis compounds frequently employ (HPLC) for separating and quantifying , phenolic acids, and sugars, often coupled with UV detection or for identification. (NMR) is used to elucidate structures of isolated metabolites, such as lignin derivatives and hemicellulosic , providing detailed insights into molecular configurations. These methods have been instrumental in characterizing variations in secondary metabolites across tissues.

Nutritional profile

The edible shoots of Phyllostachys edulis provide a low-calorie macronutrient , with approximately 27 kcal per 100 grams of fresh weight, consisting of 2.6 g , 5.2 g carbohydrates, 0.3 g , and 2.2 g . This composition supports their role as a nutrient-dense, low- option, where the contributes to and gastrointestinal . Micronutrient content in the shoots includes 0.5 mg iron, 13 mg calcium, and 4 mg per 100 grams, offering modest contributions to daily requirements for and intake. The acts as an , while iron and calcium aid in oxygen transport and , respectively, though levels are lower than in fortified foods. Anti-nutritional factors in fresh Phyllostachys edulis shoots include taxiphyllin, a cyanogenic with potential to release toxic (levels up to 434 mg/kg in immature shoots), and at 264–287 mg per 100 grams. Cooking, such as for 25–48 minutes, reduces taxiphyllin by 90–97%, rendering the shoots safe, while processing like or lowers by 20–56%, minimizing risks to . Compared to many vegetables like carrots or eggplants, Phyllostachys edulis shoots excel in (2.2 g/100 g versus 1–1.5 g/100 g in those examples), enhancing their value for intake, but they necessitate processing to address anti-nutritional concerns for optimal .

References

  1. [1]
    Phyllostachys edulis in Flora of China @ efloras.org
    mitis Poiret. This is the most economically important bamboo in China, widely cultivated for its versatile culms and delicious shoots. Many cultivars have been ...
  2. [2]
    Phyllostachys edulis (Carrière) J.Houz. | Plants of the World Online
    The native range of this species is Central & S. China, Taiwan. It is a bamboo and grows primarily in the temperate biome.
  3. [3]
    Rapid growth of Moso bamboo (Phyllostachys edulis) - NIH
    Moso bamboo (Phyllostachys edulis) is a large, woody bamboo species widely distributed in East and Southeast Asia, covering ∼4.43 million hectares in China ...
  4. [4]
    Phyllostachys edulis - Useful Temperate Plants
    ### Summary of Phyllostachys edulis
  5. [5]
    Moso Bamboo (Phyllostachys edulis) - iNaturalist
    Plants Kingdom Plantae ; Vascular Plants Phylum Tracheophyta ; Flowering Plants Subphylum Angiospermae ; Monocots Class Liliopsida ; Grasses, Sedges, Cattails, and ...
  6. [6]
    Bambusa edulis Carrière | Plants of the World Online | Kew Science
    Bambusa edulis Carrière. First published in Rev. Hort. (Paris) 38: 380 (1866). This name is a synonym of Phyllostachys edulis · Taxonomy. Publications; Other ...
  7. [7]
    Phyllostachys edulis | International Plant Names Index
    ### Summary of Phyllostachys edulis
  8. [8]
    Phyllostachys edulis - Plant Finder - Missouri Botanical Garden
    Common Name · moso bamboo ; Type · Ornamental grass ; Family · Poaceae ; Native Range · Caucasus, China, eastern Asia ; Zone · 7 to 10.Missing: taxonomic classification
  9. [9]
    Phyllostachys edulis - an overview | ScienceDirect Topics
    Phyllostachys edulis is defined as a species of bamboo characterized by culms that are smaller in ultimate size, measuring 5 m in height and 2-3 cm in diameter ...
  10. [10]
    Phyllostachys edulis (Carrière) J.Houz. - World Flora Online
    Synonyms · Bambos moosoo Siebold · Bambusa edulis Carrière · Bambusa heterocycla Carrière · Bambusa mitis Carrière · Bambusa pubescens Carrière · Bambusa pubescens ...
  11. [11]
    Predominance of a single clone of the most widely ... - PubMed
    Phyllostachys edulis, one of the most dominant bamboo species with the leptomorph rhizome system, has been asexually expanding its range into adjacent ...
  12. [12]
    (PDF) Moso bamboo (Phyllostachys edulis (Carrière) J.Houz.)
    Sep 12, 2025 · Phyllostachys edulis (Carrière) J.Houz. (Moso bamboo) is a monopodial, indigenous, widely distributed, highly productive, and economically ...
  13. [13]
    Sources of carbon supporting the fast growth of developing ... - NIH
    Phyllostachys edulis is a spectacularly fast-growing species that completes its height growth within 2 months after the shoot emerges without producing ...
  14. [14]
    Influence of Age and Harvesting Season on The Tensile Strength of ...
    Jun 10, 2022 · Bamboo culms reach their maximum strength after two to three years of maturation [9]. Bamboo properties, on the other hand, vary depending on ...Missing: lifespan | Show results with:lifespan
  15. [15]
    Phyllostachys: Bamboo - Portland Nursery
    Genus: Phyllostachys. Common: Bamboo. Origin: Native to China – now around 75 species of Phyllostachys grow in temperate climates around the world. Roots: All ...Missing: etymology | Show results with:etymology
  16. [16]
    [PDF] Is Bamboo for You?
    Feb 21, 2025 · Bamboo produces new culms from rhizomes in the spring. They grow rapidly for 30 to 60 days, obtaining their full height. Only then will they ...
  17. [17]
    Phyllostachys edulis (Moso Bamboo) - Gardenia.net
    A remarkable evergreen bamboo with huge, upright, very thick, gray-green canes surmounted by plumes of small, pale green leaves.
  18. [18]
    a review using a multivariate imputation approach - ScienceDirect
    Jul 25, 2025 · Moso bamboo (Phyllostachys edulis) – hereafter referred to as 'Moso bamboo' - is a giant, arborescent, perennial grass of the Poaceae family ( ...
  19. [19]
    Phyllostachys edulis - Moso Bamboo
    Jun 13, 2020 · Phyllostachys edulis, commonly known as Moso Bamboo, is a temperate species of giant timber bamboo native to China and Taiwan.
  20. [20]
    Bambusa heterocycla Carrière - Lucid key
    Moso bamboo (Phyllostachys edulis) is extensively cultivated in both China and Japan for its edible shoots as well as other uses such as timber. It is also ...Missing: 1873 | Show results with:1873
  21. [21]
    Phyllostachys edulis (Carrière) J.Houz. - Trees and Shrubs Online
    The popular name – of Japanese origin – refers to the humped appearance of the space between the joints. This distortion is a freak of nature, and is not, as ...Missing: etymology | Show results with:etymology
  22. [22]
    The global distribution of bamboos: assessing correlates of ...
    For example, Moso bamboo (Phyllostachys edulis syn. P. pubescens), one species of about 583 native to China, has become widespread (both through natural ...
  23. [23]
    Moso bamboo (Phyllostachys edulis (Carriere) J. Houzeau) invasion ...
    Feb 27, 2018 · Moso bamboo (Phyllostachys edulis) is widely distributed in subtropical China (Wang et al. 2013). Because of its typical clonal propagation, ...1 Introduction · 3 Results · 4 Discussion<|control11|><|separator|>
  24. [24]
    Early warning of two emerging plant invaders in Europe - Nature
    Apr 5, 2025 · The pool of invasive ornamental plants keeps expanding, and one of the best studied plant invasion habitats is the riparian zone.<|control11|><|separator|>
  25. [25]
    Transcriptome and anatomical comparisons reveal the specific ...
    Nov 1, 2021 · In asexual reproduction, the lateral buds located on the basal part of the rhizome internode develop into new shoots. Three distinct growth ...
  26. [26]
    Running Bamboo - Lexington, MA
    Running bamboos, however, have a leptomorph, or monopodial rhizome system. Their rhizomes usually grow 3 feet to 5 feet per year, sending up new shoots all ...Missing: rate | Show results with:rate
  27. [27]
    Transcriptome analysis of lateral buds from Phyllostachys edulis ...
    In bamboo morphogenesis, the long-term asexual reproduction of rhizome bud controls the rise and fall of the bamboo forest [8]. Moreover, as the initial ...
  28. [28]
    [PDF] Breeding Strategies and Utilization of Phyllostachys edulis for Shoot ...
    Sep 30, 2025 · The flowering of Phyllostachys edulis is very rare and has no fixed pattern. The sexual reproduction cycle often takes 60 to 120 years, or even ...
  29. [29]
    The Bamboo Flowering Cycle Sheds Light on Flowering Diversity
    We observed that all the flowering culms died after flowering in many species such as Bambusa multiplex, Chimonobambusa sichuanensis, Phyllostachys edulis, Ph. ...
  30. [30]
    Advances in technology for seed germination of bamboo species
    Bamboo seeds typically have low germination rates and a short viability period (Sarkar et al., 2020). Factors such as seed dormancy, poor storage conditions, ...
  31. [31]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC7180196/
  32. [32]
    Bamboo Flowering from the Perspective of Comparative Genomics ...
    Dec 1, 2016 · Additionally, we investigated triggers like stress (drought), physiological maturity and micro RNAs that may play crucial roles in flowering. ...
  33. [33]
    Moso bamboo (Phyllostachys edulis) expansion enhances soil pH ...
    Feb 20, 2024 · Our findings highlight that bamboo expansion leads to an increase in soil pH and alters soil N components and fungal microbial communities.<|separator|>
  34. [34]
    (PDF) Ecological stoichiometry of nitrogen and phosphorus in Moso ...
    Nov 1, 2018 · Ecological stoichiometry of nitrogen and phosphorus in Moso bamboo (Phyllostachys edulis) during the explosive growth period of new emergent ...
  35. [35]
    Managing woody bamboos for carbon farming and carbon trading
    Mean carbon storage and sequestration rate in woody bamboos range from 30–121 Mg ha−1 and 6–13 Mg ha−1 yr−1, respectively. Bamboo has vigorous growth, with ...Missing: edulis | Show results with:edulis
  36. [36]
    Rapid bamboo invasion (expansion) and its effects on biodiversity ...
    Zhejiang, Anhui, Fujian and Sichuan Provinces, China, Bamboo invasion may cause the loss of species diversity and destruction of the native forest ecosystems.
  37. [37]
    Effects of bamboo invasion on forest structures and diameter–height ...
    We found that bamboo invasion decreased the mean and maximum diameter at breast height, maximum height, and total basal area, but increased the mean height, ...1. Introduction · 3. Results · 4. Discussion
  38. [38]
    Ecological functionality of Phyllostachys edulis (Moso Bamboo ...
    Oct 12, 2025 · Our results indicate that Moso bamboo preserves considerable biodiversity values at shrub and herb levels, is also able to absorb high values of biomass.Missing: interactions | Show results with:interactions
  39. [39]
    (PDF) Moso bamboo (Phyllostachys edulis (Carrière) J. Houzeau ...
    Aug 6, 2025 · Moso bamboo (Phyllostachys edulis (Carrière) J. Houzeau) invasion affects soil microbial communities in adjacent planted forests in the Lijiang ...
  40. [40]
    Carbon sequestration in a bamboo plantation: a case study in a ...
    Here we investigated the C mitigation potential of the fast-growing Moso bamboo (Phyllostachys edulis) introduced in Italy for climate-change mitigation.
  41. [41]
    Phyllostachys edulis - UF/IFAS Assessment
    Aug 8, 2022 · Common Names. Moso bamboo, moso-chiku, tortoise shell bamboo ; Synonyms. No known synonyms ; Family. Poaceae ; Conclusions by Zone. Central, North, ...
  42. [42]
    Ecological functions of bamboo forest: Research and Application
    Aug 9, 2025 · This review describes ecological functions of the bamboo forest on soil erosion control, water conservation, land rehabilitation, and carbon sequestration.<|control11|><|separator|>
  43. [43]
    (PDF) A Review of Bamboo: Characteristics, Components, and Its ...
    Bamboo species play an important role in supporting wildlife and maintaining ecological balance. Bamboo forests provide essential habitat for a variety of ...
  44. [44]
    Glomeromycota associations with bamboos (Bambusoideae ...
    Nov 9, 2023 · Bamboo species such as Phyllostachys edulis have been described as promising in their roles of carbon sequestration through their mycorrhizal ...
  45. [45]
    Bamboo as a valuable resource and its utilization in historical and ...
    Phyllostachys edulis is reportedly one of the major commercially cultivated bamboo species in subtropical climatic regions. Moso bamboo is mainly cultivated ...Missing: native | Show results with:native
  46. [46]
    Chinese Moso Bamboo: Its importance - ResearchGate
    Moso bamboo (Phyllostachys edulis) is widely distributed in southern China and has been introduced in many other countries in Southeast Asia (Watanabe et al., ...
  47. [47]
    The draft genome of the fast-growing non-timber forest species ...
    Feb 24, 2013 · We report a high-quality draft genome sequence of moso bamboo (P. heterocycla var. pubescens). The 2.05-Gb assembly covers 95% of the genomic region.
  48. [48]
    [PDF] A MANUAL FOR VEGETATIVE PROPAGATION OF BAMBOOS
    Over the years, many new vegetative propagation techniques have been developed, tested and perfected. This manual is an attempt to summarize such techniques ...
  49. [49]
    Limitations, progress and prospects of application ... - PubMed Central
    ... propagation techniques like seed propagation, clump division, rhizome and culm cuttings etc. Pests and diseases also play an important role in the success ...
  50. [50]
    Bamboo Farming Techniques - Amwoodo
    Jul 10, 2024 · Site Preparation. Prepare the land by clearing any weeds and debris. Bamboo thrives in well-drained soil with a pH between 5.5 and 6.5.
  51. [51]
    Frequently Asked Questions | Bamboo Garden
    What's the difference between running bamboo and clumping bamboo? Clumping bamboo spread very slowly. They have a pachymorph rhizome system, which means ...<|separator|>
  52. [52]
    Bamboo: Is it for you? - Skagit County Master Gardener Foundation
    Feb 22, 2025 · Bamboo is unlike any other plant in the garden. Bamboo resists drought, deer, pests, and disease. As a landscape plant, it is self-mulching and evergreen.
  53. [53]
    Bamboo (Phyllostachys sp.)-Leaf Spots
    Bamboo leaf spots are caused by fungi like Cyphellophora sp. and Cladosporium herbarum, and bacteria like Pseudomonas sp., favored by wet conditions. Symptoms ...Missing: edulis aphids
  54. [54]
    Analysis of the Cell Structural Characters of Moso Bamboo ... - MDPI
    Jan 27, 2023 · Analysis of the Cell Structural Characters of Moso Bamboo (Phyllostachys edulis (Carriere) J. Houzeau) and Its Varieties. by. Wenbo Zhang.Missing: patented | Show results with:patented
  55. [55]
    https://amwoodo.com/bamboo-farming-techniques/
  56. [56]
    Moso bamboo plant named 'BSM-002' - Google Patents
    The present disclosure relates to a new and distinct cultivar of Phyllostachys edulis discovered and asexually reproduced by the inventor and will be referred ...
  57. [57]
    Uses of Bamboo for Sustainable Construction—A Structural and ...
    The average tensile strength was 126.7 and 159 MPa for the Phyllostachys edulis and Phyllostachys viridiglaucescens species. Parusaram and Baskaran [24] ...Missing: scaffolding furniture
  58. [58]
    The structure and mechanics of Moso bamboo material - Journals
    Oct 6, 2014 · Our data for Moso bamboo indicates that it is 31% stronger in bending, 15% less stiff and 48% stronger in compression than red oak [31]. It is ...Missing: scaffolding furniture
  59. [59]
    The structure and mechanics of Moso bamboo material - PMC - NIH
    The modulus of rupture has a range from 50 to 250 MPa, slightly lower than the range of the majority of literature for tensile strength (100–400 MPa) [8–10].
  60. [60]
    Dynamic Changes of Chemical and Mechanical Properties of Moso ...
    The main mechanical properties of the P. edulis culms control were compressive strength 72.50 MPa, bending strength 137.50 MPa, and tensile strength 225.43 MPa ...
  61. [61]
    Review of the Resources and Utilization of Bamboo in China
    May 30, 2018 · The national bamboo forest covers 6.01 million ha, including 4.43 million ha of Moso bamboo and 1.58 million ha of other bamboo species. As the ...Missing: plantations | Show results with:plantations
  62. [62]
    [PDF] Bamboo: an overlooked biomass resource? - UNT Digital Library
    Above- ground biomass of this mature stand (age not given) was 138 t/ha (117 t/ha in culms). Above-ground woody biomass increments averaging 7.7 t/ha/year ...
  63. [63]
    Bamboo for the Future: From Traditional Use to Industry 5.0 ... - MDPI
    Its high tensile strength, flexibility, and ecological adaptability make it suitable for applications in bioenergy (bioethanol, biogas, biochar), advanced ...
  64. [64]
    Fabrication and Characterization of Activated Carbon from ... - MDPI
    Aug 28, 2022 · In this study, activated carbon (ACs) was fabricated and characterized from Phyllostachys edulis (Moso bamboo) using single-step potassium hydroxide (KOH) ...Missing: bioenergy | Show results with:bioenergy
  65. [65]
    Bamboos Market Size, Share, Growth | Industry Report, 2030
    The global bamboos market size was estimated at USD 67.13 billion in 2024 and is projected to reach USD 88.44 billion by 2030, growing at a CAGR of 4.7% ...
  66. [66]
    [PDF] the sustainability of MOSO bamboo
    Thus, as bamboo – in contrast with hardwood - is best managed as an agricultural crop with an annual harvesting scheme, in practice, no deforestation takes.
  67. [67]
    Precooking processing of bamboo shoots for removal of anti-nutrients
    Therefore freshly harvested bamboo shoots should be processed before cooking to remove the toxic and bitter components. The processes (peeling, slicing, ...
  68. [68]
    A systematic review on the composition, storage, processing of ...
    Processing workflows of bamboo shoot products via drying, fermentation and canning. Canning is a common way to preserve vegetables usually by thermal ...
  69. [69]
    Bamboo Rice (Takenoko Gohan) (Video) たけのこご飯
    Rating 4.7 (10) · 1 hrBamboo Rice (Takenoko Gohan) is a simple, elegant Japanese dish cooked in dashi broth with sweet, tender, and crunchy bamboo shoots, a taste of spring.Missing: Phyllostachys edulis
  70. [70]
    Quality improvement of bamboo shoots by removal of antinutrients ...
    Jan 27, 2021 · In order to eliminate or reduce the level of anti-nutrients to barest minimum, appropriate processing techniques such as soaking, boiling, ...
  71. [71]
    Bamboo shoots nutrition: calories, carbs, GI, protein, fiber, fats
    Bamboo shoots nutrition (100 grams). Richest in Potassium: 533mg (16% of DV), Vitamin C: 4mg (4% of DV). Glycemic Index: 32, Calories:27, Net carbs: 3, ...Missing: Phyllostachys edulis
  72. [72]
    The Nutritional Facts of Bamboo Shoots and Their Usage as ...
    Bamboo shoots have immense potential of being used as important health food as they contain high proteins, amino acids, carbohydrates, many important minerals, ...
  73. [73]
    Potential Medicinal Application and Toxicity Evaluation of Extracts ...
    A poultice of the shoots is often used for cleaning wounds and healing infections. Bamboo shoot decoction taken along with honey is used to treat respiratory ...Missing: culinary | Show results with:culinary
  74. [74]
    Evaluation of Antioxidant and Prooxidant Activities of Bamboo ...
    Solvent-extracted bamboo leaf extract (BLE) containing chlorogenic acid, caffeic acid, and luteolin 7-glucoside was evaluated in vitro for free radical ...
  75. [75]
    Anti-Inflammatory and Antioxidant Effects of Leaves and Sheath from ...
    Jun 8, 2023 · These findings highlight the anti-inflammatory and antioxidant properties of BL and BS, corroborating their different potential applications.
  76. [76]
    Variations of the fundamental chemical components in Moso ...
    The cellulose content ranged from 36% to 40%, the hemicelluloses content ranged from 25% to 28%, and the lignin content ranged from 26% to 34%.Missing: composition | Show results with:composition
  77. [77]
    Controls for phytolith accumulation in Moso bamboo leaves across ...
    Oct 1, 2023 · The average phytolith content in bamboo leaves across the different age groups ranged from 32.18 to 55.56 g kg−1, with the lowest in group A. ...<|control11|><|separator|>
  78. [78]
    Effects of the Species and Growth Stage on the Antioxidant ... - NIH
    Feb 2, 2024 · Phenolics, including phenolic acids and flavonoids, might represent the constituents in bamboo leaves that confer their antioxidant and ...
  79. [79]
    Antibacterial activity of the biogenic volatile organic compounds from ...
    Nov 15, 2024 · Overall, Phyllostachys edulis had a stronger and wider range antibacterial effect among the three bamboo species. Terpenes are the main ...
  80. [80]
    The Nutritional Facts of Bamboo Shoots and Their Usage as ...
    Jul 20, 2014 · Out of 17 amino acids reported in bamboo shoots, 8 amino acids were essential for human body [24]. Nirmala et al. [6] studied amino acid content ...
  81. [81]
    Association among starch storage, metabolism, related genes and ...
    Oct 20, 2021 · The amylopectin content of bamboo shoots was 80–90%, and that of bamboo rhizome was 67–76% (Fig. 3e,f). The change trend of amylose and ...Missing: amino | Show results with:amino
  82. [82]
    Characterization and identification of the major flavonoids in ...
    Feb 2, 2020 · 3.1. UPLC–QTOF-MS/MS Analysis Phyllostachys edulis Leaves Flavonoids. UPLC-UV chromatograms collected at 350 nm and UPLC–QTOF-MS extracted ion ...
  83. [83]
    Identification and quantitation of the actual active components in ...
    Nov 12, 2020 · In this study, 26 main compounds of bamboo juice (Phyllostachys edulis) were separated, precisely identified, and qualitative analysis using NMR ...
  84. [84]
    Characterization of hemicelluloses in Phyllostachys edulis (moso ...
    Oct 1, 2019 · Our results show that the main chain of hemicellulose in P. edulis consists of glucuronoarabinoxylans (GAXs) with backbone 1, 4-β-d-Xyl, and ...