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Safflower

Safflower (Carthamus tinctorius L.) is an annual in the family, recognized for its thistle-like growth habit with branching stems, spiny leaves, and solitary globular flower heads that bloom in shades of yellow, orange, or red. The plant typically reaches heights of 30 to 150 cm (12 to 59 in), features an extensive root system that enables drought tolerance, and thrives in arid and semi-arid environments with well-drained soils. Cultivated since prehistoric times, safflower is among the world's oldest crops, originating from the Mediterranean region and , where it was initially valued for the vibrant pigments extracted from its flowers—carthamin for red and yellow flavonoids—for use in textiles, , and . Over centuries, its cultivation spread across , , and the , evolving from a and medicinal source to a major oilseed crop by the , with global production reaching approximately 996,000 metric tons in 2022. In modern , safflower is primarily grown for its , which contain 30-40% oil high in (up to 70%), a polyunsaturated prized for oils in dressings, cooking, and margarines due to its neutral flavor and high . The oil also finds industrial applications in paints, varnishes, and biofuels, while the defatted seed meal serves as a protein-rich feed, though its use is limited by antinutritional factors like . Major producing regions include , the (particularly , , , and ), , , and , where it is favored as a dryland rotational crop with or to improve and suppress weeds. Beyond agriculture, safflower holds significant traditional and pharmacological value; its flowers have been employed in Iranian, , and Ayurvedic for treating circulatory issues, amenorrhea, , and wounds, attributed to bioactive compounds like and hydroxysafflor yellow A. Contemporary studies underscore its , , and potential cardiovascular protective effects, supporting ongoing research into its therapeutic applications while highlighting the need for standardized extracts.

Taxonomy and Etymology

Taxonomy

Safflower is scientifically classified as Carthamus tinctorius L., a binomial name assigned by in his 1753 work , where it was described based on specimens from the region. Lectotype: Herb. Clifford: 394, Carthamus 1 (BM 000646936), designated by Rechinger (Fl. Iranica 139b: 434, 1980). It belongs to the family (also known as Compositae), subfamily Carduoideae, tribe Cardueae, and subtribe Centaureinae. The genus encompasses approximately 14–15 species, primarily annual or perennial herbs native to the Mediterranean, , and parts of , with C. tinctorius as the sole cultivated species. These species are distinguished by their thistle-like habit, spiny involucral bracts, and capitula (flower heads) that are typically discoid with tubular florets. Carthamus tinctorius is diploid with a number of 2n = 24, consistent across the sect. Carthamus group to which it belongs. Historical synonyms include Carduus tinctorius (Ehrh.) and Carthamus glaber (Burm. f.), reflecting earlier classifications that placed it within related genera before its establishment in Carthamus.

Etymology

The English word "safflower" derives from Middle French safleur, which in turn originates from Arabic ʾaṣfar meaning "yellow," reflecting the plant's vibrant flower color, though it was later influenced by associations with safran (saffron) and fleur (flower). The modern Arabic name al-ʿuṣfur similarly stems from the root ṣ-f-r, denoting "yellow," highlighting the linguistic emphasis on the flower's hue across . The scientific genus name Carthamus traces back to Arabic qurtum or kurthum, a verb meaning "to dye," alluding to the plant's longstanding use in producing red and yellow pigments from its flowers. An alternative derivation links it to Hebrew qartamī or krtm, also signifying "dye" or "to paint," underscoring its role as a coloring agent in ancient Near Eastern cultures. In Greek, the term kárthamos (κάρθαμος), recorded in Mycenaean tablets from the 14th century BCE, may relate to this Semitic root and possibly carries connotations of "bastard ," as the plant's flowers served as a cheaper substitute for true saffron in dyeing and flavoring. Common names often reflect this saffron mimicry and regional uses, such as "false saffron" or "bastard saffron" in English and European languages like French safran bâtard, emphasizing its deceptive similarity to the more valuable . In , it is known as hónghuā (红花), literally " flower," directly describing the mature florets' pigmentation. Indian vernaculars include kusumbha or kusum in and , derived from ancient terms for the flower's properties, and kusumba in regional dialects like , tying into traditional applications. Historical naming appears in ancient Greek texts, where kárthamos denoted both white and red varieties used for oil and dye, as noted in Linear B inscriptions from sites like Knossos. This linguistic evolution parallels the plant's cultural role in producing dyes, a practice evident from early Bronze Age contexts in the Near East.

Botanical Description

Morphology

Safflower (Carthamus tinctorius) is an annual herbaceous plant characterized by an erect, thistle-like growth habit, typically reaching heights of 30 to 150 cm at maturity. The plant is highly branched from the base, forming a bushy structure with a robust central stem and numerous lateral branches, supported by a deep system that enhances its . This overall architecture allows safflower to thrive in arid conditions, with the branching pattern promoting efficient light capture and seed . The stems are cylindrical, upright, and glabrous or armed with spines, particularly in wild varieties, while the leaves are alternate, sessile, and pinnately lobed, measuring 5 to 25 cm in length with prominent white veins and spiny margins. These leaves clasp the and decrease in size up the , contributing to the overall spiny appearance that deters herbivores. The spiny features on leaves and provide a mechanical defense against pests and animals. The comprises solitary or clustered capitula (flower heads) at the branch tips, each 2 to 5 cm in diameter and containing 15 to 100 tubular disc florets, enclosed by an involucre of spiny bracts in overlapping series. The flowers are predominantly to , though rare or variants occur, and lack ray florets typical of some ; the corollas are tubular and slightly expanded at the base. Following , the fruits develop as achenes, 3 to 5 mm long, to pale brown in color, with two morphological types—elongated central achenes and more rounded peripheral ones. The seeds within are 4 to 6 mm long, smooth or faintly ribbed, and rich in oil, comprising 25 to 40% of their weight. Domesticated safflower cultivars exhibit notable morphological variations from wild progenitors, including reduced density on stems, leaves, and bracts, which improves ease of mechanical harvest and reduces injury risk during handling, while maintaining the core structural traits for oilseed production.

Growth and Reproduction

Safflower (Carthamus tinctorius) is an annual with a spanning 110 to 150 days from to maturity, varying by and . The vegetative stage begins with and , followed by a phase lasting 2 to 4 weeks where leaves develop near the ground and a deep forms, conferring early . This transitions to stem elongation and branching, with rapid growth under favorable conditions. The reproductive stage initiates with bud formation, leading to flowering typically 85 to 140 days after , depending on and . ripening occurs 30 to 40 days post-flowering, completing the cycle. Germination occurs epigeally, with optimal soil temperatures of 15 to 20°C for maximum efficiency, though viable emergence happens between 5°C and 40°C, taking 7 to 14 days. Seedlings establish quickly, exhibiting resistance from the outset due to the developing , which can reach depths of 2 to 3 meters. Flowering is largely photoperiod insensitive but highly temperature-dependent; cool temperatures delay it, while heat accelerates development but risks frost damage post-elongation, as tolerate lows to -7°C only in the rosette stage. Safflower varieties differ in maturity, with early types completing the cycle in under 120 days and late types extending to 150 days or more. Reproduction is primarily autogamous, with over 90% self-pollination due to the hermaphroditic disc florets where the stigma is enclosed by anthers, though insect visitors like bees can increase outcrossing to 10% or higher in some fields. Each flower head sets 20 to 50 viable seeds, with pollen viability averaging 80% at anthesis but declining rapidly thereafter due to environmental factors like humidity. Meiosis in pollen mother cells is typically regular, producing fertile gametes, though irregularities can occur under stress, reducing fertility. Seed viability remains high for 2 to 3 years under dry storage at 10 to 20°C, supporting propagation. Heat and drought during flowering and seed fill can reduce yield by 20 to 50% through impaired pollination and seed development, with drought-tolerant varieties maintaining stability via osmotic adjustments.

History and Domestication

Origins and Domestication

Safflower (Carthamus tinctorius) originated in the arid regions of , particularly the encompassing modern-day , , and , where wild progenitors such as Carthamus palaestinus, its closest wild progenitor, and related species thrived in dry, steppe-like environments. The plant's is believed to have occurred through a single event approximately 4,000 to 6,000 years ago in this region, marking a transition from wild, spiny forms to cultivated varieties adapted for human use. This process involved for key traits, including non-spiny leaves to facilitate harvesting, non-shattering achenes to prevent seed loss, larger seed size for improved yield, and enhanced oil content in the seeds, distinguishing domesticated safflower from its wild ancestors. Archaeological evidence supports this timeline, with the earliest remains of species identified in northern dating to around 3000 BCE during the Early , indicating initial for and production. These findings extend to sites in and by the 6th millennium BCE for wild forms, evolving to domesticated uses; notably, safflower-derived dyes were applied to mummy wrappings and textiles in as early as the New Kingdom (ca. 1550–1070 BCE), with confirmed use on wrappings during the 21st Dynasty (ca. 1069–945 BCE) and later periods such as the Late Period (circa 700–500 BCE), providing colorants for textiles in funerary practices. Such evidence underscores safflower's role in early agricultural societies, where it served as a multipurpose resource beyond mere subsistence. Following domestication, safflower spread via ancient trade routes, reaching northwestern by the 3rd–2nd millennium BCE as evidenced by archaeological records, and extending to through Central Asian silk roads by the 2nd century BCE. It reached , including the Aegean and Thracian regions, by the Early (ca. 2800 BCE) via exchanges from the , and was later introduced to the in the late for agricultural experimentation. Genetic studies, including of cultivated and wild accessions, reveal low nucleotide diversity in modern varieties (with a 20–30% reduction compared to wild C. palaestinus), consistent with a genetic from this single Near Eastern origin and subsequent limited during dispersal.

Historical Uses

Safflower (Carthamus tinctorius) has been valued for its vibrant pigments since antiquity, particularly for dye production. In , the flowers yielded carthamin, a used to color textiles and , with evidence from mummy wrappings and garlands found in tombs, including those associated with , where safflower-dyed linens provided bright and orange hues despite the pigment's poor . Cultivation for this purpose extended to and as early as 4500 BC, where safflower produced and yellow dyes for and fabrics, often combined with other natural colorants to achieve fiery reds for ceremonial garments and turbans. Culinary applications of safflower emerged in ancient Persia and spread to medieval , where its dried flowers served as an affordable substitute for , imparting a similar yellow-orange tint to dishes without the latter's intense flavor. By the 13th century in , particularly and , safflower oil was extracted from seeds for cooking, prized for its neutral taste and stability in high-heat preparations like stir-fries and curries. Limited archaeological evidence, such as seeds found in ancient mummies and Carthaginian sites, suggests occasional inclusion in early diets, though flowers and oil dominated historical consumption. In , safflower held prominent roles across cultures. In , the florets (known as hong hua) were employed to promote blood circulation, alleviate stasis, and support by regulating and easing . In Ayurvedic practices in , it addressed conditions like and rashes, as well as fevers, through its and diaphoretic properties, often prepared as oils or decoctions for topical and internal use. Beyond dyes and remedies, safflower fulfilled other practical roles. In , the red pigment beni extracted from flowers colored woodblock prints and textiles during the , symbolizing vitality in art and fashion. The oil illuminated lamps in ancient Egyptian pharaonic courts, providing a clean-burning . In Middle Eastern folklore, particularly Iranian traditions, safflower was revered for its protective qualities in rituals, warding off melancholy and ailments while embodying resilience in arid landscapes.

Cultivation

Environmental Requirements

Safflower (Carthamus tinctorius L.) is well-adapted to semi-arid and arid climates, thriving in regions with hot, dry summers and moderate winters. It performs optimally under daytime temperatures ranging from 20°C to 32°C during flowering and seed development, though it can tolerate extremes up to 45°C without significant damage due to its deep root system that facilitates heat and resilience. For early growth stages like development, cooler mean daily temperatures of 15°C to 20°C are preferred to promote root establishment. The crop requires low annual rainfall, typically 300 to 500 mm total for rainfed production, with much of its water needs met post-establishment through its extensive , which can reach depths of 2 to 3 meters to access subsoil . It exhibits strong resistance after the stage but is sensitive to excessive during flowering, where dry conditions enhance seed quality. Safflower demonstrates moderate tolerance, enduring temperatures as low as -7°C (20°F) during the or early phase, but it becomes highly susceptible to damage once begins, with injury occurring at around -4°C. Safflower grows best in well-drained, light to medium-textured loamy soils with good water-holding capacity, as heavy clays or poorly drained sites lead to and reduced yields. It tolerates a range of 6.0 to 8.0, performing adequately in neutral to slightly alkaline conditions, and shows superior adaptability to saline and alkaline soils compared to many other crops, maintaining productivity at electrical conductivity () levels up to 8 dS/m due to its efficient exclusion mechanisms. Water demands are minimal for an oilseed crop, with total seasonal requirements of 200 to 400 mm under deficit or rainfed systems, emphasizing its suitability for low-input ; however, it is highly sensitive to waterlogging, which can cause oxygen deprivation in . Safflower is cultivated from up to approximately 1,000 meters in and is largely day-length neutral, allowing consistent growth across latitudes without strong photoperiodic constraints on flowering. Recent breeding efforts since 2010 have focused on enhancing safflower's resilience to marginal lands amid , selecting genotypes with improved tolerance to combined , , and stresses for expanded in degraded or arid environments. These adaptations, informed by genomic studies and field trials, aim to sustain yields under projected increases in environmental variability.

Agronomic Practices

Safflower is typically grown in rotation with cereals such as or , or , to break disease cycles and improve , avoiding consecutive planting with related crops like sunflowers or mustards that share pathogens. Sowing occurs in autumn in mild climates or in cooler regions, with a rate of 20-40 kg per to achieve optimal plant density; rows are spaced 30-45 cm apart, and seeds are planted at a depth of 2-5 cm in firm seedbeds to promote uniform emergence. During the growing season, fertilization focuses on at 40-60 kg/ha and at 20-40 kg/ha, applied based on tests to support vegetative and seed development without excess that could promote . is essential early in the cycle, achieved through pre-emergence herbicides like sulfentrazone or mechanical between rows, as safflower's slow initial makes it competitive only after the stage. is minimal for this drought-tolerant , limited to 1-2 applications during flowering if rainfall is insufficient, particularly in dryland systems. Harvest is performed by direct combining when approximately 70% of the heads have turned brown and seed moisture reaches 28-35%, typically 120-150 days after planting, to minimize shattering losses; yields generally range from 1-3 tons per under rainfed conditions, varying with rainfall and management. Breeding efforts have produced modern hybrids emphasizing high oil content (35-45%) or elevated levels for industrial uses, alongside improved seed shattering resistance. Recent developments include drought-tolerant varieties released in , such as ISF 300 from the Indian Institute of Oilseeds Research (released August 2024), which offers higher yields under water-limited conditions through enhanced root systems and stress-responsive traits. In May 2025, a variety from SAU was released, increasing oil content by 35%. Safflower's upright growth and determinate habit make it well-suited to mechanization in , compatible with standard small-grain equipment for , cultivating, and harvesting, which reduces labor and supports large-scale . preparation involves conventional on well-drained loamy soils to ensure good seed-to-soil contact, aligning with the crop's environmental preferences.

Pest and Disease Management

Safflower cultivation is susceptible to several key insect pests that primarily target foliage and roots. Aphids, particularly Uroleucon compositae (Theobald), feed on sap from leaves, stems, flowers, and capsules, leading to curling and yellowing of leaves, production of honeydew that promotes sooty mold, and overall stunted plant growth. Wireworms (Agriotes spp.) damage seeds and roots by boring into them, causing poor emergence and reduced vigor, while leaf miners (Liriomyza spp.) create serpentine tunnels in leaves, impairing photosynthesis and weakening the plant. Control measures include planting resistant varieties where available and applying systemic insecticides such as imidacloprid to target aphids and wireworms effectively. Seed and seedling stages are vulnerable to cutworms (Agrotis spp.), which sever young plants at the base, and damping-off caused by fungi like Pythium spp., resulting in rotting stems and seedling death under cool, wet conditions. Integrated pest management (IPM) strategies emphasize crop rotation with non-host crops such as cereals or legumes to break pest cycles and reduce soil-borne populations. The spiny traits of safflower leaves may offer partial mechanical resistance to some foliage pests. Among diseases, Fusarium wilt caused by Fusarium oxysporum f. sp. carthami leads to yellowing, wilting, and vascular discoloration, particularly in warmer soils; safflower rust (Puccinia carthami) produces orange pustules on leaves and stems, defoliating plants; and Alternaria leaf spot (Alternaria carthami) causes circular brown spots with yellow halos on leaves, with higher incidence in humid environments. Management involves using certified, disease-free seeds treated with appropriate fungicides, foliar applications of propiconazole for rust and Alternaria, and avoiding susceptible rotations. Root-knot nematodes (Meloidogyne spp.) pose a threat in sandy soils, forming on that disrupt water and nutrient uptake. Avoidance through long-term crop rotations with non- plants like grasses is the primary strategy, as safflower acts as a moderate . Post-2015 has highlighted emerging pest issues, such as increasing in populations, prompting studies on plant in safflower for tolerant varieties. Organic control methods, including neem-based extracts and biological agents like entomopathogenic fungi, have shown promise in reducing and infestations without synthetic chemicals.

Production

Global Production Trends

Safflower seed production worldwide has fluctuated between approximately 600,000 and 1,000,000 tonnes annually during the , reflecting its status as a niche oilseed . In 2020, global output reached 756,663 tonnes, up from a low of 645,243 tonnes in 2019, according to data from the (FAO). This range underscores safflower's variable cultivation scale, primarily driven by demand for its high-oleic oil in and industrial applications. Production has shown a of around 5% in recent years, fueled by expanding markets for healthy cooking oils and biofuels. Historically, safflower transitioned from a dye-producing to a dominant oilseed after the , when commercial breeding and extraction technologies shifted focus to seed for paints, varnishes, and later edible uses. Global production peaked in the at about 867,000 tonnes, supported by expanded acreage in major regions, but declined through the early due to competition from other oilseeds like sunflower and . A recovery began in the , with output rising from 732,524 tonnes in 2010, aided by renewed interest in safflower-derived and its drought-resistant traits amid policies. Average yields range from 0.8 to 1.5 tonnes per globally, heavily influenced by varietal selection, conditions, and variability, with rainfed systems typically yielding lower than irrigated ones. Recent advancements in , including varieties, have achieved yield gains of up to 20% through improved resistance and content, enhancing overall productivity. in safflower seeds remains modest, with the global market valued at around USD 1.1 billion in recent estimates; the and serve as net exporters, shipping volumes worth USD 2.1 million and USD 1.8 million respectively in 2023. Production faces volatility from , particularly in semi-arid zones where limitations can reduce yields by 30-50% during droughts, though safflower's inherent tolerance mitigates some impacts. Projections to 2030 anticipate steady growth at 5-6% annually, supported by climate-adaptive breeding and efficient agronomic practices that optimize water use without expanding acreage significantly.

Major Producing Regions

Kazakhstan leads worldwide production, accounting for approximately 33% of the global total with 242,000 metric tons in 2023 from vast steppe regions adapted to semi-arid conditions. Russia ranks second with about 138,000 metric tons, benefiting from similar dryland conditions in its southern regions. The United States follows, producing approximately 140,000 metric tons in 2023, with California contributing over 50% of domestic output through both dryland and irrigated systems, favoring high-oleic acid varieties for oil extraction. India is a major producer, accounting for approximately 12% of global output with around 90,000 metric tons in 2023, primarily cultivated in the state of Maharashtra where dryland farming predominates on rainfed soils. Other notable producing regions include , with production around 66,000 metric tons and yields exceeding 1,900 kg per hectare, alongside with 34,000 metric tons concentrated in northern provinces, and East African countries like (14,000 metric tons) and (9,000 metric tons) through smallholder systems. produces smaller volumes, approximately 10,000-20,000 metric tons, mainly in and , utilizing bird-resistant spiny cultivars to minimize wildlife damage in dryland setups. Emerging areas such as and are expanding cultivation, with focusing on regions for export-oriented growth and yielding about 39,000 metric tons in . Safflower cultivation plays a vital role in rural economies, particularly in where it sustains smallholder farmers in drought-prone areas and benefits from government subsidies under the National Mission on Edible Oils - Oil Palm (NMEO-OP), launched in as an extension of post-2015 oilseed initiatives to boost yields and income stability. In the United States and , it diversifies crop rotations, enhancing and providing alternative revenue streams for arid-zone agriculture. In the 2020s, safflower production has expanded in , driven by its inherent , with initiatives in , , and promoting resilient varieties to address and climate challenges in semi-arid zones. This growth ties into broader global trends, where total safflower seed output reached approximately 724,000 metric tons in 2023.

Uses and Applications

Culinary and Nutritional Uses

Safflower oil, extracted from the seeds of Carthamus tinctorius, is available in two primary varieties distinguished by their fatty acid profiles: high-linoleic types containing 70-80% (an omega-6 polyunsaturated ) and high-oleic types with 70-75% (a monounsaturated ). These oils are widely used in culinary applications such as cooking, frying, and salad dressings due to their neutral flavor and stability. Refined safflower oil has a high of approximately 265°C (510°F), making it suitable for high-heat methods like stir-frying and . The seeds of safflower typically contain 35-45% oil, 15-20% protein, and are notably rich in , primarily in the form of tocopherols, which contribute to the oil's properties. The flowers, meanwhile, are a source of bioactive compounds including and , which provide additional through their effects. These components support safflower's incorporation into diverse food preparations while enhancing overall dietary intake. Safflower flowers feature edible petals that are low in calories and high in antioxidants, often consumed in herbal teas, salads, or as a colorful, cost-effective substitute for in dishes like and soups. The petals impart a mild, slightly bitter and vibrant yellow-orange hue without the expense of true . Incorporating safflower oil into the offers health benefits linked to its content, including the reduction of (LDL) levels, which supports cardiovascular health. It may also aid in blood sugar control, with studies showing improvements in glycemic response over time with regular consumption. Recommended daily intake is 1-2 tablespoons (15-30 mL) of the oil, aligning with general guidelines for healthy fat consumption to maximize these effects without excess. In processed foods, safflower oil serves as a key ingredient in margarines and shortenings, where its high profile provides a softer texture and extended compared to alternatives. Recent research has explored reformulations of safflower oil by blending it with omega-3-rich sources like flaxseed oil to achieve a more balanced omega-6 to omega-3 ratio, potentially enhancing benefits and addressing modern dietary imbalances.

Industrial Uses

Safflower seeds are primarily processed for oil extraction through mechanical pressing or solvent methods using , achieving yields of 30-40% depending on variety and processing conditions. The extracted , rich in linoleic and oleic acids, exhibits excellent properties that make it suitable for applications such as paints and varnishes, where it resists yellowing over time and forms durable films. Additionally, safflower serves as a base for lubricants due to its oxidative stability and characteristics. High-oleic variants of safflower oil are increasingly utilized in via , offering a conversion efficiency of approximately 95% to fatty acid methyl esters, which enhances fuel stability and cold-flow properties. These oils also support the development of biodegradable products, including biolubricants and, through post-2010 patents, bioplastics derived from their profiles for eco-friendly and materials. The residual meal after oil extraction contains 20-30% protein and is incorporated into animal feeds as a cost-effective , providing essential while minimizing waste in processing. The vibrant red pigment carthamin is extracted from safflower flowers, yielding 0.3-0.6% from dried florets through alkaline or oxidative processes, and has historically been applied in dyeing textiles and as a colorant in . However, the rise of synthetic dyes since the mid-20th century has diminished its commercial use in these sectors, shifting focus to niche markets. Safflower oil also finds application in as an emollient, leveraging its non-comedogenic properties to moisturize without clogging pores. As a low-input tolerant to drought and poor soils, safflower supports initiatives by enabling sustainable sourcing of bio-based oils and pigments for industrial processes, reducing reliance on . In the 2020s, its role in bio-based industries has expanded, particularly in and biodegradable material production, driven by demand for renewable feedstocks in semi-arid regions.

Medicinal and Pharmacological Uses

Safflower (Carthamus tinctorius L.) has been employed in (TCM) primarily for promoting cardiovascular health and regulating menstruation, treating conditions such as , amenorrhea, postpartum abdominal pain, and blood stasis-related issues. In and Indian traditional medicine, it is utilized for its properties, particularly in managing , mastalgia, and skin conditions like . The plant's therapeutic potential stems from key bioactive compounds, including such as and , which contribute to its and effects, and hydroxysafflor yellow A (HSYA), a prominent isolated from the flowers with cardioprotective and neuroprotective activities. Additionally, serotonin derivatives like N-(p-coumaroyl)serotonin and N-feruloylserotonin, found predominantly in the seeds, exhibit anti-atherosclerotic and neuroprotective properties by modulating and . Pharmacological studies have demonstrated safflower's antioxidant effects through scavenging free radicals and reducing oxidative damage, as well as anti-tumor activities against gastric and other cancers via apoptosis induction in cancer cells. Its cardioprotective role includes reducing myocardial ischemia-reperfusion and improving blood circulation by dilating vessels and enhancing , with reviews from 2018 to 2025 highlighting these mechanisms in preclinical models. Modern research explores safflower's potential in diabetes management, where safflower oil supplementation at 8 g daily has shown improvements in glycemia, insulin sensitivity, and lipid profiles in clinical trials involving patients since the 2000s. For anti-inflammatory applications in , extracts demonstrate modulation and reduced in animal models of , though human clinical trials remain limited. Safflower is for oral consumption in dietary amounts, with clinical trials reporting good tolerability for HSYA at doses up to 75 mg daily for 14 days; however, allergies to the flowers can occur, manifesting as reactions, and high doses may pose risks during . Recent 2025 studies on emphasize cerebrovascular protection but underscore the need for more large-scale clinical trials to establish optimal dosages. Emerging research highlights serotonin derivatives from safflower seeds in preventing , with 2024 studies showing their role in modulating , reducing TNF-α levels, and improving in fructose-induced models.

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