New Highly Stable Dimeric 3‐Deoxyanthocyanidin Pigments from <i>Sorghum bicolor</i> Leaf Sheath

Geera, Bhimalingeswarappa; Ojwang, Leonnard O.; Awika, Joseph M.

doi:10.1111/j.1750-3841.2012.02668.x

Cited by 58 publications

(42 citation statements)

References 18 publications

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“…Their derivatives including the methoxylated form (7‐methoxy‐apigeninidin, 7‐methoxy‐luteolinidin, and 5‐methoxy‐luteolinidin), glycosides (apigeninidin 5‐glucoside and luteolinidin 5‐glucoside), and methoxylated glycosides (7‐methoxy‐apigeninidin 5‐glucoside, 7‐methoxy‐luteolinidin 5‐glucoside, and 5‐methoxy‐luteolinidin 7‐glucoside) have also been reported and in relatively moderate or small quantities (Dykes et al., ; Dykes et al., ; Petti et al., ; Wu & Prior, ). Moreover, other novel derivatives such as dimeric 3‐deoxyanthocyanidins (for example, apigeninidin‐flavene dimer) and pyranic 3‐deoxyanthocyanidins (an additional ring connected to the C‐4 and C‐5 position) have also been reported and demonstrated promising color stability (Bai et al., ; Geera, Ojwang, & Awika, ; Khalil, Baltenweck‐Guyot, Ocampo‐Torres, & Albrecht, ).…”

Section: Sorghum Grain Bioactive Phenolic Compoundsmentioning

confidence: 99%

“…Among the red pericarp sorghum genotypes, black sorghum (genotypically red but phenotypically black) bran has the highest levels of 3‐deoxyanthocyanidins (1,790 to 6,120 µg/g), at least twice higher than red (both genotypically and phenotypically red) and brown sorghum (red genotype with pigmentated testa) bran (Table ) (Awika et al., ; Dykes et al., ; Dykes et al., ; Dykes et al., ). In addition, 3‐deoxyanthocyanidins are also distributed in other plant tissues of sorghum such as the sheath and leaves, with a concentration up to 90,000 µg/g (Geera et al., ; Petti et al., ).…”

Section: Sorghum Grain Bioactive Phenolic Compoundsmentioning

confidence: 99%

See 1 more Smart Citation

Sorghum Grain: From Genotype, Nutrition, and Phenolic Profile to Its Health Benefits and Food Applications

Xiong

Zhang

Warner

et al. 2019

Comp Rev Food Sci Food Safe

227

127

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Globally, sorghum is one of the most important but least utilized staple crops. Sorghum grain is a rich source of nutrients and health‐beneficial phenolic compounds. The phenolic profile of sorghum is exceptionally unique and more abundant and diverse than other common cereal grains. The phenolic compounds in sorghum are mainly composed of phenolic acids, 3‐deoxyanthocyanidins, and condensed tannins. Studies have shown that sorghum phenolic compounds have potent antioxidant activity in vitro, and consumption of sorghum whole grain may improve gut health and reduce the risks of chronic diseases. Recently, sorghum grain has been used to develop functional foods and beverages, and as an ingredient incorporated into other foods. Moreover, the phenolic compounds, 3‐deoxyanthocyanidins, and condensed tannins can be isolated and used as promising natural multifunctional additives in broad food applications. The objective of this review is to provide a comprehensive understanding of nutrition and phenolic compounds derived from sorghum and their related health effects, and demonstrate the potential for incorporation of sorghum in food systems as a functional component and food additive to improve food quality, safety, and health functions.

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Section: Sorghum Grain Bioactive Phenolic Compoundsmentioning

confidence: 99%

Section: Sorghum Grain Bioactive Phenolic Compoundsmentioning

confidence: 99%

Sorghum Grain: From Genotype, Nutrition, and Phenolic Profile to Its Health Benefits and Food Applications

Xiong

Zhang

Warner

et al. 2019

Comp Rev Food Sci Food Safe

227

127

View full text Add to dashboard Cite

show abstract

“…[3][4][5][6] The suggested mechanism of action was an immune-boosting effect, which is interesting in light of the presence of antiviral peptides in some parts of the sorghum plant, 7 as well as unique polyphenol compounds identified in Jobelyn. 8,9 Evidence in vitro for many biological properties of Jobelyn was recently published. The data include immune modulation, activation of natural killer cells involved in antiviral immune defense actions, and up-regulating of the production of antiviral chemokines.…”

mentioning

confidence: 99%

Clinical Efficacy of a West African Sorghum bicolor-Based Traditional Herbal Preparation Jobelyn Shows Increased Hemoglobin and CD4+ T-Lymphocyte Counts in HIV-Positive Patients

Ayuba¹,

Jensen

Benson

et al. 2014

The Journal of Alternative and Complementary Medicine

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Objectives: The purpose of this study was to evaluate a traditional herbal preparation, Jobelyn,Ò for its effects on anemia and CD4 + T-cell counts in human immunodeficiency virus-positive (HIV + ) patients in Nigeria.Design: An open-label pilot study involving 10 confirmed (HIV + ) patients who were not receiving antiretroviral therapy (ARVT) was performed, in which the patients consumed Jobelyn for 8 weeks, at a dose of 500 mg twice daily. The pilot study was followed by a controlled trial involving 51 patients, all confirmed HIV + , where the patients with CD4 + T-cell counts below 350 cells/lL were receiving ARVT. The eight patients with baseline CD4 + T-cell counts above 350 cells/lL received Jobelyn. The remaining patients who all received ARVT were randomized to ARVT alone versus ARVT + Jobelyn for 12 weeks. Results: Patients receiving ARVT showed a statistically significant improvement in their CD4 + T-cell counts across the 12-week study period ( p < 0.01). Patients receiving ARVT + Jobelyn showed a faster improvement, reaching a high level of statistical significance compared to baseline already at 6 weeks ( p < 0.001), and remained highly significant at 12 weeks ( p < 0.001). Conclusions: This is the first controlled study conducted to evaluate efficacy of Jobelyn on immune status in HIV + patients. The data suggest that consumption of Jobelyn contributed to improved hemoglobin levels and increased CD4 + T-cell counts in Nigerian HIV + patients. Further studies are needed to examine similar effects in other populations, and to elaborate on the underlying mechanisms, specifically, whether the consumption of Jobelyn supported multiple aspects of bone marrow function.

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“…For example, apigeninidin extracted from sorghum has demonstrated good stability at pH 6 to 10, with increased color intensity at alkaline pH (Akogou, Kayodé, den Besten, Linnemann, & Fogliano, ). Second, 3‐deoxyanthocyanidins are resistant to common food bleaching additives such as ascorbic acid and sulfites (Ojwang & Awika, , ), especially the complex dimeric 3‐deoxyanthocyanidins which have shown stronger resistance to bleaching in a wide pH range of 1 to 7 (Geera et al., ). Third, they have promising thermal stability and are resistant to severe heat treatments (Akogou et al., ; Yang, Dykes, & Awika, ).…”

Section: Applications Of 3‐deoxyanthocyanidinsmentioning

confidence: 99%

3‐Deoxyanthocyanidin Colorant: Nature, Health, Synthesis, and Food Applications

Xiong

Zhang

Warner

et al. 2019

Comp Rev Food Sci Food Safe

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3‐Deoxyanthocyanidins are a rare type of anthocyanins that are present in mosses, ferns, and some flowering plants. They are water‐soluble pigments and impart orange‐red and blue‐violet color to plants and play a role as phytoalexins against microbial infection and environmental stress. In contrast to anthocyanins, the lack of a hydroxyl group at the C‐3 position confers unique chemical and biochemical properties. They are potent natural antioxidants with a number of potential health benefits including cancer prevention. 3‐Deoxyanthocyanidin pigments have attracted much attention in the food industry as natural food colorants, mainly due to their higher stability during processing and handling conditions compared with anthocyanins. They are also photochromic compounds capable of causing a change in “perceived” color, when exposed to UV light, which can be used to design novel foods and beverages. Due to their interesting properties and potential industrial applications, great efforts have been made to synthesize these compounds. For biosynthesis, researchers have discovered the 3‐deoxyanthocyanidin biosynthetic pathway and their biosynthetic genes. For chemical synthesis, advances have been made to synthesize the compounds in a simpler and more efficient way as well as looking for its novel derivative with enhanced coloration properties. This review summarizes the developments in the research on 3‐deoxyanthocyanidin as a colorant, from natural sources to chemical syntheses and from health benefits to applications and future prospects, providing comprehensive insights into this group of interesting compounds.

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New Highly Stable Dimeric 3‐Deoxyanthocyanidin Pigments from Sorghum bicolor Leaf Sheath

Cited by 58 publications

References 18 publications

Sorghum Grain: From Genotype, Nutrition, and Phenolic Profile to Its Health Benefits and Food Applications

Sorghum Grain: From Genotype, Nutrition, and Phenolic Profile to Its Health Benefits and Food Applications

Clinical Efficacy of a West African Sorghum bicolor-Based Traditional Herbal Preparation Jobelyn Shows Increased Hemoglobin and CD4+ T-Lymphocyte Counts in HIV-Positive Patients

3‐Deoxyanthocyanidin Colorant: Nature, Health, Synthesis, and Food Applications

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