Vegetables as Chemical Reagents

Cordell, Geoffrey A.; Lemos, Telma L. G.; Monte, and Francisco J. Q.; Mattos, Marcos Carlos de

doi:10.1021/np0680634

Cited by 79 publications

(41 citation statements)

References 124 publications

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“…56 It is now well-established that carrots (Daucus carota), manihot (Manihot escuela and Manihot dulcis), and coconut juice (Cocos nucifera) can perform a number of significant organic chemical transformations, including the reduction of ketones and aldehydes, the reduction of double bonds, and various esterification and hydrolysis reactions. As appropriate, these reactions typically occur with high (95-99%) stereospecificity.…”

Section: Vegetables As Chemical Reagentsmentioning

confidence: 99%

“…These vegetable-based, enzymatic reactions can be repeated many times over (6-7 times) without loss of system reactivity, and have minimum energy requirements (room temperature for 3 days). As indicated, 56 this area of chemistry has a very high potential for future development in less-developed countries around the world where the range of potential reagents (such as vegetables or other commercial plants) is high, and where facilities for product determination may be limited. Long term, incorporation of these reactions into synthetic sequences for drug manufacture may make the delivery of cheaper, semisynthetic products through local production a viable alternative to costly importation.…”

Section: Vegetables As Chemical Reagentsmentioning

confidence: 99%

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Sustainable drugs and global health care

Cordell¹

2009

Quím. Nova

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Each day, Earth's finite resources are being depleted for energy, for material goods, for transportation, for housing, and for drugs. As we evolve scientifically and technologically, and as the population of the world rapidly approaches 7 billion and beyond, among the many issues with which we are faced is the continued availability of drugs for future global health care. Medicinal agents are primarily derived from two sources, synthetic and natural, or in some cases, as semi-synthetic compounds, a mixture of the two. For the developed world, efforts have been initiated to make drug production "greener", with milder reagents, shorter reaction times, and more efficient processing, thereby using less energy, and reactions which are more atom efficient, and generate fewer by-products. However, most of the world's population uses plants, in either crude or extract form, for their primary health care. There is relatively little discussion as yet, about the long term effects of the current, non-sustainable harvesting methods for medicinal plants from the wild, which are depleting these critical resources without concurrent initiatives to commercialize their cultivation. To meet future public health care needs, a paradigm shift is required in order to adopt new approaches using contemporary technology which will result in drugs being regarded as a sustainable commodity, irrespective of their source. In this presentation, several approaches to enhancing and sustaining the availability of drugs, both synthetic and natural, will be discussed, including the use of vegetables as chemical reagents, and the deployment of integrated strategies involving information systems, biotechnology, nanotechnology, and detection techniques for the development of medicinal plants with enhanced levels of bioactive agents.

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Section: Vegetables As Chemical Reagentsmentioning

confidence: 99%

Section: Vegetables As Chemical Reagentsmentioning

confidence: 99%

Sustainable drugs and global health care

Cordell¹

2009

Quím. Nova

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“…The asymmetric reduction reaction by biocatalysis, especially by whole-cell biocatalysis, has many advantages such as outstanding enantioselectivity, mild reaction conditions and environmental friendliness, and regeneration of cofactor [i.e., nicotinamide adenine dinucleotide phosphate, NAD(P)H] in situ in whole cells [16,22,25,28]. So far, bacteria, fungi, and plant tissues have been extensively researched as biocatalysts [3,6,11,16,22,29,34], and many excellent bioreaction processes have been developed. In our previous work, we devoted our efforts to explore the asymmetric reduction of aromatic ketone and b-ketoesters by yeast and plant tissues [31,34], and we also developed bioreduction processes by introducing resin adsorption and ionic liquid or organic two-phase systems [30,32,33,35].…”

Section: Introductionmentioning

confidence: 99%

Production of chiral alcohols from prochiral ketones by microalgal photo-biocatalytic asymmetric reduction reaction

Yang

Luo

et al. 2012

Journal of Industrial Microbiology and Biotechnology

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Microalgal photo-biocatalysis is a green technique for asymmetric synthesis. Asymmetric reduction of nonnatural prochiral ketones to produce chiral alcohols by microalgal photo-biocatalysis was studied in this work. Acetophenone (ACP) and ethyl acetoacetate (EAA) were chosen as model substrates for aromatic ketones and β-ketoesters, respectively. Two prokaryotic cyanophyta and two eukaryotic chlorophyta were selected as photo-biocatalysts. The results proved that nonnatural prochiral ketones can be reduced by microalgal photo-biocatalysis with high enantioselectivity. Illumination is indispensable to the photo-biocatalysis. For aromatic ketone, cyanophyta are eligible biocatalysts. For ACP asymmetric reduction reaction, about 45% yield and 97% e.e. can be achieved by the photo-biocatalysis reaction with Spirulina platensis as biocatalyst. On the contrary, chlorophyta are efficient biocatalysts for β-ketoester asymmetric reduction reaction among the four tested algae. For EAA asymmetric reduction reaction, about 70% yield and 90% e.e. can be achieved with Scenedesmus obliquus as biocatalyst. The microalgae used in this study outperformed other characterized biocatalysts such as microbial and plant cells.

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“…Diversas técnicas de imobilização de enzimas foram desenvolvidas com a finalidade de fornecer estabilidade, facilitar a recuperação e possibilitar a reutilização desses catalisadores. 5 A aplicação de enzimas ou complexos enzimáticos imobilizados 6 cresceu bastante nos últimos anos com a utilização pelas indústrias de medicamentos, detergentes, couros e panificação em seus processos. 7,8 O presente trabalho pesquisou o uso do caldo da cana-de-açúcar [Saccharum officinarum, (Poaceae)], planta facilmente cultivável e abundante no Brasil, 9,10 como fonte de enzimas (sistema imobilizado) para biotransformações em reações de esterificação.…”

Section: Introductionunclassified

Bioacetilação de álcoois catalisada por Saccharum officinarum

Assunção¹,

Lemos²,

Monte³

2009

Quím. Nova

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Recebido em 26/8/08; aceito em 11/2/09; publicado na web em 3/7/09 BIOACETYLATION OF ALCOHOLS CATALYSED BY Saccharum officinarum. Lipase-catalysed esterifications of alcohols using immobilized enzyme system from sugar cane (Saccharum officinarum) as biocatalyst afforded the corresponding esters in considerable yields (68-93%). Under optimized conditions, the material was utilized for reactions of acetylation with several advantage. It also investigated the possibility of reuse of immobilized enzymes of S. officinarum as biocatalyst under optimal reaction conditions. Keywords: biocatalysis; esterifications; Saccharum officinarum. INTRODUÇÃOO uso de plantas como fonte de catalisadores naturais constitui um importante e antigo meio empregado em síntese orgânica, sobretudo, na obtenção de moléculas de interesse biológico, tais como drogas, 1 cosméticos 2 e produtos agrícolas. 3 Nos últimos 10 anos, várias indústrias de química fina exploraram o uso de processos biocatalíticos em síntese orgânica e, em vista da necessidade da elaboração de determinadas substâncias, especificamente, com fins farmacêuticos, um grande número de enzimas foi investigado.3,4 As enzimas, embora sejam catalisadores extremamente eficientes, são espécies sensíveis à inativação causada por vários fatores, tais como, temperatura, solvente e pH. Logo, um mecanismo de proteção é essencial para que seu potencial catalítico se mantenha. Diversas técnicas de imobilização de enzimas foram desenvolvidas com a finalidade de fornecer estabilidade, facilitar a recuperação e possibilitar a reutilização desses catalisadores. 5 A aplicação de enzimas ou complexos enzimáticos imobilizados 6 cresceu bastante nos últimos anos com a utilização pelas indústrias de medicamentos, detergentes, couros e panificação em seus processos. 7,8 O presente trabalho pesquisou o uso do caldo da cana-de-açúcar [Saccharum officinarum, (Poaceae)], planta facilmente cultivável e abundante no Brasil, 9,10 como fonte de enzimas (sistema imobilizado) para biotransformações em reações de esterificação. RESULTADOS E DISCUSSÃOOs experimentos iniciais consistiram na determinação do total de proteínas (1,4%) no sistema enzimático do caldo de cana (CC) empregando o método de Hartree 11 e, na imobilização do complexo enzimático em um suporte polimérico (alginato de sódio) utilizando o método de Kalogers, 12 resultando em um percentual de 99,2% de enzimas imobilizadas do caldo de cana (EICC). As reações de biotransformações começaram por investigar a capacidade redutora das EICC tendo o benzaldeído como substrato. Diferentemente do CC bruto, 13 não houve indício de reação, provavelmente, devido à ausência dos cofatores (perdidos no processo de imobilização) que as redutases necessitam para sua atuação. Entretanto, EICC frente ao álcool anísico em mistura com anidrido acético originou um produto identificado através de cromatógrafo gasoso acoplado a espectrômetro de massas (CG-EM) como o acetato do álcool anísico, mostrando a ação biocatalisadora do complexo enzimático imobilizado. As lipases...

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Vegetables as Chemical Reagents

Cited by 79 publications

References 124 publications

Sustainable drugs and global health care

Sustainable drugs and global health care

Production of chiral alcohols from prochiral ketones by microalgal photo-biocatalytic asymmetric reduction reaction

Bioacetilação de álcoois catalisada por Saccharum officinarum

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