Soft Drugs. 12. Design, Synthesis, and Evaluation of Soft Bufuralol Analogues

Hwang, Sung Kwan; Juhász, Attila; Yoon, Sung Hwa; Bodor, Nicholas

doi:10.1021/jm9904654

Cited by 30 publications

(7 citation statements)

References 42 publications

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“…The asymmetric reduction of heteroaryl ketones containing furan, thiophene, chroman, and thiochroman moieties is one of the most important reactions for producing chiral alcohols. The potential use of such optically enriched alcohols building blocks is vast, and includes, among others, pharmaceuticals and synthetic intermediates in organic synthesis . The catalysts for the asymmetric reduction of ketones can be classified into two categories: chemical and biological methodologies.…”

Section: Introductionmentioning

confidence: 99%

Asymmetric Reduction of Ketones by Biocatalysis Using Clementine Mandarin (Citrus reticulata) Fruit Grown in Annaba or by Ruthenium Catalysis for Access to Both Enantiomers

2014

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Biocatalytic reduction of prochiral ketones using freshly ripened clementine mandarin (Citrus reticulata) in aqueous medium is reported. High enantioselectivities were observed, especially for the bioreduction of indanone , tetralone , and thiochromanone with respectively 95%, 99%, and 86% enantiomeric excess (ee). Enantioselective bio- and metal-catalyzed reactions were compared. Chiral ruthenium catalysts afforded good asymmetric inductions (>75% ee) in most cases, enantiomeric excesses depending on the nature of substrate and ligand. N-aminoindanol prolinamide was revealed as the best ligand for most ketones. Interestingly, for several substrates both enantiomers could be obtained using either Citrus reticulata or ruthenium complex.

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Section: Introductionmentioning

confidence: 99%

Asymmetric Reduction of Ketones by Biocatalysis Using Clementine Mandarin (Citrus reticulata) Fruit Grown in Annaba or by Ruthenium Catalysis for Access to Both Enantiomers

2014

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“…Not only does a differential metabolism of the two enantiomers occur but also differences due to genetic polymorphism are encountered [139]. A soft drug approach may help avoid these problems, and a number of ester-containing SD candidates (25) were synthesized and then tested for b-antagonist activity by recording ECG and intra-arterial blood pressure in rats [140]. This is an example of a hypothetical inactive metabolite-based approach, as the retrometabolic design starts not from an actual, major metabolite, but from a hypothetical one (26).…”

Section: Inactive Metabolite-based Soft Drugsmentioning

confidence: 99%

Retrometabolism‐Based Drug Design and Targeting

Bodor

Buchwald

2010

Burger's Medicinal Chemistry and Drug Discovery

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Retrometabolic drug design (RMDD) approaches are systematic methodologies aimed to design safe compounds with an improved therapeutic index. RMDDs thoroughly integrate structure– activity and structure‐metabolism considerations into the entire design process and incorporate two major concepts aimed to design soft drugs and chemical delivery systems, respectively. Soft drugs (SDs) are new, active therapeutic agents designed to undergo predictable metabolism resulting in inactive metabolites after exerting their desired therapeutic effect(s). Chemical delivery systems (CDSs) are biologically inert molecules that provide enhanced and targeted delivery of an active drug to a particular organ or site through a designed sequential metabolism that involves several steps. Here, we present a comprehensive review including a general overview of the RMDD principles and a large number of specific examples from various pharmacological areas, including many recent developments, to illustrate RMDD concepts. Whenever possible, the rationale for the design as well as the pharmacokinetic and pharmacodynamic properties of the new therapeutic agents are briefly summarized and compared to those of the other compounds used in the same field.

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“…At the same time, it undergoes rapid hydrolysis in human blood, a most important advantage, since this eliminates undesired systemic activity. Essentially the same approach was adopted more recently to design ultra-short acting, soft bufuralol analogues, which are also β-blockers [52]. In this case the aromatic moiety of the lead compound, bufuralol, contains an ethyl substituent, which is metabolised to an acetic acid group in the inactive metabolite.…”

Section: The Soft Drug Approachmentioning

confidence: 99%

Strategies for Drug Design

Ionescu¹,

Caira²

2005

Drug Metabolism

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The prodrug approachAccording to the original definition by Albert [9], a prodrug is a chemical with little or no pharmacological activity that undergoes biotransformation to the therapeutically active metabolite. Actually, the 'activation' of the prodrug i.e. its conversion to the pharmacologically active form, may proceed under enzyme control, by non-enzymatic reaction, or by each of these in sequence. In general, the intention of the prodrug approach is to improve the efficacy of an established drug [10].Prodrugs are developed to address numerous shortcomings, but probably most frequently to improve oral bioavailability, either by enhancing oral absorption or by reducing pre-systemic metabolism. As indicated in Chapter 1, transport of a drug through membranes, and hence its absorption, depends critically on the balance between the drug's aqueous solubility and its lipophilicity. Optimisation of this balance is often achieved by attaching a 'carrier moiety' to a polar group such as an acidic, alcoholic, phenolic or amino-function of the active species to yield the prodrug, which should then undergo predictable metabolism to release the active form in the body. Chemical derivatisation used to improve lipophilicity often involves conversion of acidic, phenolic and alcoholic functions into appropriate esters that are metabolised to the corresponding active drugs by esterases, which are ubiquitous. Aldehydes and ketones may be converted into acetals, and amines into quaternary ammonium species, amino acid peptides and imines [11].More recent developments involving prodrugs relate to their activation in two-step targeting therapies such as ADEPT (antibody-directed enzyme prodrug therapy) and GDEPT (gene-directed enzyme prodrug therapy). These approaches hold particular promise in the area of cancer treatment through selective liberation of anticancer drugs at the surface of tumour cells. In contrast to the prodrugs described above, which are developed primarily to overcome pharmacokinetic problems, those used in ADEPT and GDEPT therapies are associated with site-specific drug delivery. Prodrug activation again relies on specific enzymes but in this case these are 'predelivered' to the desired sites of action [12].Several examples of relatively simple prodrugs are described first in this section. This is followed by a description of more complex systems that utilise prodrugs with the specific intention of site-specific delivery.A recent example of a successful prodrug is ximelagatran (Figure 9.1), which upon absorption is converted into its active metabolite melagatran [13], a potent competitive inhibitor of human α-thrombin.

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Soft Drugs. 12. Design, Synthesis, and Evaluation of Soft Bufuralol Analogues

Cited by 30 publications

References 42 publications

Asymmetric Reduction of Ketones by Biocatalysis Using Clementine Mandarin (Citrus reticulata) Fruit Grown in Annaba or by Ruthenium Catalysis for Access to Both Enantiomers

Asymmetric Reduction of Ketones by Biocatalysis Using Clementine Mandarin (Citrus reticulata) Fruit Grown in Annaba or by Ruthenium Catalysis for Access to Both Enantiomers

Retrometabolism‐Based Drug Design and Targeting

Strategies for Drug Design

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