In the field of

drug discovery In the fields of medicine, biotechnology and pharmacology, drug discovery is the process by which new candidate medications are discovered. Historically, drugs were discovered by identifying the active ingredient from traditional remedies or by ...

, retrometabolic drug design is a strategy for the design of safer drugs either using predictable metabolism to an inactive

moiety Moiety may refer to: Chemistry * Moiety (chemistry), a part or functional group of a molecule ** Moiety conservation, conservation of a subgroup in a chemical species Anthropology * Moiety (kinship), either of two groups into which a society is ...

or using targeted drug delivery approaches. The phrase retrometabolic drug design was coined by Nicholas Bodor. The method is analogous to retrosynthetic analysis where the synthesis of a target molecule is planned backwards. In retrometabolic drug design, metabolic reaction information of drugs is used to design parent drugs whose metabolism and distribution can be controlled to target and eliminate the drug to increase efficacy and minimize undesirable side effects. The new drugs thus designed achieve selective organ and/or therapeutic site drug targeting and produce safe therapeutic agents and safe environmental chemicals. These approaches represent systematic methodologies that thoroughly integrate structure-activity (SAR) and structure-metabolism (SMR) relationships and are aimed at designing safe, locally active compounds with improved therapeutic index (ratio of benefit vs. side effect). Retrometabolic Drug Design loop

Classification

The concept of retrometabolic drug design encompasses two distinct approaches. One approach is the design of soft drugs (SDs), new, active therapeutic agents, often isosteric or isolelectronic analogs of a lead compound, with a chemical structure specifically designed to allow predictable metabolism into inactive metabolites after exerting their desired therapeutic effect(s). The other approach is the design of chemical delivery systems (CDSs). CDSs are biologically inert molecules intended to enhance drug delivery to a particular organ or site and requiring several conversion steps before releasing the active drug. Although both retrometabolic design approaches involve chemical modifications of the molecular structure and both require enzymatic reactions to fulfill drug targeting, the principles of SD and CDS design are distinctly different. While CDSs are inactive as administered and sequential enzymatic reactions provide the differential distribution and ultimately release the active drug, SDs are active as administered and are designed to be easily metabolized into inactive species. Assuming an ideal situation, with a CDS the drug is present at the site and nowhere else in the body because enzymatic processes destroy the drug at those sites. Whereas, CDSs are designed to achieve drug targeting at a selected organ or site, SDs are designed to afford a differential distribution that can be regarded as reverse targeting.

Soft drugs

Since its introduction by Nicholas Bodor in the late 1970s, the soft drug concept generated considerable research both in academic and in industrial settings. Bodor defined soft drugs as biologically active, therapeutically useful chemical compounds characterized by a predictable and controllable in vivo metabolism to non-toxic moieties after they achieve their therapeutic role. There are several rationally designed soft drugs that have either already reached the market, such as *

esmolol Esmolol, sold under the brand name Brevibloc, is a cardio selective beta1 receptor blocker with rapid onset, a very short duration of action, and no significant intrinsic sympathomimetic or membrane stabilising activity at therapeutic dosages. ...

(Breviblock) *

landiolol Landiolol (INN) is an ultra short-acting, β1-superselective intravenous adrenergic antagonist, which decreases the heart rate effectively with less negative effect on blood pressure or myocardial contractility. In comparison to other beta blo ...

(Onoact) * remifentanil (Ultiva) * loteprednol etabonate (Lotemax, Alrex, Zylet) *

clevidipine Clevidipine (INN, trade name Cleviprex) is a dihydropyridine calcium channel blocker indicated for the reduction of blood pressure when oral therapy is not feasible or not desirable. Clevidipine is used IV only and practitioners titrate this dr ...

(Cleviprex) *

remimazolam Remimazolam, sold under the brand name Byfavo, is a medication for the induction and maintenance of procedural sedation in adults for invasive diagnostic or surgical procedures lasting 30 minutes or less. It is a benzodiazepine drug, developed ...

(Byfavo) or are in late-stage development (

budiodarone Budiodarone (ATI-2042) is an antiarrhythmic agent and chemical analog of amiodarone that is currently being studied in clinical trials. Amiodarone is considered the most effective antiarrhythmic drug available, but its adverse side effects, inclu ...

celivarone Celivarone is an experimental drug being tested for use in pharmacological antiarrhythmic therapy. Cardiac arrhythmia is any abnormality in the electrical activity of the heart. Arrhythmias range from mild to severe, sometimes causing symptoms ...

, AZD3043, tecafarin). There are also compounds that can be considered as soft chemicals (e.g., malathion) or soft drugs (e.g., articaine, methylphenidate) even though they were not developed as such.

Chemical delivery systems

Since their introduction in the early 1980s, CDSs have also generated considerable research work, especially for brain and eye targeting of various therapeutic agents, including those that cannot cross the blood–brain barrier or the blood–retinal barrier on their own. Within this approach, three major general CDS classes have been identified: :* ''Enzymatic physicochemical-based (e.g., brain-targeting) CDSs:'' exploit site-specific traffic properties by sequential metabolic conversions that result in considerably altered properties :* ''Site-specific enzyme-activated (e.g., eye-targeting) CDSs:'' exploit specific enzymes found primarily, exclusively, or at higher activity at the site of action :* ''Receptor-based transient anchor-type (e.g., lung-targeting) CDSs:'' provide enhanced selectivity and activity through transient, reversible binding at the receptor This concept has been extended to many drugs and peptides, its importance illustrated by the fact that its first applications and uses were published in ''Science'' in 1975, 1981 and 1983. Its extension to the targeted brain-delivery of neuropeptides was included by the ''Harvard Health Letter'' as one of the top 10 medical advances of 1992. Several compounds have reached advanced clinical development phase, such as :* E₂-CDS (Estredox) for the brain-targeted delivery of estradiol and :* betaxoxime for the eye-targeted delivery of betaxolol In the first example above, brain-targeted CDSs employ a sequential metabolic conversion of a redox-based targetor moiety, which is closely related to the ubiquitous NAD(P)H ⇌ NAD(P)⁺ coenzyme system, to exploit the unique properties of the

blood–brain barrier The blood–brain barrier (BBB) is a highly selective semipermeable membrane, semipermeable border of endothelium, endothelial cells that prevents solutes in the circulating blood from ''non-selectively'' crossing into the extracellular fluid of ...

(BBB). After enzymatic oxidation of the NADH type drug conjugate to its corresponding NAD⁺- drug, the still inactive precursor, "locks-in" behind the BBB to provide targeted and sustained CNS-delivery of the compound of interest. The second example involves eye-specific delivery of betaxoxime, the oxime derivative of

betaxolol Betaxolol is a selective beta1 receptor blocker used in the treatment of hypertension and angina. Being selective for beta1 receptors, it typically has fewer systemic side effects than non-selective beta-blockers, for example, not causing bronc ...

. The administered, inactive β-amino-ketoxime is converted to the corresponding ketone via

oxime hydrolase In organic chemistry, an oxime is a organic compound belonging to the imines, with the general formula , where R is an organic side-chain and R’ may be hydrogen, forming an aldoxime, or another organic group, forming a ketoxime. O-substituted ...

, an enzyme recently identified with preferential activity in the eye, and then stereospecifically reduced to its alcohol form. IOP-lowering activity is demonstrated without producing the active

β-blocker Beta blockers, also spelled β-blockers, are a class of medications that are predominantly used to manage abnormal heart rhythms, and to protect the heart from a second heart attack after a first heart attack (secondary prevention). They are al ...

s systemically, making them void of any cardiovascular activity, a major drawback of classical antiglaucoma agents. Because of the advantages provided by this unique eye-targeting profile, oxime-based eye-targeting CDSs could replace the β-blockers currently used for ophthalmic applications.

History and significance

These retrometabolic design strategies were introduced by Nicholas Bodor, one of the first and most prominent advocates for the early integration of metabolism, pharmacokinetic and general physicochemical considerations in the drug design process. These drug design concepts recognize the importance of design-controlled metabolism and directly focus not on the increase of activity alone but on the increase of the activity/toxicity ratio (therapeutic index) in order to deliver the maximum benefit while also reducing or eliminating unwanted side effects. The importance of this field is reviewed in a book dedicated to the subject (Bodor, N.; Buchwald, P.; ''Retrometabolic Drug Design and Targeting'', 1st ed., Wiley & Sons, 2012), as well as by a full chapter of ''Burger's Medicinal Chemistry and Drug Design'', 7th ed. (2010) with close to 150 chemical structures and more than 450 references. At the time of its introduction, the idea of designed-in metabolism represented a significant novelty and was against mainstream thinking then in place that instead focused on minimizing or entirely eliminating drug metabolism. Bodor's work on these design concepts developed during the late 1970s and early 1980s, and came to prominence during the mid-1990s. Loteprednol etabonate, a soft corticosteroid designed and patented by Bodor received final Food and Drug Administration (FDA) approval in 1998 as the active ingredient of two ophthalmic preparations (Lotemax and Alrex), currently the only corticosteroid approved by the FDA for use in all inflammatory and allergy-related ophthalmic disorders. Its safety for long-term use further supports the soft drug concept, and in 2004, loteprednol etabonate was also approved as part of a combination product (Zylet). A second generation of soft corticosteroids such as etiprednol dicloacetate is in development for a full spectrum of other possible applications such as nasal spray for rhinitis or inhalation products for asthma. The soft drug concept ignited research work in both academic (e.g., Aston University, Göteborg University, Okayama University, Uppsala University, University of Iceland, University of Florida, Université Louis Pasteur, Yale University) and industrial (e.g., AstraZeneca, DuPont, GlaxoSmithKline, IVAX, Janssen Pharmaceutica, Nippon Organon, Novartis, ONO Pharmaceutical, Schering AG) settings. Besides corticosteroids, various other therapeutic areas have been pursued such as soft beta-blockers, soft opioid analgetics, soft estrogens, soft beta-agonists, soft anticholinergics, soft antimicrobials, soft antiarrhythmic agents, soft angiotensin converting enzyme (ACE) inhibitors, soft dihydrofolate reductase (DHFR) inhibitors, soft cancineurin inhibitors (soft immunosuppressants), soft matrix metalloproteinase (MMP) inhibitors, soft cytokine inhibitors, soft cannabinoids, soft Ca²⁺ channel blockers (see for a recent review). Following the introduction of the CDS concepts, work along those lines started in numerous pharmaceutical centers around the world, and brain-targeting CDSs were explored for many therapeutic agents such as steroids (testosterone, progestins, estradiol, dexamethasone), anti-infective agents (penicillins, sulfonamides), antivirals (acyclovir, trifluorothymidine, ribavirin), antiretrovirals (AZT, ganciclovir), anticancer agents (Lomustine, chlorambucil), neurotransmitters (dopamine, GABA), nerve growth factor (NGF) inducers, anticonvulsants (Phenytoin, valproate, stiripentol), Ca²⁺ antagonists (felodipine), MAO inhibitors, NSAIDs and neuropeptides (tryptophan, Leu-enkephalin analogs, TRH analogs, kyotorphin analogs). A number of new chemical entities (NCE) were developed based on these principles, such as E₂-CDS (Estredox or betaxoxime are in advanced clinical development phases. A review of ongoing research using the general retrometabolic design approaches is conducted biennially at the ''Retrometabolism Based Drug Design and Targeting Conference'', an international series of symposia developed and organized by Nicholas Bodor. Proceedings of each conference held have been published in the international pharmaceutical journal ''Pharmazie''. Past conferences, and their published proceedings are: :* May 1997, Amelia Island, Florida; ''Pharmazie'' 52(7) S1, 1997 :* May 1999, Amelia Island, Florida; ''Pharmazie'' 55(3), 2000 :* May 2001, Amelia Island Florida; ''Pharmazie'' 57(2), 2002 :* May 2003, Palm Coast, Florida; ''Pharmazie'' 59(5), 2004 :* May 2005, Hakone, Japan; ''Pharmazie'' 61(2), 2006 :* June 2007, Göd, Hungary; ''Pharmazie'' 63(3), 2008 :* May 2009, Orlando, Florida; ''Pharmazie'' 65(6), 2010 :* June 2011, Graz, Austria; ''Pharmazie'' 67(5), 2012 :* May 2013, Orlando, Florida; ''Pharmazie'' 69(6), 2014 :* October 2015, Orlando, Florida.

References

{{reflist, 30em Drug discovery