Pharmabiz
 

Pharmacotherapy: A chiral perspective

Dr. Valliappan KannappanThursday, December 16, 2010, 08:00 Hrs  [IST]

The article is an effort to highlight the prominence and relevance of chirality in pharmacotherapy. As evident the main partners in pharmacotherapy are the patient (biological system) and the medicines. About 70 per cent of new small-molecule drugs that the Food & Drug Administration approved in 2007 contained at least one chiral molecule as its central active component.

Chirality or handedness is the phenomenon described when an object cannot be superimposed on its mirror-image (Fig.1). The medicines are designed to interact with the biological system, which is highly chiral, and bring out the desired therapeutic response. Human system is a classical chiral environment being built up of chiral discriminators viz. proteins, and carbohydrates. So we find that in most cases both the partners in pharmacotherapy are handed. As a consequence one can expect the interactions to be enantioselective and will have significant clinical implications.

For a better understanding of the situation one need to look into the various biological events the drug molecule travels through before eliciting a pharmacological effect which could be desired response or a toxic/side effect. The events of biological actions can be classified into three phases namely pharmaceutical, pharmacokinetic (PK) and pharmcodynamic (PD). In all the three phases one can expect enantioselectivity if the drug molecule under question is a racemate. There are studies that go to show that the release of enantiomers of chiral drugs from pharmaceutical formulations containing chiral excipients can be enantioselective.

Most pharmaceutical excipients employed in formulations are chiral. It is not surprising to observe enantioselectivity in the pharmacokinetic process. All the PK processes viz. absorption (active), distribution, metabolism and elimination are mediated by enzymes and most enzymes are chiral. Hence PK processes may be handed. PD phase where the actual interaction of the pharmcophoric group of the drug with the receptor happens is three-dimensional in nature. The Easson-stedman model offers simple explanation for these kinds of interactions.

Since so many drugs in common use are chiral, the question that would pop-up is whether patients would obtain more benefit from either single enantiomer rather than the racemate currently in use. Also, if an enantiopure drug is currently used, is it in fact the better one? In responding these questions, the overriding criterion is not whether one enantiomer is more active or more toxic than the other, as is often the case.

More important is the therapeutic index of each enantiomer i.e., the margin between efficacy and safety. Examination of the cases of racemic therapeutics where enantiomers have been evaluated separately for their activities reveals the following categories from a clinical perspective viz. Racemate currently used: clinically acceptable; Racemate currently used: enantiopure drug preferable; Enantiopure drug currently used: clinical advantage; Enantiomer developed to replace racemates: chiral switches.

Racemate currently used: clinically acceptable
Racemic warfarin is a well established in drug therapy. It is documented that S-warfarin is about 3-5 times more potent than the mirror-image twin (R-warfarin). A chiral switch to the S-enantiomer would merely alter the dosage requirement without any significant gain in the therapeutic index. Nevertheless the gain from using the chirally pure drug would be outweighed by the cost involved in producing them. Like racemic warfarin, racemic propranolol is well established in drug therapy and there is no evidence to suspect that the isomeric ballast provided by d-propranolol, which has less b-blocking activity than l-propranolol, is a weakness in the treatment of angina and hypertension.

Racemate currently used: enantiopure drug preferable
At times there is a genuine clinical reason for developing a single enantiomer of a previously marketed racemic therapeutic. The anesthetic Ketamine is available as a racemic mixture. S-ketamine has the desired activity (referred to as the eutomer) where as the other enantiomers (referred to as distomer) harbors the psychomimetic effects, which limits the clinical use of the racemate. It would seem preferable to use the more potent and less toxic S-enantiomer rather than the racemate.

Racemic sotalol is used as an antiarrhythmic agent but the ß-blocking activity of (R)- sotalol is a problem in patients with failing hearts. The (S)-sotalol has significant class III anti-arrhythmic activity and is not a b-blocker. Hence the use of (S)-enantiomer instead of the (R)-enantiomer provides an advantage from clinical viewpoint.

Enantiopure drug currently used: clinical advantage
There are compelling evidences supporting the clinical use of chirally pure forms in pharmacotherapy. Ethambutol, the tuberculostatic agent, is an old drug that is marketed in the enantiopure form. Ethambutol introduced for clinical use is (+)-ethambutol with an (S, S)-stereochemical configuration. Compared to the (+)-isomer, the (-)-isomer had about 1/500th of the required antibacterial activity while the meso-isomer was only 1/12th as active. In contrast, all the three isomers were almost equipotent in terms of their potential to produce the major side effect of the drug, ocular neuropathy. This side effect was related to the dose and duration of the treatment with the drug. The risk/benefit ratio of the treatment with ethambutol was greatly enhanced by marketing the (+)-enantiomer.

Other older drugs which have been used in chirally pure form include L-dopa and D-penicillamine. Although enantioselectivity in their toxicity was recognized, both were originally used a racemates until it was possible to produce pure enantiomers in a commercial scale. L-dopa is absorbed selectively by active processes and it is the D-dopa which is associated with granulocytopenia. Similarly D-penicillamine is far less prone to serious nephrotoxicity than L-penicillamine and hence D-penicillamine is preferred over L-enantiomer in the treatment of Wilson’s disease. These drugs are marketed as unichiral solely because their toxicities reside almost exclusively in one of the chiral twins.

Further familiar but less well appreciated examples of enantiopure chiral drugs in clinical use are (S)-timolol, (S)-naproxen, levamisole, (+)-methorphan which is an over the counter antitussive while (-)-methorphan is a controlled narcotic and (+)-propoxyphene which is a potent analgesic while (-)-propoxyphene is an active antitussive.

Enantiomer developed to replace racemates: chiral switches
A racemic or chiral switch may be defined as the development of a single enantiomer from a previously marketed racemate. Chiral purification is primarily intended to introduce single-enantiomer versions of the existing racemates which offer greater therapeutic value. It is observed that the innovator drug companies sometimes employ this approach as a defence strategy to rejuvenate the commercial life of a racemate whose patent protection is nearing expiry.

A classical example that fits into the first category is the chiral switch of ofloxacin to levofloxacin. Ofloxacin is fluoroquinolone, on the market since 1987 as a racemic mixture. The antibacterial activity mainly reside in the (-)-enantiomer (levofloxacin). From the microbial standpoint levofloxacin is 128 times more effective than the (+)-enantiomer and twice as effective as the racemate according to the gram positive and gram negative bacterial stocks assayed. Levofloxacin and ofloxacin has similar pharmacokinetic profile. Of particular clinical interest is the extension of the spectrum with respect to Streptococcus pnuemoniae (pneumococcus). In fact, the main guidelines on the treatment of community acquired pneumonia mention levofloxacin (and not ofloxacin) among the fluoroquinolones with activity against pneumococcus. The levofloxacin, S-(-)-isomer of ofloxacin, has an important clinical advantage over racemic ofloxacin.

The three single-enantiomer versions of widely used racemic drugs viz. esomperazole (from Omeprazole), levalbuterol (from Albuterol) and Escitalopram (from Citalopram) are examples of chiral switches that falls into the second category of commercial motives.

The potential markets for each of these are large because they are used for common conditions: reflux oesophagitis, asthma and depression. In the all the three cases the claims of increased efficacy were based on comparisons of non-equivalent doses and any advantage seemed small and clinically unimportant. The prices of esomperazole and levalbuterol were higher than their racemic alternatives. The enantiopure drugs marketed for these common diseases do not have valuable clinical advantage over the racemic products they were being promoted to replace.

There are chiral switches that have been failures. For example the clinical development of (R)-fluoxetine for depression was stopped because of statistically significant prolongation of the QT interval with high doses. Dilevalol (the chiral switch of labetalol) was thought to have advantage over labetalol, but was withdrawn from the Japanese market because of hepatotoxicity. The experience of chiral switching so far has been not very satisfying. Although chiral switching has not been a success for scientific medicine, it has been an achievement for scientific marketing.

There are number of unichiral introductions in the Indian market including(S)-amlodipine, (S)-atenolol, (S)-metoprolol, (S)-pantoprazole, eszopicolone, (R)-ondasterone, levocetrizine, and dexibuprofen.

Conclusion
The consequences of enantioselective pharmacokinetics, pharmcodynamics and toxicology of chiral drugs are not only a curious scientific phenomenon but have an array of implications in pharmacotherapy. This reinforces the need for pharmacists to educate themselves regarding issues pertaining to drug chirality and pharmacological consequences.

The burgeoning knowledge about the structure of various sites of action of drugs, exponential explosion of chiral technology and an increased awareness of possible disadvantages of using racemic therapeutics would be expected to result in increased marketing of enantiopure drugs in future. The potential benefit of enantiopure medicines include less complex, more selective pharmcodynamic profile, less complex pharmacokinetic profile, improved therapeutic index and reduced potential for complex drug interactions.

In this context, for effective clinical practice pharmacists as the drug experts must be aware of the relevance of chirality and be able to translate scientific data as well as clinical knowledge clearly to the patient and other members of the allied health care team. The pharmacist’s ability to provide pharmaceutical care will depend on their ability to educate themselves on the issues of chirality, and their willingness to assume greater responsibility in communicating with patients regarding these issues.

It is the responsibility of the pharmacists to provide update information on chiral drugs especially racemic forms to healthcare professionals to enable them to find an optimal treatment and achieve a right therapeutic control. Physicians need to reassess the rationality of existing racemates and also determine the clinical value of recent enantiopure introductions. For chiral drugs a mirror-image perspective in pharmacotherapy is vital and valuable to ensure that the left hand knows what the right hand is doing.

The author is Professor, Department of Pharmacy, Annamalai University Annamalainagar, Tamil Nadu

 
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