Ibuprofen racemic

S.K. Dwivedi, S. Sattari, F. Jamali, A.G. Mitchell, Ibuprofen racemate and enantiomers phase diagram, solubility, and thermodynamic studies, Int. J. Pharm. 87 (1992) 95-104. 

Another, commonly known example of stereoselective drug biotransformation is in vitro and in vivo conversion of inactive ( )-(—)-ibuprofen to the active (5)-(-l-)-enantiomer in drug formulations containing ibuprofen racemate [30-32]. 

Ibuprofen is an analgesic sold under various names including Advil, Motrin, and Nuprin. The material is sole as a racemic mixture, but only one enantiomer acts as ar analgesic. The other enantiomer is inactive. Assign R oi S forms to the two enantiomers of ibuprofen. 

Most of the chiral membrane-assisted applications can be considered as a modality of liquid-liquid extraction, and will be discussed in the next section. However, it is worth mentioning here a device developed by Keurentjes et al., in which two miscible chiral liquids with opposing enantiomers of the chiral selector flow counter-currently through a column, separated by a nonmiscible liquid membrane [179]. In this case the selector molecules are located out of the liquid membrane and both enantiomers are needed. The system allows recovery of the two enantiomers of the racemic mixture to be separated. Thus, using dihexyltartrate and poly(lactic acid), the authors described the resolution of different drugs, such as norephedrine, salbu-tamol, terbutaline, ibuprofen or propranolol. 

To get around this problem, pharmaceutical companies attempt to devise methods of enantioselective synthesis, which allow them to prepare only a single enantiomer rather than a racemic mixture. Viable methods have already been developed for the preparation of (5)-ibuprofen, which is now being marketed in Europe. We ll look further into enantioselective synthesis in the Chapter 19 Focus On. 

CASE STUDY ENZYME KINETIC MODELS FOR RESOLUTION OF RACEMIC IBUPROFEN ESTERS IN A MEMBRANE REACTOR... 

In this case study, an enzymatic hydrolysis reaction, the racemic ibuprofen ester, i.e. (R)-and (S)-ibuprofen esters in equimolar mixture, undergoes a kinetic resolution in a biphasic enzymatic membrane reactor (EMR). In kinetic resolution, the two enantiomers react at different rates lipase originated from Candida rugosa shows a greater stereopreference towards the (S)-enantiomer. The membrane module consisted of multiple bundles of polymeric hydrophilic hollow fibre. The membrane separated the two immiscible phases, i.e. organic in the shell side and aqueous in the lumen. Racemic substrate in the organic phase reacted with immobilised enzyme on the membrane where the hydrolysis reaction took place, and the product (S)-ibuprofen acid was extracted into the aqueous phase. 

The reaction under investigation is the enzymatic hydrolysis of racemic ethoxyethyl-ibuprofen ester. The (R)-ester is not active in the above reaction,1-3, thus simplifying the reaction mechanism, as shown in Figure 5.13. Because both enantiomers are converted according to fust-order kinetics, the conversion of one enantiomer is independent of the conversion of the other.4... 

Fig. 5.13. Lipase-catalysed hydrolysis of racemic ibuprofen ester. CRL Candida rugosa lipase.

The plotting of Dixon plot and its slope re-plot (see 5.9.5.9) is a commonly used graphical method for verification of kinetics mechanisms in a particular enzymatic reaction.9 The proposed kinetic mechanism for the system is valid if the experimental data fit the rate equation given by (5.9.4.4). In this attempt, different sets of experimental data for kinetic resolution of racemic ibuprofen ester by immobilised lipase in EMR were fitted into the rate equation of (5.7.5.6). The Dixon plot is presented in Figure 5.22. 

The hydrolysis of various para-substituted a-methylstyrene oxides was studied using 10 EHs [184]. The hydrolysis of the isobutyl compound with the enzyme from A. niger WHS the key step in the synthesis of (S)-ibuprofen (Figure 6.65). The (R)-diol was recycled via chemical racemization. 

Long, W.S., Kamaruddin, A.H. and Bhatia, S. (2005) Enzyme kinetics of kinetic resolution of racemic ibuprofen ester using enzymatic membrane reactor. Chemical Engineering Science, 60 (18), 4957—1970. 

Kwakman et al. [65] described the synthesis of a new dansyl derivative for carboxylic acids. The label, N- (bromoacetyl)-A -[5-(dimethylamino)naphthalene-l-sulfonyl]-piperazine, reacted with both aliphatic and aromatic carboxylic acids in less than 30 min. Excess reagent was converted to a relatively polar compound and subsequently separated from the derivatives on a silica cartridge. A separation of carboxylic acid enantiomers was performed after labeling with either of three chiral labels and the applicability of the method was demonstrated by determinations of racemic ibuprofen in rat plasma and human urine [66], Other examples of labels used to derivatize carboxylic acids are 3-aminoperylene [67], various coumarin compounds [68], 9-anthracenemethanol [69], 6,7-dimethoxy-l-methyl-2(lH)-quinoxalinone-3-propionylcarboxylic acid hydrazide (quinoxalinone) [70], and a quinolizinocoumarin derivative termed Lumarin 4 [71],... 

Since the separated enantiomers of a dissymmetric compound must crystallize in a different space group than does the racemic mixture, it should not be unanticipated that quantitative XRPD would be useful in the determination of enantiomeric composition. For instance, the differing XRPD characteristics of (S)-(+)-ibuprofen relative to the (-RS)-racemate have been exploited to develop a sound method for the determination of the enantiomeric purity of ibuprofen samples [53]. 

Many nonsteroidal anti-inflammatory drugs (NSAIDs) are substituted 2-arylpropionic acids. Most NSAIDs also have a chiral carbon next to the carboxylate and are administered as a racemic mixture of the two enantiomers. In general, the (S)-enantiomcr is responsible for most of the antiinflammatory activity of these agents. It was found that the (/ -enantiomer is converted to the (S)-enantiomer but the reverse does not occur (23). As with amino acid conjugation, the pathway involves reaction with ATP to form an AMP ester, which is, in turn, converted to a Co-A ester, and it is the Co-A ester that undergoes chiral inversion (Fig. 7.14). Substrates include ibuprofen, naproxen, and fenoprofen. 

Dynamic kinetic resolution (DKR) is a process in which the resolution process is coupled with in situ racemization of unreacted substrate. This has been shown to be a potential and feasible method to produce 100 % theoretical yield. We have developed a chemo-enzymatic DKR to obtain higher desired yield for (5)-ibuprofen. The combined base catalyst with lipase has resulted in high conversion and excellent ee of the product. 

The racemic (7 ,5)-ibuprofen ester obtained from chemical synthesis was characterized by FTIR and NMR. 

The procedure shows that it is feasible to combine racemization with the kinetic resolution process (hence the DKR) of R,S)- ethoxyethyl ibuprofen ester. The chemical synthesis of the ester can be applied to any esters, as it is a common procedure. The immobilized lipase preparation procedure can also be used with any enzymes or support of choice. However, the enzyme loading will need to be optimized first. The procedures for the enzymatic kinetic resolution and DKR will need to be adjusted accordingly with different esters. Through this method, the enantiopurity of (5)-ibuprofen was found to be 99.4 % and the conversion was 85 %. It was demonstrated through our work that the synthesis of (5)-ibuprofen via DKR is highly dependent on the suitability of the reaction medium between enzymatic kinetic resolution and the racemization process. This is because the compatibility between both processes is crucial for the success of the DKR. The choice of base catalyst will vary from one reaction to another, but the basic procedures used in this work can be applied. DKRs of other profens have been reported by Lin and Tsai and Chen et al. ... 

Long, W.S. Kamaruddin, A.H. andBhatia, S., Chiral Resolution of Racemic Ibuprofen Ester in an Enzymatic Membrane Reactor. Journal of Membrane Science., 2005, 247, 185-200. 

Ibuprofen is an interesting case, in that the (5)-(+)-form is an active analgesic, but the ( )-(—)-enantiomer is inactive. However, in the body there is some metabolic conversion of the inactive (I )-isomer into the active (5 )-isomer, so that the potential activity from the racemate is considerably more than 50%. Box 10.11 shows a mechanism to account for this isomerism. 

The analgesic ibuprofen is supplied for drug use in its racemic form. However, only the (S)-(+)-enantiomer is the biologically active species the (R)-(—)-form is inactive. 

Racemization via 1) HBr/AcOH and 2) KOH/MeOH Scheme 10.3 Two different preparations of (S)-ibuprofen by chemoenzymatic methods. 

Ibuprofen is a popular analgesic and anti-inflammatory drug. There are two stereoisomeric forms of ibuprofen. This drug can exist as (S)- and (/ )-stereoisomers (enantiomers). Only the (5)-form is active. The (/ )-form is completely inactive, although it is slowly converted in the body to the active (5)-form. The drug marketed under the trade names, commercially known as Advil , Anadin , Arthrofen , Brufen , Nurofen , Nuprin , Motrin etc., is a racemic mixture of (/ )- and (5)-ibuprofen. 

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