Heng-Keang Lim

Publications (6)17.66 Total impact

• Article: Bio-generation of stable isotope labeled internal standards for absolute and relative quantitation of drug metabolites in plasma samples by LC-MS/MS.

  Pei Li, Yong Gong, Heng-Keang Lim, Wenying Jian, Richard W Edom, Rhys Salter, Jose Silva, Naidong Weng
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  ABSTRACT: In order to achieve a better understanding of the toxicity of drug candidates, quantitative characterization of circulatory drug metabolites has been of increasing interest in current pharmaceutical research. Stable isotope labeled (STIL) internal standards (IS) are ideally used to simplify drug metabolite quantitation via liquid chromatography and tandem mass spectrometry (LC-MS/MS) analysis, primarily due to their capability to compensate matrix effects, thereby leading to faster method establishment by using generic assay conditions. However, chemical synthesis of STIL metabolites can often be resource intensive, requiring lengthy exploratory synthesis route development and/or extensive optimization to achieve the required stability for some metabolites. To overcome these challenges, we developed a general method that could generate STIL metabolites in a matter of hours from STIL parent drugs through the utilization of an appropriate in vitro metabolic incubation. This methodology can potentially save valuable synthesis resources, as well as provide timely availability of STIL IS. The following work demonstrates the proof-of-concept that multiple STIL metabolites can be generated simultaneously to provide satisfactory performance for both absolute quantitation of drug metabolites and for potential use in assessment of relative exposure coverage across species in safety tests of drug metabolites (MIST).
  Journal of chromatography. B, Analytical technologies in the biomedical and life sciences 03/2013; 926C:92-100. · 2.78 Impact Factor
• Article: Free radical metabolism of raloxifene in human liver microsomes.

  Heng-Keang Lim, Min Yang, Wing Lam, Fran Xu, Jie Chen, Yaodong Xu, H Umesha Shetty, Ke Yang, Jose Silva, David C Evans
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  ABSTRACT: Raloxifene was metabolized predominantly by CYP3A4 in human liver microsomes to a pair of carbon-carbon (RD1–2) and ether (RD3–4) linked homodimers in an nicotinamide adenine dinucleotide phosphate-dependent manner. The major homodimer formed by human liver microsomes (RD3) was different from the major homodimer formed by peroxidases (RD1). RD1, 3 and 4 were identified by both mass spectrometry (MS) and nuclear magnetic resonance (NMR) as symmetrical carbon-carbon (both carbon 7 from benzo[b]thiopen-6-ol) linked homodimer, asymmetrical ether (oxygen from 4-hydroxyphenyl and carbon 7 from benzo[b]thiopen-6-ol) linked homodimer and asymmetrical ether (oxygen and carbon 7 from benzo[b]thiopen-6-ol) linked homodimer, respectively. The structures of the homodimers RD1, 3 and 4 provided evidence for free radical metabolism of raloxifene by predominantly CYP3A4 in human liver microsomes to oxygen-centered phenoxy radicals from 4-hydroxyphenyl and benzo[b]thiopen-6-ol moieties. Further delocalization to ortho carbon-centered radical was only observed for benzo[b]thiopen-6-ol derived phenoxy radical.
  Xenobiotica 02/2012; 42(8):737-47. · 1.79 Impact Factor
• Article: Overcoming the genotoxicity of a pyrrolidine substituted arylindenopyrimidine as a potent dual adenosine A(2A)/A(1) antagonist by minimizing bioactivation to an iminium ion reactive intermediate.

  Heng-Keang Lim, Jie Chen, Carlo Sensenhauser, Kevin Cook, Robert Preston, Tynisha Thomas, Brian Shook, Paul F Jackson, Stefanie Rassnick, Kenneth Rhodes, Vedwatee Gopaul, Rhys Salter, Jose Silva, David C Evans
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  ABSTRACT: 2-Amino-4-phenyl-8-pyrrolidin-1-ylmethyl-indeno[1,2-d]pyrimidin-5-one (1) is a novel and potent selective dual A(2A)/A(1) adenosine receptor antagonist from the arylindenopyrimidine series that was determined to be genotoxic in both the Ames and Mouse Lymphoma L5178Y assays only following metabolic activation. Compound 1 was identified as a frame-shift mutagen in Salmonella typhimurium tester strain TA1537 as indicated by a significant dose-dependent increase in revertant colonies as compared to the vehicle control. The metabolic activation-dependent irreversible covalent binding of radioactivity to DNA, recovery of 1 and its enamine metabolite from acid hydrolysis of covalently modified DNA, and protection of covalent binding to DNA by both cyanide ion and methoxylamine suggest that the frame-shift mutation in TA1537 strain involved covalent binding instead of simple intercalation to DNA. Compound 1 was bioactivated to endocyclic iminium ion, aldehyde, epoxide, and α,β-unsaturated keto reactive intermediates from the detection of cyano, oxime, and glutathione conjugates by data-dependent high resolution accurate mass measurements. Collision-induced dissociation of these conjugates provided evidence for bioactivation of the pyrrolidine ring of 1. The epoxide and α,β-unsaturated keto reactive intermediates were unlikely to cause the genotoxicity of 1 because the formation of their glutathione adducts did not ameliorate the binding of compound related material to DNA. Instead, the endocyclic iminium ions and amino aldehydes were likely candidates responsible for genotoxicity based on, first, the protection afforded by both cyanide ion and methoxylamine, which reduced the potential to form covalent adducts with DNA, and, second, analogues of 1 designed with low probability to form these reactive intermediates were not genotoxic. It was concluded that 1 also had the potential to be mutagenic in humans based on observing the endocyclic iminium ion following incubation with a human liver S9 preparation and the commensurate detection of DNA adducts. An understanding of this genotoxicity mechanism supported an evidence-based approach to selectively modify the structure of 1 which resulted in analogues being synthesized that were devoid of a genotoxic liability. In addition, potency and selectivity against both adenosine A(2A) and A(1) receptors were maintained.
  Chemical Research in Toxicology 06/2011; 24(7):1012-30. · 3.78 Impact Factor
• Article: A generic method to detect electrophilic intermediates using isotopic pattern triggered data-dependent high-resolution accurate mass spectrometry.

  Heng-Keang Lim, Jie Chen, Kevin Cook, Carlo Sensenhauser, Jose Silva, David C Evans
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  ABSTRACT: A need still exists for a liquid chromatography/tandem mass spectrometry (LC/MS/MS) method that can detect broad classes of glutathione (GSH) conjugates and provide characterization of their structures. We now describe the development of a method that multiplexes high-resolution accurate mass analysis with isotope pattern triggered data-dependent product ion scans, for simultaneous detection and structural elucidation of GSH conjugates within a single analysis using a LTQ/Orbitrap. This method was initially developed to detect GSH conjugates generated from incubating 10 microM test compound with pooled human liver microsomes fortified with NADPH-regenerating system and a 2:1 ratio of 5 mM glutathione and [(13)C(2) (15)N-Gly]glutathione. The GSH conjugates were detected by isotope search of mass defect filtered and control subtracted full scan accurate MS data using MetWorks software. This was followed by elucidation of reactive intermediate structures using chemical formulae for both protonated molecules and their product ions from accurate masses in a single analysis. The mass accuracies measured for the precursor and product ions by the Orbitrap were <2 ppm in external mass calibration mode. Successful detection and characterization of GSH conjugates of acetaminophen, tienilic acid, clozapine, ticlopidine and mifepristone validated this method. In each case, the detected GSH conjugates were within the top five hits by isotope search. This method also has a broader detection capability since it is independent of the collision-induced dissociation behavior of the GSH conjugates. Furthermore, this method is amenable to a broad class of reactive intermediate trapping agents as exemplified by the simultaneous detection and structural elucidation of the cyano-N-methylene iminium ion conjugates of verapamil and its O-desmethyl metabolites, which we report for the first time. In addition to the chemically tagged reactive intermediates, this method also provides information on stable metabolites from the full scan accurate MS data.
  Rapid Communications in Mass Spectrometry 05/2008; 22(8):1295-311. · 2.79 Impact Factor
• Source

  Available from: Subrahmanyam Vangala

  Article: Metabolite identification by data-dependent accurate mass spectrometric analysis at resolving power of 60,000 in external calibration mode using an LTQ/Orbitrap.

  Heng-Keang Lim, Jie Chen, Carlo Sensenhauser, Kevin Cook, Vangala Subrahmanyam
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  ABSTRACT: Performance evaluation of accurate mass measurement by the LTQ/Orbitrap, at a resolving power of 60,000 and in external calibration mode, indicated that the Orbitrap is capable of providing high mass accuracy of <2 ppm for over 24 h post-calibration. This, together with limited trade-off between sensitivity and resolving power plus a wide dynamic range for mass accuracy, suggested that the LTQ/Orbitrap is an ideal analytical tool for structural elucidation of metabolites. The application of the LTQ/Orbitrap to identification of human liver microsomal metabolites of carvedilol was evaluated, using parent mass list triggered data-dependent multiple-stage accurate mass analysis, at a resolving power of 60,000 in external calibration mode. A metabolite identification workflow was developed to utilize chemical formulas from high-resolution accurate mass measurements to confirm structures of product ions of a drug proposed by Mass Frontier, illustrated by identification of structures used to establish lineage of product ions of carvedilol, which later served as a template for identification of its metabolites. A total of 58 in vitro metabolites of carvedilol were detected using 5-ppm mass tolerance filters for theoretical m/z of protonated molecules of predicted metabolites in addition to product ions and neutral mass losses diagnostic of carvedilol. The chemical formulas with unsaturation numbers calculated from the accurate m/z of precursor and product ions can be used to assign, with a high degree of confidence, the structures of metabolites and the sites of metabolism. The mass accuracies obtained for all full scan MS and MSn spectra were <2 ppm. The majority of the metabolites identified agreed with those previously reported except for those that have not been reported before. For example, several glutathione conjugates of carvedilol were reported for the first time, which may explain the reported hepatotoxicity during clinical trials and recent clinical use.
  Rapid Communications in Mass Spectrometry 01/2007; 21(12):1821-32. · 2.79 Impact Factor
• Article: Automated screening with confirmation of mechanism-based inactivation of CYP3A4, CYP2C9, CYP2C19, CYP2D6, and CYP1A2 in pooled human liver microsomes.

  Heng-Keang Lim, Nicholas Duczak, Linda Brougham, Michael Elliot, Krupa Patel, Kelvin Chan
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  ABSTRACT: A strategy is proposed to profile compounds for mechanism-based inactivation of CYP3A4, CYP2C19, CYP2C9, CYP2D6, and CYP1A2 based on an apparent partition ratio screen. Potent positives from the screen are confirmed by time- and concentration-dependent inactivation assays. Quasi-irreversible inhibitions are then differentiated from irreversible inactivations by oxidation with potassium ferricyanide and/or dialysis. The three-step screening procedure has been validated with acceptable accuracy and precision for detection and confirmation of mechanism-based inactivators in drug discovery. We report here the apparent partition ratios for 19 mechanism-based inactivators and four quasi-irreversible inhibitors obtained under the same experimental conditions. The apparent partition ratio screen was automated to provide throughput for determining structure-mechanism-based inactivation relationships. Information about reversibility can be used to assess potential toxicity mediated by covalent adducts, as well as the potential for pharmacokinetic drug-drug interactions. Direct comparison of known mechanism-based inactivators and quasi-irreversible inhibitors, based on our screening of apparent partition ratios, has identified ritonavir, mibefradil, and azamulin as highly effective mechanism-based inactivators; e.g., 1 mol of CYP3A4 was inactivated on turnover of about 2 mol of compound. Other mechanism-based inactivators we identified include bergamottin (CYP1A2 besides previously reported CYP3A4), troglitazone (CYP3A4), rosiglitazone (CYP3A4), and pioglitazone (CYP3A4). Comparison of the apparent partition ratios and inactivation clearance data for the three glitazones suggests that the chromane moiety on troglitazone contributes to its greater potency for mechanism-based inactivation.
  Drug Metabolism and Disposition 09/2005; 33(8):1211-9. · 3.73 Impact Factor