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School of Pharmacy

expertise: Pharmacogenomics

(including: Precision-Medicine)

David Veenstra

Education

  • PharmD, University of California, San Francisco
  • PhD in Pharmaceutical Chemistry, University of California, San Francisco

Research Interests

  • Precision medicine
  • Cost-effectiveness analysis
  • Managed care decision making

Courses Taught

  • Pharm 520: Introduction to Pharmacoeconomics
  • Pharm 542: Managed Care Pharmacy

Biography

Dr. Veenstra is a Professor in the Comparative Health Outcomes, Policy & Economics (CHOICE) Institute in the Department of Pharmacy at the University of Washington.

Dr. Veenstra’s primary research interests are the clinical, economic, and policy implications of precision medicine. His major research projects include evaluation of the cost effectiveness of population-level genomic screening, and evidence thresholds and preferences for precision medicine.

Dr. Veenstra’s research has been funded through grants from the National Human Genome Research Institute, Centers for Disease Control, and the National Cancer Institute.
He also has worked extensively with organizations such as the Academy of Managed Care Pharmacy (AMCP) and the Institute for Clinical and Economic Review (ICER) to further the practical application of cost-effectiveness analysis in managed care decision making.

Dr. Veenstra teaches courses in health economics and managed care and is an author of five book chapters and 240 peer-reviewed publications.

Recent Publications

  1. Guzauskas GF, Garbett S, Zhou Z, Schildcrout JS, Graves JA, Williams MS, Hao J, Jones LK, Spencer SJ, Jiang S, Veenstra DL*, Peterson JF*. Population Genomic Screening for Three Common Hereditary Conditions: A Cost-Effectiveness Analysis. Ann Intern Med. 2023 May;176(5):585-595. PMID: 37155986
  2. Lee W, Dayer V, Jiao B, Carlson JJ, Devine B, Veenstra DL. Use of real-world evidence in economic assessments of pharmaceuticals in the United States. J Manag Care Spec Pharm. 2021 Jan;27(1):5-14. PMID: 33377439
  3. Guzauskas GF, Basu A, Veenstra DL. Are there different evidence thresholds for genomic vs. clinical precision medicine? A VOI-based framework applied to antiplatelet drug therapy. Value in Health, 2019.
  4. Dhanda DS, Veenstra DL, Regier DA, Basu A, Carlson JJ. Payer Preferences and Willingness to Pay for Genomic Precision Medicine: A Discrete Choice Experiment. J Manag Care Spec Pharm. 2020 Apr;26(4):529-537. PMID: 32223606
  5. Henderson LM, Robinson RF, Ray L, Li T, Dillard DA, Schilling BD, Mosley M, Janssen PL, Fohner AE, Rettie AE, Thummel KE, Thornton TA, Veenstra DL. VKORC1 and Novel CYP2C9 Variation Predict Warfarin Response in Alaska Native and American Indian People. Clin Transl Sci. 2019 Mar 1. PMID: 30821933.

Kenneth Thummel

Education

  • B.S., Chemistry
  • Ph.D., Pharmaceutical Sciences

Research Interests

  • Drug metabolism kinetics
  • Intestinal first-pass metabolism
  • Mechanisms of inter-individual variability in metabolic drug clearance and drug response
  • Pharmacogenetics
  • Fat soluble vitamins and regulation of DMETs

Courses Taught

  • PCEUT 502
  • PCEUT 506
  • PCEUT 510
  • PCEUT 513
  • PCEUT 534
  • PCEUT 583
  • PCEUT 586
  • MEDCH 527

Biography

Kenneth Thummel received his Ph.D. in Pharmaceutical Science from the University of Washington in 1987 and completed a post-doctoral fellowship in Pharmacology at the University of Connecticut Health Science Center. In 1989, he was appointed to the University of Washington School of Pharmacy faculty, promoted to the rank of Professor in 2001 and was Chairman of the Department of Pharmaceutics between 2006 – 2019. He currently holds the title of Professor of Pharmaceutics and is an Adjunct Professor in the UW Department of Environmental and Occupational Health Sciences. Dr. Thummel’s research interests include the elucidation of genetic, hormonal and environmental factors that contribute to interindividual differences in xenobiotic biotransformation, in particular, intestinal cytochrome P450 3A-mediated first-pass drug metabolism, as well as gene x diet modifiers of drug response in Alaska Native and American Indian people. Dr. Thummel is a Fellow of the American Association for the Advancement of Science and the American Association of Pharmaceutical Scientists, and the recipient of the Rawls-Palmer Progress in Medicine Award from ASCPT. He is a Past-President of the American Society for Pharmacology and Experimental Therapeutics.

Selected Publications

https://www.ncbi.nlm.nih.gov/pubmed/?term=Thummel+K

Yvonne Lin

Accepting Students to Lab: Yes

Education

  • BA in Biophysics, University of California at Berkeley
  • PhD in Pharmaceutical Sciences, University of Washington

Research Interests:

  • Pharmacokinetics/pharmacogenomics
  • Natural products research
  • Regulation of drug metabolizing enzymes in children and pregnant women

Courses Taught

  • PHARBE 506
  • PHARBE 510
  • PCEUT 507
  • PCEUT 537

Biography

Dr. Lin is an Assistant Dean for Academic Affairs and Associate Professor in the Department of Pharmaceutics. She received her BA in Biophysics from the University of California at Berkeley and her PhD in Pharmaceutical Sciences from the University of Washington, and completed a postdoctoral fellowship at St. Jude Children’s Research Hospital.

Her research interests include: natural product-drug interactions, regulation of drug metabolizing enzymes in children and in pregnancy, and using metabolomics to discover endogenous biomarkers of drug metabolism and transport.

Selected Publications

https://www.ncbi.nlm.nih.gov/myncbi/yvonne.lin.1/bibliography/public/

Beth Devine

Education

  • MSc, Medical Statistics and Health Data Science, University of Bristol
  • Post-doctoral Fellowship, The CHOICE Institute, UW and Roche Global Pharma Business
  • PhD, Health Services Research, UW
  • MBA, University of San Francisco
  • PharmD, University of the Pacific
  • Clinical Pharmacy Residency, Palo Alto VA Medical Center

Research Interests

  • Evidence synthesis; systematic reviews, meta-analysis, network meta-analysis using Bayesian and frequentist methods.
  • Precision medicine: pharmacogenomics; genomic risk for hereditary cancers.
  • Health technology assessment and outcomes research including preference-based methods, discrete choice experiments and multi-criteria decision analysis.
  • Comparative effectiveness research in the context of clinical informatics.
  • Real world evidence of costs and outcomes.
  • Medication safety.

Biography

Beth Devine is Professor Emerita at The CHOICE Institute, School of Pharmacy Prior to becoming emerita, she held adjunct professorships in the Department of Health-Systems and Population Health, School of Public Health and the Department of Biomedical Informatics, School of Medicine.

She also held the Shirley and Herb Bridge Endowed Professor for Women in Pharmacy (2021-2023). She is currently a Visiting Professor at the University of Bristol, UK (2024-2026). She was a Fulbright US Scholar to the University of Murcia, Spain (2021-2022) and an Honorary Professor there (2022-2023).

She is currently president-elect of ISPOR – The Professional Society for Health Economics and Outcomes Research (2025-2026), was a member of the Board of Directors of ISPOR (2021-2024) and is an Associate Editor for the ISPOR journal Value in Health (2021-2029). She served on the ISPOR Task Force that developed guidelines to conduct network meta-analyses (2009-2011) and is currently co-chairing the ISPOR Task Force to update to these guidelines (2026). From 2014-2025 she served as an Assistant Director of the AHRQ-funded Pacific Northwest Evidence-based Practice Center. In 2013, she was elected as a member of the Society for Research Synthesis Methodology.

Prior to joining the faculty at the UW, Dr. Devine was an advanced practice (prescribing) clinical pharmacist and led the Pharmacy & Therapeutics Committee at the University of California San Francisco. where she served a term as president of the California Society of Health-System Pharmacists, earning their Lifetime Achievement Award for her leadership role in advancing the scope of practice for California pharmacists through legislation (1994).

Courses Taught

  • HEOR DS 510: Data Science in Health Economics and Outcomes Research
  • HECON 530 – Health Technology Assessment in a Global Environment
  • HEOR 531/HSERV 584 – Assessing Outcomes in Health & Medicine
  • PHRMCY 514 – Design and Analysis of Medical Studies

Selected Peer-Reviewed Publications

MyNCBI Bibliography
https://www.ncbi.nlm.nih.gov/myncbi/emily.devine.1/bibliography/public/

Google Scholar Profile: (n = 336; citations: 11294; h-index = 43, i10-index = 128)
https://scholar.google.com/citations?user=Wor4Qv0AAAAJ&hl=en

Lingtak-Neander Chan

Education

  • BS in Pharmacy (Northeastern University)
  • BS in Toxicology (Northeastern University)
  • PharmD (University of Washington)
  • Board-Certified Nutrition Support Pharmacist

Courses Taught

  • PHARM 510
  • PHARM 557
  • PHARM 569
  • PHARM 571
  • PHARM 562
  • PHRMCY 535
  • PHRMCY 537

Research

  • FocusClinical Nutrition
  • Micronutrient deficiencies and treatments
  • Nutritional anemia
  • Nutrition support in critically ill patients
  • Pharmaco- and nutrient kinetics after bariatric surgery or bowel resection

Biography

Lingtak-Neander Chan is a Professor of Pharmacy in the School of Pharmacy, and an Interdisciplinary Faculty of the Graduate Program in Nutritional Sciences at the University of Washington, Seattle. He was formerly a faculty member of the College of Pharmacy and College of Medicine at the University of Illinois at Chicago. He is a board-certified nutrition support pharmacist, an elected fellow of the American College of Nutrition and an elected fellow of the American College of Clinical Pharmacy.

His primary research focus is on the absorption kinetics of micronutrients and drugs after bariatric surgery and other GI tract repairs. Other key areas of interest include micronutrient deficiencies, intestinal failure, critical care nutrition.

Dr. Chan is the 43rd president of the American Society for Parenteral and Enteral Nutrition (ASPEN) in 2019-2020

Selected Publications

  • Chan LN. Cardiovascular Risk Reduction with Icosapent Ethyl. N Engl J Med. 2019 Apr 25;380(17):1677.
  • Blaauw R, Osland E, Sriram K, Ali A, Allard JP, Ball P, Chan LN, Jurewitsch B, Logan Coughlin K, Manzanares W, Menéndez AM, Mutiara R, Rosenfeld R, Sioson M, Visser J, Berger MM. Parenteral Provision of Micronutrients to Adult Patients: An
    Expert Consensus Paper. JPEN J Parenter Enteral Nutr. 2019 Mar;43 Suppl 1:S5-S23.
  • Dickerson RN, Kumpf VJ, Bingham AL, Blackmer AB, Canada TW, Chan LN, Cogle SV, Tucker AM. Significant Published Articles for Pharmacy Nutrition Support Practice in 2017. Hosp Pharm. 2018 Jul;53(4):239-246.
  • Worthington P, Balint J, Bechtold M, Bingham A, Chan LN, Durfee S, Jevenn AK, Malone A, Mascarenhas M, Robinson DT, Holcombe B. When Is Parenteral Nutrition Appropriate? JPEN J Parenter Enteral Nutr. 2017 Mar;41(3):324-377.
  • Chan LN, Neilson CH, Kirk EA, Colovos TF, Javelli DR, Khandelwal S. Optimization of Vitamin D Status After Roux-en-Y Gastric Bypass Surgery in Obese Patients Living in Northern Climate. Obes Surg. 2015 Dec;25(12):2321-7.
  • Chan LN, Lin YS, Tay-Sontheimer JC, Trawick D, Oelschlager BK, Flum DR, Patton KK, Shen DD, Horn JR. Proximal Roux-en-Y gastric bypass alters drug absorption pattern but not systemic exposure of CYP3A4 and P-glycoprotein substrates. Pharmacotherapy. 2015 Apr;35(4):361-9.
  • Chan LN, Seres DS, Malone A, Holcombe B, Guenter P, Plogsted S, Teitelbaum DH. Hangover and hydration therapy in the time of intravenous drug shortages: an ethical dilemma and a safety concern. JPEN J Parenter Enteral Nutr. 2014
    Nov;38(8):921-3.
  • Chan LN, Mike LA. The science and practice of micronutrient supplementations in nutritional anemia: an evidence-based review. JPEN J Parenter Enteral Nutr. 2014 Aug;38(6):656-72.
  • Chan LN. Warfarin dosing changes after bariatric surgery: implications on the mechanism for altered dose requirements and safety concerns–an alternative viewpoint. Pharmacotherapy. 2014;34(4):e26-8.
  • Chan LN. Drug-nutrient interactions. JPEN J Parenter Enteral Nutr. 2013
    Jul;37(4):450-9.
  • Mornar S, Chan LN, Mistretta S, Neustadt A, Martins S, Gilliam M. Pharmacokinetics of the etonogestrel contraceptive implant in obese women. Am J Obstet Gynecol. 2012 Aug;207(2):110.e1-6.
  • American College of Clinical Pharmacy, Boyce EG, Burkiewicz JS, Haase MR, MacLaughlin EJ, Segal AR, Chung EP, Chan LN, Rospond RM, Barone JA, Durst SW, Wells BG. ACCP position statement: Clinical faculty development. Pharmacotherapy.
    2009 Jan;29(1):124-6.
  • Pai AB, Norenberg J, Boyd A, Raj D, Chan LN. Effect of intravenous iron supplementation on hepatic cytochrome P450 3A4 activity in hemodialysis patients: a prospective, open-label study. Clin Ther. 2007 Dec;29(12):2699-705.
  • Haugen HA, Chan LN, Li F. Indirect calorimetry: a practical guide for clinicians. Nutr Clin Pract. 2007 Aug;22(4):377-88.

Josh Carlson

Education

  • PhD in Public Health Genetics, University of Washington
  • Master of Public Health in Public Health Genetics, University of Washington

Research Interests

  • Economic Evaluation of Healthcare Interventions
  • Comparative Effectiveness Research
  • Precision Medicine

Courses Taught

  • HEOR 530
  • PHRMCY 515

Biography

Dr. Carlson is a Professor in the The Comparative Health Outcomes, Policy, and Economics (CHOICE) Institute in the School of Pharmacy at the University of Washington. He graduated with his PhD from the Institute for Public Health Genetics in the School of Public Health and Community Medicine at the University of Washington in 2007 and conducted his postdoctoral training in health economics and outcomes research in the Pharmaceutical Outcomes Research and Policy Program (now the CHOICE Institute) at the University of Washington from 2007-2009. He was awarded the ISPOR Bernie J. O’Brien new investigator award in 2014.

Dr. Carlson’s research seeks to inform healthcare decision making using economic modeling, evidence synthesis, preference assessment, and health policy evaluation. This work spans many diseases, topics, and methodologies, but specific focus areas include economic analysis, precision medicine, and performance-based risk sharing arrangements. He has diverse formal training in decision modeling, discrete choice experiments, comparative effectiveness, outcomes research, and public health genetics.

Allan Rettie

Education

  • PhD in Pharmaceutical Sciences, University of Newcastle-upon-Tyne, England
  • BSc, Heriot-Watt University, Scotland
  • Postdoctoral Fellow, UW

Research Areas

  • Biochemistry of the human CYP2 and CYP4 families of P450s
  • Pharmacogenomics of cardiovascular drugs
  • P450-dependent bioactivation and associated adverse reactions

Taking Students: No

Biography

Dr. Rettie obtained a PhD in Pharmaceutical Sciences in 1983 from the University of Newcastle-upon-Tyne, England, before moving to Seattle to post-doc with Drs. Mont Juchau and Dr. Bill Trager at the UW in the areas of extra-hepatic drug metabolism and mechanisms of drug-drug interactions. He joined the faculty of the UW School of Pharmacy in 1987 and was Department Chair from 2000-2014.

Dr. Rettie’s research interests have focused mainly on the human P450 enzymes and attempts to understand mechanisms of catalysis, substrate specificity, pharmacogenetic variability and adverse drug reactions related to these monooxygenases. He has published over 190 peer-reviewed papers and held research grants from the National Institutes of Health (NIH) in these topic areas for the last 25 years.

Dr. Rettie has served on the editorial boards of Drug Metabolism and Disposition, Drug Metabolism Reviews, Journal of Pharmacology and Therapeutics, Current Drug Metabolism, Chemico-Biological Interactions and Chemical Research in Toxicology, as well as numerous NIH grant review panels. He has chaired the Scientific Affairs Committee of the International Society for Study of Xenobiotics (ISSX) and is Past Chair of the International Union of Basic and Applied Pharmacology’s Section of Drug Metabolism and Transport. In 2005, Dr. Rettie received the North American Scientific Achievement Award from ISSX for his work on elucidating metabolic and pharmacogenetic mechanisms of adverse reactions to the anticoagulant drug, warfarin, and in 2016 was appointed a Fellow of the Japanese Society for the Study of Xenobiotics.

Research Overview

Metabolism by the cytochrome P450s is the principal means whereby lipid-soluble drugs and compounds foreign to the body are converted to water-soluble derivatives that can be readily excreted. This is a beneficial effect of the enzyme system. However, it is well recognized that P450-mediated bioactivation of drugs and other xenobiotics is an important mechanism of chemical toxicity (Baillie and Rettie, 2011). Moreover, unexpected interruptions in P450 activity, due to genetic variation (Danese et al., 2012) or administration of agents that inhibit P450 activity (McDonald et al., 2015), can cause serious adverse drug reactions and contribute to disease states.

Much of the research in the Rettie laboratory focuses on the biochemistry and pharmacogenetics of the vitamin K cycle with an emphasis on how P450 enzymes interact with components of the cycle to maintain homeostasis. Human CYP2C9, for example, is the primary catalyst of (S)-warfarin metabolism (Daly et al., 2018). This vitamin K antagonist is an anticoagulant drug that is very difficult to dose correctly, and there are many drug-drug and drug-gene interactions associated with its use (Rettie and Tai, 2006).

An important goal for the laboratory is to define sources of inter-individual variability in warfarin dosing that can span a 100-fold range (Cooper et al., 2008). We have shown that common genetic polymorphisms in CYP2C9 decrease warfarin dose requirements by reducing the metabolic clearance of (S)-warfarin, while common polymorphisms in the warfarin target enzyme, VKORC1, affect warfarin dose by changing hepatic concentrations of this critical recycling enzyme (Rieder et al., 2005). We found that CYP4F2 and CYP4F11 are key vitamin K catabolizing enzymes (Edson et al., 2013) and common variation in CYP4F2 at least, affects warfarin dose, likely by modulating hepatic vitamin K concentrations (McDonald et al., 2009). We are currently examining the role of novel genetic variation in determining warfarin response in underserved populations (Henderson et al., 2019).

Other research in the laboratory is concerned with CYP4 enzymes that are potential drug targets because of their critical roles in health and disease (Edson et al., 2013; Johnson et al., 2015). Efforts are ongoing to synthesize chemical inhibitors of specific CYP4-family members to better dissect their physiological roles. CYP4B1 metabolizes a host of pro-toxins, including furans, aromatic amines, and certain fatty acids to reactive intermediates that can damage the cell. In this regard, CYP4B1 is a curious member of the CYP4 family because these enzymes typically have
a restricted substrate specificity that does not extend much beyond endogenous fatty acids. To evaluate the role of CYP4B1 in chemical toxicity, we have also developed a knockout mouse model (Parkinson et al, 2013). Most recently, we identified structural determinants of human CYP4B1 that confer high activity towards 4-ipomeanol (Wiek et al., 2015), and evaluated the substrate specificity of the ‘optimized’ human enzyme (Roellecke et al., 2017).

Our CYP4 research extends to the study of ‘orphan P450s’, like CYP4V2 and CYP4Z1, whose substrate specificity is unknown. We have reported on the fatty acid substrate specificity of CYP4V2 (Nakano et al., 2009) and the enzyme’s distribution in the eye (Nakano et al., 2012). Intriguingly, polymorphisms in CYP4V2 are found in patients suffering from the eye disease Bietti’s Crystalline Dystrophy (BCD). A knockout mouse model for CYP4V2 that recapitulates BCD has been developed in collaboration with the Kelly laboratory that should be of help in ‘deorphanizing’ the enzyme (Lockhart et al., 2014). Finally, the newest project in the Rettie lab concerns CYP4Z1, an unusual CYP that is localized to mammary tissue in humans and is up-regulated in breast cancer. We have expressed the enzyme in yeast and HepG2 cells and reported on the fatty acid metabolite profile of the enzyme (McDonald et al., 2017) and the development of novel, selective chemical inhibitors of CYP4Z1 (Kowalski et al., 2020).

In general, we use genetic re-engineering coupled with conventional protein biochemistry methods for the expression and isolation of CYP2 and CYP4 proteins and mutants of interest from heterologous hosts such as E.coli, insect cells and yeast (Mosher et al., 2008; Roberts et al., 2010). We also make extensive use of mass spectrometry for analyte quantification, including evaluation of structural changes in mutant proteins and lipidomic analysis to probe changes in endogenous metabolism due to CYP4V and CYP2C enzyme polymorphisms. Gene sequencing to discover novel polymorphisms in important pharmacogenes and disease-associated P450s is a continuing focus of the laboratory. Synthetic chemistry comes into play in the preparation of new substrates, inhibitors and metabolites for P450s of interest. Our long-term goals are to understand how structure and function are related for these important P450 enzyme families, and how their dysregulation affects drug response and disease.

Recent Publications

Deep mutational scanning of CYP2C19 in human cells reveals a substrate specificity-abundance tradeoff. Boyle GE, Sitko KA, Galloway JG, Haddox HK, Bianchi AH, Dixon A, Wheelock MK, Vandi AJ, Wang ZR, Thomson RES, Garge RK, Rettie AE, Rubin AF, Geck RC, Gillam EMJ, DeWitt WS, Matsen FA 4th, Fowler DM. Genetics. 2024 Nov 6;228(3):iyae156.

Sodium Dehydroacetate and Dehydroacetic Acid. Cherian P, Bergfeld WF, Belsito DV, Cohen DE, Klaassen CD, Rettie AE, Ross D, Slaga TJ, Snyder PW, Tilton S, Fiume M, Heldreth B. Int J Toxicol. 2024 Oct;43(4_suppl):130-134.

Isobutane, Isopentane, Butane, and Propane. Tucker R, Bergfeld WF, Belsito DV, Cohen DE, Klaassen CD, Rettie AE, Ross D, Slaga TJ, Snyder PW, Tilton S, Fiume M, Heldreth B. Int J Toxicol. 2025 Feb;44(1_suppl):17S-21S.

There and Back Again: A Perspective on 20 Years of CYP4Z1. Kowalski JP, Rettie AE. Drug Metab Dispos. 2024 Apr 11:DMD-MR-2024-001670.

Cytochrome P450 Family 4F2 and 4F11 Haplotype Mapping and Association with Hepatic Gene Expression and Vitamin K Hydroxylation Activity. Alade AN, Claw KG, McDonald MG, Prasad B, Rettie AE, Thummel KE. ACS Pharmacol Transl Sci. 2024 Feb 3;7(3):716-732.

Characterization of Gla proteoforms and non-Gla peptides of gamma carboxylated proteins: Application to quantification of prothrombin proteoforms in human plasma. Singh DK, Basit A, Rettie AE, Alade N, Thummel K, Prasad B. Anal Chim Acta. 2023 Dec 15;1284:341972.

Improved methods for the detection of heme and protoporphyrin IX adducts and quantification of heme B from cytochrome P450 containing systems. Pelletier RD, Rettie AE, Kowalski JP. J Chromatogr B Analyt Technol Biomed Life Sci. 2023 Dec 1;1231:123921.

Experimental pharmacology in precision medicine. Urbaniak A, Thummel KE, Alade AN, Rettie AE, Prasad B, De Nicolò A, Martin JH, Sheppard DN, Jarvis MF. Pharmacol Res Perspect. 2023 Dec;11(6):e01147.

An Integrative Approach to Elucidate Mechanisms Underlying the Pharmacokinetic Goldenseal-Midazolam Interaction: Application of In Vitro Assays and Physiologically Based Pharmacokinetic Models to Understand Clinical Observations. Nguyen JT, Tian DD, Tanna RS, Arian CM, Calamia JC, Rettie AE, Thummel KE, Paine MF. J Pharmacol Exp Ther. 2023 Dec;387(3):252-264.

Translating Kratom-Drug Interactions: From Bedside to Bench and Back.  Tanna RS, Cech NB, Oberlies NH, Rettie AE, Thummel KE, Paine MF. Drug Metab Dispos. 2023 Aug;51(8):923-935.

Clinical Assessment of the Drug Interaction Potential of the Psychotropic Natural Product Kratom. Tanna RS, Nguyen JT, Hadi DL, Layton ME, White JR, Cech NB, Oberlies NH, Rettie AE, Thummel KE, Paine MF. Clin Pharmacol Ther. 2023 Jun;113(6):1315-1325.

Spotlight on CYP4B1. Röder A, Hüsken S, Hutter MC, Rettie AE, Hanenberg H, Wiek C, Girhard M. Int J Mol Sci. 2023 Jan 20;24(3):2038.

A Physiological-Based Pharmacokinetic Model Embedded with a Target-Mediated Drug Disposition Mechanism Can Characterize Single-Dose Warfarin Pharmacokinetic Profiles in Subjects with Various CYP2C9 Genotypes under Different Cotreatments. Cheng S, Flora DR, Rettie AE, Brundage RC, Tracy TS. Drug Metab Dispos. 2023 Feb;51(2):257-267.

Pharmacokinetic Modeling of Warfarin І – Model-based Analysis of Warfarin Enantiomers with a Target Mediated Drug Disposition Model Reveals CYP2C9 Genotype-dependent Drug-drug Interactions of S-Warfarin. Cheng S, Flora DR, Rettie AE, Brundage RC, Tracy TS. Drug Metab Dispos. 2022 Jul 7;50(9):1287-301.

Pharmacokinetic Modeling of Warfarin ІI – Model-based Analysis of Warfarin Metabolites following Warfarin Administered either Alone or Together with Fluconazole or Rifampin. Cheng S, Flora DR, Rettie AE, Brundage RC, Tracy TS. Drug Metab Dispos. 2022 Jul 7;50(9):1302-11.

Clinical Pharmacokinetic Assessment of Kratom (Mitragyna speciosa), a Botanical Product with Opioid-like Effects, in Healthy Adult Participants. Tanna RS, Nguyen JT, Hadi DL, Manwill PK, Flores-Bocanegra L, Layton ME, White JR, Cech NB, Oberlies NH, Rettie AE, Thummel KE, Paine MF. Pharmaceutics. 2022 Mar 11;14(3):620.

Adapting regulatory drug-drug interaction guidance to design clinical pharmacokinetic natural product-drug interaction studies: A NaPDI Center recommended approach. Cox EJ, Rettie AE, Unadkat JD, Thummel KE, McCune JS, Paine MF. Clin Transl Sci. 2022 Feb;15(2):322-329.