Pharmacometabolomics

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Pharmacometabolomics, also known as pharmacometabonomics, is a field which stems from metabolomics, the quantification and analysis of metabolites produced by the body.[1][2] It refers to the direct measurement of metabolites in an individual's bodily fluids, in order to predict or evaluate the metabolism of pharmaceutical compounds, and to better understand the pharmacokinetic profile of a drug.[1][2] Alternatively, pharmacometabolomics can be applied to measure metabolite levels following the administration of a pharmaceutical compound, in order to monitor the effects of the compound on certain metabolic pathways(pharmacodynamics). This provides detailed mapping of drug effects on metabolism and the pathways that are implicated in mechanism of variation of response to treatment.[3][4][5][6][7] In addition, the metabolic profile of an individual at baseline (metabotype) provides information about how individuals respond to treatment and highlights heterogeneity within a disease state.[8] All three approaches require the quantification of metabolites found in bodily fluids and tissue, such as blood or urine, and can be used in the assessment of pharmaceutical treatment options for numerous disease states.

Goals of Pharmacometabolomics

Pharmacometabolomics is thought to provide information that complements that gained from other omics, namely genomics, transcriptomics, and proteomics. Looking at the characteristics of an individual down through these different levels of detail, there is an increasingly more accurate prediction of a person's ability to respond to a pharmaceutical compound. The genome, made up of 25 000 genes, can indicate possible errors in drug metabolism; the transcriptome, made up of 85,000 transcripts, can provide information about which genes important in metabolism are being actively transcribed; and the proteome, >10,000,000 members, depicts which proteins are active in the body to carry out these functions. Pharmacometabolomics complements the omics with direct measurement of the products of all of these reactions, but with perhaps a relatively smaller number of members: that was initially projected to be approximately 2200 metabolites,[9] but could be a larger number when gut derived metabolites and xenobiotics are added to the list. Overall, the goal of pharmacometabolomics is to more closely predict or assess the response of an individual to a pharmaceutical compound, permitting continued treatment with the right drug or dosage depending on the variations in their metabolism and ability to respond to treatment.[1][2][10]

Pharmacometabolomic analyses, through the use of a metabolomics approach, can provide a comprehensive and detailed metabolic profile or “metabolic fingerprint” for an individual patient. Such metabolic profiles can provide a complete overview of individual metabolite or pathway alterations, providing a more realistic depiction of disease phenotypes. This approach can then be applied to the prediction of response to a pharmaceutical compound by patients with a particular metabolic profile.[2][10] Pharmacometabolomic analyses of drug response are often coupled or followed up with pharmacogenetics studies. Pharmacogenetics focuses on the identification of genetic variations (e.g. single-nucleotide polymorphisms) within patients that may contribute to altered drug responses and overall outcome of a certain treatment. The results of pharmacometabolomics analyses can act to “inform” or “direct” pharmacogenetic analyses by correlating aberrant metabolite concentrations or metabolic pathways to potential alterations at the genetic level.[11] This concept has been established with two seminal publications from studies of antidepressants serotonin reuptake inhibitors [11][12] where metabolic signatures were able to define pathway implicated in response to the antidepressant and that lead to identification of genetic variants within a key gene within highlighted pathway as being implicated in variation in response. These genetic variants were not identified through genetic analysis alone and hence illustrated how metabolomics can guide and inform genetic data.

History

Although the applications of pharmacometabolomics to personalized medicine are largely only being realized now, the study of an individual's metabolism has been used to treat disease since the Middle Ages. Early physicians employed a primitive form of metabolomic analysis by smelling, tasting and looking at urine to diagnose disease. Obviously the measurement techniques needed to look at specific metabolites were unavailable at that time, but such technologies have evolved dramatically over the last decade to develop precise, high-throughput devices, as well as the accompanying data analysis software to analyze output. Currently, sample purification processes, such as liquid or gas chromatography, are coupled with either mass spectrometry (MS)-based or nuclear magnetic resonance (NMR)-based analytical methods to characterize the metabolite profiles of individual patients.[1] Continually advancing informatics tools allow for the identification, quantification and classification of metabolites to determine which pathways may influence certain pharmaceutical interventions.[1] One of the earliest studies discussing the principle and applications of pharmacometabolomics was conducted in an animal model to look at the metabolism of paracetamol and liver damage. NMR spectroscopy was used to analyze the urinary metabolic profiles of rats pre- and post-treatment with paracetamol. The analysis revealed a certain metabolic profile associated with increased liver damage following paracetamol treatment.[13] At this point, it was eagerly anticipated that such pharmacometabolomics approaches could be applied to personalized human medicine. Since this publication in 2006, the Pharmacometabolomics Research Network led by Duke University researchers and that included partnerships between centers of excellence in metabolomics, pharmacogenomics and informatics (over sixteen academic centers funded by NIGMS) has been able to illustrate for the first time the power of the pharmacometabolomics approach in informing about treatment outcomes in large clinical studies and with use of drugs that include antidepressants, statins, antihypertensives, antiplatelet therapies and antipsychotics.[3][4][5][6][7][8][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] Totally new concepts emerged from these studies on use of pharmacometabolomics as a tool that can bring a paradigm shift in the field of pharmacology. It illustrated how pharmacometabolomics can enable a Quantitative and Systems Pharmacology approach.[2] Pharmacometabolomics has been applied for the treatment of numerous human diseases, such as schizophrenia, diabetes, neural disease, depression and cancer.[1]

Personalized Medicine

As metabolite analyses are being conducted at the individual patient level, pharmacometabolomics may be considered a form of personalized medicine. This field is currently being employed in a predictive manner to determine the potential responses of therapeutic compounds in individual patients, allowing for more customized treatment regimens. It is anticipated that such pharmacometabolomics approaches will lead to the improved ability to predict an individual's response to a compound, the efficacy and metabolism of it as well as adverse or off-target effects that may take place in the body. The metabolism of certain drugs varies from patient to patient as the copy number of the genes which code for common drug metabolizing enzymes varies within the population, and leads to differences in the ability of an individual to metabolize different compounds.[36] Other important personal factors contributing to an individual's metabolic profile, such as patient nutritional status, commensal bacteria, age, and pre-existing medical conditions, are also reflected in metabolite assessment.,[5][13] Overall, pharmacometabolomic analyses combined with such approaches as pharmacogenetics, can function to identify the metabolic processes and particular genetic alterations that may compromise the anticipated efficacy of a drug in a particular patient. The results of such analyses can then allow modification of treatment regimens for an optimal outcome.[11][12][37]

Current Applications

Predicting treatment outcome

Metabotype informs about treatment outcomes

Pharmacometabolomics may be used in a predictive manner to determine the correct course of action in regards to a patient about to undergo some type of drug treatment. This involves determining the metabolic profile of a patient prior to treatment, and correlating metabolic signatures with the outcome of a pharmaceutical treatment course. Analysis of a patient's metabolic profile can reveal factors that may contribute to altered drug metabolism, allowing for predictions of the overall efficacy of a proposed treatment, as well as potential drug toxicity risks that may differ from the general population. This approach has been used to identify novel or previously characterized metabolic biomarkers in patients, which can be used to predict the expected outcome of that patient following treatment with a pharmaceutical compound.[1][37] One example of the clinical application of pharmacometabolomics are studies that looked to identify a predictive metabolic marker for the treatment of major depressive disorder (MDD).,[3][8][11][12][14] In a study with antidepressant Sertraline, the Pharmacometabolomics Network illustrated that metabolic profile at baseline of patients with major depression can inform about treatment outcomes.[8] In addition the study illustrated the power of metabolomics for defining response to placebo and compared response to placebo to response to sertraline and showed that several pathways were common to both.[8] In another study with escitalopram citalopram, metabolomic analysis of plasma from patients with MDD revealed that variations in glycine metabolism were negatively associated with patient outcome upon treatment with selective serotonin reuptake inhibitors (SSRIs), an important drug class involved in the treatment of this disease.[11][12]

Monitoring drug-related alterations in metabolic pathways

The second major application of pharmacometabolomics is the analysis of a patient's metabolic profile following the administration of a specific therapy. This process is often secondary to a pre-treatment metabolic analysis, allowing for the comparison of pre- and post-treatment metabolite concentrations. This allows for the identification of the metabolic processes and pathways that are being altered by the treatment either intentionally as a designated target of the compound, or unintentionally as a side effect. Furthermore, the concentration and variety of metabolites produced from the compound itself can also be identified, providing information on the rate of metabolism and potentially leading to development of a related compound with increased efficacy or decreased side effects. An example of this approach was used to investigate the effect of several antipsychotic drugs on lipid metabolism in patients treated for schizophrenia.[20] It was hypothesized that these antipsychotic drugs may be altering lipid metabolism in treated patients with schizophrenia, contributing to the weight gain and hypertriglyceridemia. The study monitored lipid metabolites in patients both before and after treatment with antipsychotics. The compiled pre- and post-treatment profiles were then compared to examine the effect of these compounds on lipid metabolism. The researchers found correlations between treatment with antipsychotic drugs and lipid metabolism, in both a lipid-class-specific and drug-specific manner,[20] establishing new foundations around the concept that pharmacometabolomics provides powerful tools for enabling detailed mapping of drug effects. Additional studies by the Pharmacometabolomics Research Network enabled mapping in ways not possible before effects of statins,[4][5][6][17] atenolol [18] and aspirin.[7][19] Totally new insights were gained about effect of these drugs on metabolism and they highlighted pathways implicated in response and side effects.

Metabolite Quantification and Analysis

In order to identify and quantify metabolites produced by the body, various detection methods have been employed. Most often, these involve the use of nuclear magnetic resonance (NMR) spectroscopy or mass spectrometry (MS), providing universal detection, identification and quantification of metabolites in individual patient samples. Although both processes are used in pharmacometabolomic analyses, there are advantages and disadvantages for using either nuclear magnetic resonance (NMR) spectroscopy- or mass spectrometry (MS)-based platforms in this application.

Nuclear Magnetic Resonance Spectroscopy

NMR spectroscopy has been utilized for the analysis of biological samples since the 1980s, and can be used as an effective technique for the identification and quantification of both known and unknown metabolites. For details on the principles of this technique, see NMR spectroscopy. In pharmacometabolomics analyses, NMR is advantageous because minimal sample preparation is required. Isolated patient samples typically include blood or urine due to their minimally-invasive acquisition, however, other fluid types and solid tissue samples have also been studied with this approach.[38] Due to the minimal preparation of samples before analysis, samples can be potentially fully recovered following NMR analysis (If samples are kept refrigerated to avoid degradation). This permits samples to be repeatedly analysed with extremely high levels of reproducibility, as well as maintaining precious patient samples for an alternative analysis. The high reproducibility and precision of NMR, coupled with relatively fast processing time (greater than 100 samples per day), makes this process a relatively high-throughput form of sample analysis. One disadvantage of this technique is the relatively poor metabolite detection sensitivity compared to MS-based analysis, leading to a requirement for greater initial sample volume.[38] Furthermore, the initial instrument costs are extremely high, for both NMR and MS equipment.[1]

Mass Spectrometry

An alternative approach to the identification and quantification of patient samples is through the use of mass spectrometry. This approach offers excellent precision and sensitivity in the identification, characterization and quantification of metabolites in multiple patient sample types, such as blood and urine. The mass spectrometry (MS) approach is typically coupled to gas chromatography (GC), in GC-MS or liquid chromatography (LC), in LC-MS, which aid in initially separating out the metabolite components within complex sample mixtures, and can allow for the isolation of particular metabolite subsets for analysis. GC-MS can provide relatively precise quantification of metabolites, as well as chemical structural information that can be compared to pre-existing chemical libraries.[1] GC-MS can be conducted in a relatively high-throughput manner (greater than 100 samples per day) with greater detection sensitivity than NMR analysis. A limitation of GC-MS for this application, however, is that processed metabolite components must be readily volatilized for sample processing.

LC-MS initially separates out the components of a sample mixture based on properties such as hydrophobicity, before processing them for identification and quantification by mass spectrometry (MS). Overall, LC-MS is an extremely flexible method for processing most compound types in a somewhat high-throughput manner (20-100 samples a day), also with greater sensitivity than NMR analysis. For both GC-MS and LC-MS there are limitations in the reproducibility of metabolite quantification.[1] Furthermore, sample processing for downstream mass spectrometry (MS) analysis is much more intensive than in NMR application, and results in the destruction of the original sample (via trypsin digestion).[1]

Following identification and quantification of metabolites in individual patient samples, NMR and mass spectrometry (MS) output is compiled into a dataset. These datasets include information on the identity and levels of individual metabolites detected within processed samples, as well as characteristics of each metabolite during the detection process (e.g. mass-to-charge ratios for mass spectrometry (MS)-based analysis). Multiple datasets can be created and compiled into large databases for individual patients in order to monitor varying metabolic profiles over a treatment course (i.e. pre- and post-treatment profiles). Each database is then processed through a type of informatics platform with software designed to characterize and analyze the data to generate an overall metabolic profile for the patient. To generate this overall profile, computational programs are designed to:

  • identify metabolic disease signatures[1]
  • assess treatment class (pre- or post-treatment)[1]
  • identify compounds present in a patient sample that may alter drug response, or be caused by a therapy[1]
  • identify metabolite variables and interactions among these variables[1]
  • map identified variables to known metabolic and biochemical pathways[1]

Limitations

Along with the emerging diagnostic capabilities of pharmacometabolomics, there are limitations introduced when individual variability is looked at. The ability to determine an individual's physiological state by measurement of metabolites is not contested, but the extreme variability that can be introduced by age, nutrition, and commensal organisms suggest problems in creating generalized pharmacometabolomes for patient groups.[39] However, as long as meaningful metabolic signatures can be elucidated to create baseline values, there still exists a possible means of comparison.[10]

Issues surrounding the measurement of metabolites in an individual can also arise from the methodology of metabolite detection, and there are arguments both for and against NMR and mass spectrometry (MS). Other limitations surrounding metabolite analysis include the need for proper handling and processing of samples, as well as proper maintenance and calibration of the analytical and computational equipment. These tasks require skilled and experienced technicians, and potential instrument repair costs due to continuous sample processing can be costly. The cost of the processing and analytical platforms alone is very high, making it difficult for many facilities to afford pharmacometabolomics-based treatment analyses.

Implications for Health Care

Pharmacometabolomics may decrease the burden on the healthcare system by better gauging the correct choice of treatment drug and dosage in order to optimize the response of a patient to a treatment. Hopefully, this approach will also ultimately limit the number of adverse drug reactions (ADRs) associated with many treatment regimens.[37] Overall, physicians would be better able to apply more personalized, and potentially more effective, treatments to their patients. It is important to consider, however, that the processing and analysis of the patient samples takes time, resulting in delayed treatment. Another concern about the application of pharmacometabolomics analyses to individual patient care, is deciding who should and who should not receive this in-depth, personalized treatment protocol. Certain diseases and stages of disease would have to be classified according to their requirement of such a treatment plan, but there are no criteria for this classification. Furthermore, not all hospitals and treatment institutes can afford the equipment to process and analyze patient samples on site, but sending out samples takes time and ultimately delays treatment. Health insurance coverage of such procedures may also be an issue. Certain insurance companies may discriminate against the application of this type of sample analysis and metabolite characterization. Furthermore, there would have to be regulations put in place to ensure that there was no discrimination by insurance companies against the metabolic profiles of individual patients (“high metabolizers” vs. risky “low metabolizers”).

See also

References

  1. ^ a b c d e f g h i j k l m n o p Kaddurah-Daouk, R; Kristal, B; Weinshilboum, RM (2008). "Metabolomics: A Global Biochemical Approach to Drug Response and Disease". Annual Review of Pharmacology and Toxicology. 48: 653–683. doi:10.1146/annurev.pharmtox.48.113006.094715. PMID 18184107.
  2. ^ a b c d e Kaddurah-Daouk, R; Weinshilboum, RM (2014). "Pharmacometabolomics: Implications for Clinical Pharmacology and Systems Pharmacology". Clinical Pharmacology and Therapeutics. 95 (2): 154–167. doi:10.1038/clpt.2013.217. PMID 24193171. S2CID 22649568.
  3. ^ a b c Kaddurah-Daouk, R; Yuan, P; Boyle, SH; Matson, W; Wang, Z; Zeng, Z; Zhu, H; Dougherty, GG; Yao, JK; Chen, G; Guitart, X; Carlson, PJ; Neumeister, A; Zarate, C; Krishnan, RR; Manji, HK; Drevets, W (2012). "Cerebrospinal Fluid Metabolome in Mood Disorders". Scientific Reports. 2: 667. doi:10.1038/srep00667. PMC 3446657. PMID 22993692.
  4. ^ a b c Kaddurah-Daouk, R; Baillie RA; Zhu H; Zeng ZB; Wiest MM; Nguyen UT; Watkins SM; Krauss RM (2010). "Lipidomics analysis of variation in response to simvastatin in the cholesterol and pharmacogenetics study". Metabolomics. 6 (2): 191–201. doi:10.1007/s11306-010-0207-x. PMC 2862962. PMID 20445760.
  5. ^ a b c d Kaddurah-Daouk, R; Baillie RA; Zhu H; Zeng ZB; Wiest MM; Nguyen UT; Wojnoonski K; Watkins SM; Trupp M; Krauss RM (2011). "Enteric Microbiome correlates with response to simvastatin treatment". PLOS ONE. 6 (10): e25482. doi:10.1371/journal.pone.0025482. PMC 3192752. PMID 22022402.
  6. ^ a b c Trupp, M; Zhu H; Wikoff WR; Baillie RA; Zeng ZB; Karp PD; Fiehn O; Krauss RM; Kaddurah-Daouk R (2012). "Metabolomics reveals amino acids contribute to variation in response to simvastatin treatment". PLOS ONE. 7 (7): e38386. doi:10.1371/journal.pone.0038386. PMC 3392268. PMID 22808006.
  7. ^ a b c Yerges-Armstrong, LM; Ellero-Simatos S; Georgiades A; Zhu H; Lewis JP; Horenstein RB; Beitelshees AL; Dane A; Reijmers T; Hankemeier T; Fiehn O; Shuldiner AR; Kaddurah-Daouk R (2013). "Purine Pathway Implicated in Mechanism of Resistance to Aspirin Therapy: Pharmacometabolomics-Informed Pharmacogenomics". Clinical Pharmacology and Therapeutics. 94 (4): 525–532. doi:10.1038/clpt.2013.119. PMC 4001726. PMID 23839601.
  8. ^ a b c d e Kaddurah-Daouk, R; Boyle SH; Matson W; Sharma S; Matson S; Zhu H; Bogdanov MB; Churchill E; Krishnan RR; Rush AJ; Pickering E; Delnomdedieu M (2011). "Pretreatment Metabotype as a Predictor of Response to Sertraline or Placebo in Depressed Outpatients: A Proof of Concept". Translational Psychiatry. 1 (7): e26–. doi:10.1038/tp.2011.22. PMC 3232004. PMID 22162828.
  9. ^ Weiss, RH; Kim, K (2012). "Metabolomics in the study of kidney disease". Nature Reviews Nephrology. 8 (1): 22–33. doi:10.1038/nrneph.2011.152. PMID 22025087. S2CID 23576016.
  10. ^ a b c Baraldi, E; Carraro, S; Giordano, G; Reniero, F; Perilongo, G; Zacchello, F (2009). "Metabolomics: moving towards personalized medicine". Italian Journal of Pediatrics. 35 (30): 30. doi:10.1186/1824-7288-35-30. PMC 2773773. PMID 19852788.
  11. ^ a b c d e Abo, R; Hebbring, S; Ji, Yuan; et al. (2012). "Merging pharmacometabolomics with pharmacogenomics using '1000 Genomes' single-nucleotide polymorphism imputation: selective serotonin reuptake inhibitor response pharmacogenomics". Pharmacogenetics and Genomics. 22 (4): 247–53. doi:10.1097/FPC.0b013e32835001c9. PMC 3303952. PMID 22322242.
  12. ^ a b c d Ji, Y; Hebbring, S; Zhu, H; Jenkins, GD; Biernacka, J; Snyder, K; Drews, M; Fiehn, O; Zeng, Z; Schaid, D; Mrazek, DA; Kaddurah-Daouk, R; Weinshilboum, RM (2011). "Glycine and a glycine dehydrogenase (GLDC) SNP as citalopram/escitalopram response biomarkers in depression: pharmacometabolomics-informed pharmacogenomics". Clinical Pharmacology and Therapeutics. 89 (1): 97–104. doi:10.1038/clpt.2010.250. PMC 3034442. PMID 21107318.
  13. ^ a b Clayton, A; Lindon, JC; Cloarec, O; et al. (2006). "Pharmaco-metabonomic phenotyping and personalized drug treatment". Nature. 440 (7087): 1073–1077. doi:10.1038/nature04648. PMID 16625200. S2CID 4424842.
  14. ^ a b Fan, TWM; Yuan P; Lane AN; Higashi RM; Wang Y; Hamidi AB; Zhou R; Guitart Z; Chen G; Manji HK; Kaddurah-Daouk R (2010). "Stable isotope-resolved metabolomic analysis of lithium effects on glial-neuronal metabolism and interactions". Metabolomics. 6 (2): 165–179. doi:10.1007/s11306-010-0208-9. PMC 2903070. PMID 20631920.
  15. ^ Kaddurah-Daouk, R; Bogdanov MB; Wikoff WR; Zhu H; Boyle SH; Churchill E; Wang Z; Rush AJ; Krishnan RR; Pickering E; Delnomdedieu M; Fiehn O (2013). "Pharmacometabolomic mapping of early biochemical changes induced by sertraline and placebo". Translational Psychiatry. 3 (1): e223. doi:10.1038/tp.2012.142. PMC 3566722. PMID 23340506.
  16. ^ Zhu, H; Bogdanov MB; Boyle SH; Matson W; Sharma S; Matson S; Churchill E; Fiehn O; Rush JA; Krishnan RR; Pickering E; Delnomdedieu M; Kaddurah-Daouk R; Network PR (2013). "Pharmacometabolomics of response to sertraline and to placebo in major depressive disorder - possible role for methoxyindole pathway". PLOS ONE. 8 (7): e68283. doi:10.1371/journal.pone.0068283. PMC 3714282. PMID 23874572.
  17. ^ a b Krauss, R; Zhu H; Kaddurah-Daouk R (2013). "Pharmacometabolomics of statin Response". Clinical Pharmacology and Therapeutics. 94 (5): 562–5. doi:10.1038/clpt.2013.164. PMC 4055080. PMID 23945822.
  18. ^ a b Wikoff, WR; Frye, RF; Zhu, H; Boyle, S; Churchill, E; Gong, Y; Cooper-Deho, RM; Beitelshees, AL; Lane, A; Chapman, AB; Turner, ST; Fiehn, O; Johnson, JA; Kaddurah-Daouk, R (2013). "Pharmacometabolomics Reveals Racial Differences in Response to Atenolol Treatment". PLOS ONE. 8 (3): e57639. doi:10.1371/journal.pone.0057639. PMC 3594230. PMID 23536766.
  19. ^ a b Lewis, JP; Yerges-Armstrong LM; Ellero-Simatos S; Georgiades A; Kaddurah-Daouk R; Hankemeier T (2013). "Integration of Pharmacometabolomic and Pharmacogenomic Approaches Reveals Novel Insights into Antiplatelet Therapy". Clinical Pharmacology and Therapeutics. 94 (5): 570–573. doi:10.1038/clpt.2013.153. PMC 4116100. PMID 23892404.
  20. ^ a b c Kaddurah-Daouk, R; McEvoy, J; Baillie, RA; et al. (2007). "Metabolomic mapping of atypical antipsychotic effects in schizophrenia". Molecular Psychiatry. 12 (10): 934–45. doi:10.1038/sj.mp.4002000. PMID 17440431.
  21. ^ Yao, JK; Dougherty GG; Reddy RD; Matson WR; Kaddurah-Daouk R; Keshavan MS (2013). "Associations between purine metabolites and monoamine neurotransmitters in first-episode psychosis". Frontiers in Cellular Neuroscience. 7 (90): 90. doi:10.3389/fncel.2013.00090. PMC 3678099. PMID 23781173.
  22. ^ Perroud, B; Paymaan JN; Gatchel JR; Wang L; Barupal DK; Crespo-Barreto J; Fiehn O; Zoghbi HY; Kaddurah-Daouk R (2013). "Pharmacometabolomic Signature of Ataxia SCA1 Mouse Model and Lithium Effects". PLOS ONE. 8 (8): e70610. doi:10.1371/journal.pone.0070610. PMC 3732229. PMID 23936457.
  23. ^ Yao, JK; Dougherty, GG; Reddy, RD; Keshavan, MS; Montrose, DM; Matson, WR; Rozen, S; Krishnan, RR; McEvoy, J; Kaddurah-Daouk, R (2009). "Altered interactions of tryptophan metabolites in first-episode neuroleptic-naive patients with schizophrenia". Molecular Psychiatry. 15 (9): 938–953. doi:10.1038/mp.2009.33. PMC 2953575. PMID 19401681.
  24. ^ Patkar, AA; Rozen S; Mannelli P; Matson W; Pae CU; Krishnan RR; Kaddurah-Daouk R (2009). "Alterations in tryptophan and purine metabolism in cocaine addiction: A metabolomic study". Psychopharmacology. 206 (3): 479–489. doi:10.1007/s00213-009-1625-1. PMID 19649617. S2CID 27979116.
  25. ^ Mannelli, P; Patkar A; Rozen S; Matson WR; Krishnan R; Kaddurah-Daouk R (2009). "Opioid use affects antioxidant activity and purine metabolism: Preliminary results". Human Psychopharmacology. 24 (8): 666–675. doi:10.1002/hup.1068. PMC 3183957. PMID 19760630.
  26. ^ Steffens, DC; Jiang W; Krishnan KR; Karoly ED; Mitchell MW; O'Connor CM; Kaddurah-Daouk R (2010). "Metabolomic differences in heart failure patients with and without major depression". Journal of Geriatric Psychiatry and Neurology. 23 (2): 138–146. doi:10.1177/0891988709358592. PMC 3279728. PMID 20101071.
  27. ^ Yao, JK; Dougherty, GG Jr.; Reddy, RD; Keshavan, MS; Montrose, DM; Matson, WR; McEvoy, J; Kaddurah-Daouk, R (2010). "Homeostatic imbalance of purine catabolism in first-episode neuroleptic-naïve patients with schizophrenia". PLOS ONE. 5 (3): e9508. doi:10.1371/journal.pone.0009508. PMC 2831068. PMID 20209081.
  28. ^ Condray, R; Dougherty GG; Keshavan MS; Reddy RD; Haas GL; Montrose DM; Matson WR; McEvoy J; Kaddurah-Daouk R; Yao JK (2011). "3-Hydroxykynurenine and clinical symptoms in first-episode neuroleptic-naive patients with schizophrenia". International Journal of Neuropsychopharmacology. 14 (6): 756–767. doi:10.1017/S1461145710001689. PMC 3117924. PMID 21275080.
  29. ^ Kaddurah-Daouk, R; Rozen S; Matson W; Han X; Hulette CM; Burke JR; Doraiswamy PM; Welsh-Bohmer KA (2011). "Metabolomic changes in autopsy-confirmed Alzheimer's disease". Alzheimer's & Dementia. 7 (3): 309–317. doi:10.1016/j.jalz.2010.06.001. PMC 3061205. PMID 21075060.
  30. ^ Han, X; Rozen S; Boyle SH; Hellegers C; Cheng H; Burke JR; Welsh-Bohmer KA; Doraiswamy PM; Kaddurah-Daouk R (2011). "Metabolomics in early Alzheimer's disease: identification of altered plasma sphingolipidome using shotgun lipidomics". PLOS ONE. 6 (7): e21643. doi:10.1371/journal.pone.0021643. PMC 3136924. PMID 21779331.
  31. ^ Kaddurah-Daouk, R; McEvoy J; Baillie R; Zhu H; Yao J; Nimgaonkar VL; Buckley PF; Keshavan MS; Georgiades A; Nasrallah HA (2012). "Impaired Plasmalogens in Patients with Schizophrenia". Psychiatry Research. 198 (3): 347–52. doi:10.1016/j.psychres.2012.02.019. PMID 22513041. S2CID 22582689.
  32. ^ Yao JK; Condray R; Dougherty GG Jr.; Keshavan MS; Montrose DM; Matson WR; McEvoy J; Kaddurah-Daouk R; Reddy RD (2012). "Associations between purine metabolites and clinical symptoms in schizophrenia". PLOS ONE. 7 (8): e42165. doi:10.1371/journal.pone.0042165. PMC 3419238. PMID 22916123.
  33. ^ Kaddurah-Daouk, R; Zhu, H; Sharma, S; Bogdanov, M; Rozen, SG; Matson, W; Oki, NO; Motsinger-Reif, AA; Churchill, E; Lei, Z; Appleby, D; Kling, MA; Trojanowski, JQ; Doraiswamy, PM; Arnold, SE; Pharmacometabolomics Research Network (2013). "Alterations in metabolic pathways and networks in mild cognitive impairment and early Alzheimer's disease". Translational Psychiatry. 3 (4): e244. doi:10.1038/tp.2013.18. PMC 3641405. PMID 23571809.
  34. ^ Motsinger-Reif AA, Zhu H, Kling MA, Matson W, Sharma S, Fiehn O, Reif DM, Doraiswamy PM, Trajonowski JQ, Kaddurah-Daouk R, Arnold SE. "Combining metabolomic and pathologic biomarkers for discriminating early Alzheimer's disease from normal cognitive aging". Acta Neuropathologica Communications. 1 (28).
  35. ^ McEvoy, J; Baillie RA; Zhu H; Buckley P; Keshavan MS; Nasrallah HA; Yao J; Kaddurah-Daouk R (2013). "Lipidomics reveals early metabolic changes in subjects with schizophrenia: effects of atypical antipsychotics". PLOS ONE. 8 (7): e68717. doi:10.1371/journal.pone.0068717. PMC 3722141. PMID 23894336.
  36. ^ Motulsky, AG (1957). "Drug reactions enzymes, and biochemical genetics". Journal of the American Medical Association. 165 (7): 835–837. doi:10.1001/jama.1957.72980250010016. PMID 13462859.
  37. ^ a b c Corona, G; Rizzolio, F; Giodano, A; Toffoli, G (2011). "Pharmaco-metabolomics: an emerging "omics" tool for the personalization of anticancer treatments and identification of new valuable therapeutic targets". Journal of Cellular Physiology. 227 (7): 2827–31. doi:10.1002/jcp.24003. PMID 22105661. S2CID 26060357.
  38. ^ a b Zhang, S; Nagana Gowda, GA; Ye, T; Raftery, D (2010). "Advances in NMR-based biofluid analysis and metabolite profiling". Analyst. 135 (7): 1490–8. doi:10.1039/c000091d. PMC 4720135. PMID 20379603.
  39. ^ D'Adamo, P; Ulivi, S; Beneduci, A; et al. (2010). "Metabonomics and population studies age-related amino acids excretion and inferring networks through the study of urine samples in two Italian isolated populations". Amino Acids. 38 (1): 65–73. doi:10.1007/s00726-008-0205-8. PMID 19067108. S2CID 24205460.

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