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Pharmacogenomics, the science of individualizing drug therapy based on the genetic makeup of individual patients, offers an unusual opportunity for future market growth. Applying pharmacogenomics would allow doctors to treat specific segments of the population based on their particular responses to a drug. The knowledge of the likely effectiveness of a drug in a patient makes the drug more reliable, and fewer drugs would have to be taken off the market due to adverse reactions in some, but not all, of the patients to whom they were administered. Additionally, reducing the occurrence of adverse effects to a drug effectually reduces the cost of patient care overall. This TriMark Publications study examines the market for diagnostic tests based on this science and the clinical measurement methods, the reagents and supplies being utilized in clinical medicine and the pharmaceutical industry. This report presents an overview of the latest information regarding emerging new products and industry trends and will not only quantify, but also, qualify the pharmacogenomic market segments as an area of research, product development and investment opportunity. Forecasts of the pharmacogenomic market and an analysis of products in the worldwide diagnostics market will provide a basis for understanding the significance of past developments and the immense possibilities of the future.

1. 1. Overview 8
2. 1.1 Statement of Report 8
3. 1.2 Objectives of this Report 8
4. 1.3 Scope of the Study 9
5. 1.4 Methodology 10
6. 1.5 Executive Summary 11
8. 2. Introduction 17
9. 2.1 Pharmacogenomic Testing Overview 17
10. 2.1.1 Clinical Applications 18
11. 2.1.2 Technologies for Pharmacogenomic Diagnostic Tools 19
12. 2.1.3 Drug and Diagnostic Combinations 22
13. 2.1.4 Economic Impact of Healthcare Costs 23
14. 2.2 Genetic Variation among Individuals 33
15. 2.2.1 Population Genomics 33
16. 2.2.2 SNPs and Haplotypes 33
17. 2.2.3 HapMap 35
18. 2.2.3.1 The International HapMap Project 35
19. 2.2.3.2 HapMap Participants and Funding Sources 36
20. 2.3 Drug Metabolism 37
21. 2.3.1 Adverse Drug Reactions (ADRs) 37
22. 2.3.2 Drug-Test Combinations 39
23. 2.4 Impact of Pharmacogenomics 39
24. 2.4.1 How Will Gene Variation Be Used in Predicting Drug Response? 40
25. 2.4.2 How Will Drug Development and Testing Benefit from Pharmacogenomics? 40
26. 2.4.3 Advantages of Pharmacogenomics 40
27. 2.4.4 The Diagnostics-Therapeutics Fusion 41
28. 2.4.5 Potential Challenges 42
29. 2.4.6 Poor Metabolizer Phenotype Testing 44
30. 2.4.7 Drug Repositioning 45
31. 2.5 Pharmacogenomic Tests 46
32. 2.5.1 CYP2D6 46
33. 2.5.2 CYP2C19 and CYP2C9 49
34. 2.5.3 CYP3A4 and CYP3A5 Genotyping 52
35. 2.5.4 CYP1A2 and CYP2B6 54
36. 2.5.5 NAT2, DPD, and UGT1A1 55
37. 2.6 HercepTest 56
38. 2.7 Drivers of Pharmacogenomic Testing 56
39. 2.8 Pharmacogenomics and Drug Discovery 57
40. 2.8.1 Business Implications of Pharmacogenomics in Drug Discovery 58
41. 2.8.2 Impact of Pharmacogenomics on Drug Sales 59
42. 2.8.3 Pressure to Optimize Drug Discovery Drives Use of Pharmacogenomics 60
44. 3. Pharmacogenomic Testing Market: Size, Growth and Share 61
45. 3.1 Global Pharmacogenomic Testing Markets by Technology Segments 61
46. 3.1.1 Market Structure 61
47. 3.1.2 Market Drivers in the Pharmacogenomic Diagnostics Testing Sector 62
48. 3.1.3 Market Restraints in Pharmacogenomic Diagnostic Testing Segment 62
49. 3.1.4 Principal Market Segments for Genomics Testing 62
50. 3.1.4.1 Diagnostic Testing 62
51. 3.1.4.2 Pharmacogenomic Testing 64
52. 3.1.4.3 SNP Identification 65
53. 3.1.5 Key Players in the Pharmacogenomic Diagnostics Testing Segment 67
54. 3.1.6 Pharmacogenomic Testing Sector Analysis 67
55. 3.2 U.S. Pharmacogenomic Testing Market 68
56. 3.2.1 Market Overview 69
57. 3.2.2 Diagnostic Testing Categories 71
58. 3.3 European Pharmacogenomic Diagnostic Testing Market 71
59. 3.4 Japanese Diagnostic Testing Market 71
61. 4. Pharmacogenomic Disease Markers 74
62. 4.1 SNPs 74
63. 4.1.1 SNP Identification Market 74
64. 4.1.2 Overview of SNP Identification 75
65. 4.1.3 Strategies for SNP Identification 76
66. 4.1.4 Candidate Gene Selection 77
67. 4.1.5 Whole-Genome Linkage Disequilibrium Mapping 77
68. 4.1.6 SNP Databases 78
69. 4.1.7 Computational Tools for SNP Identification 80
70. 4.1.8 SNPbrowser, Applied Biosystems 80
71. 4.1.9 Progeny Suite, Progeny Software, LLC 81
72. 4.1.10 Sentrix Array Matrix, Illumina 81
73. 4.1.11 Third Wave Technologies (a Hologic Company) 81
74. 4.2 Predictive Pharmacogenomics 81
75. 4.2.1 Cancer Testing 81
76. 4.2.2 Breast Cancer 83
77. 4.2.3 Melanoma 86
78. 4.2.4 Colon Cancer 87
79. 4.2.5 Predictive Cancer Testing Market Size 89
80. 4.2.6 Prostate Cancer 89
81. 4.2.7 Lung Cancer 89
82. 4.2.8 Acute Myelocytic Leukemia (AML) 89
83. 4.2.9 Cystic Fibrosis 90
84. 4.2.10 Genetic Test for Cardiac Ion Channel Mutations (Cardiac Channelopathies) 91
85. 4.2.11 Cardiac Transplants 92
86. 4.2.12 Thiopurine S-methyltransferase (TPMT) Genetic Test 92
87. 4.2.13 CARING Study 92
88. 4.2.14 Vilazodone 93
89. 4.2.15 STRENGTH Trials (Statin Response Examined by Genetic HAP Markers) 94
90. 4.2.16 HIV and AIDS 94
91. 4.2.17 Herceptin and Tykerb 103
92. 4.2.18 Asthma 104
93. 4.2.19 Hepatitis C Viral Load 106
94. 4.3 Examining the Impact of Pharmacogenomics in Specific Disease Application 107
95. 4.3.1 The Impact of Pharmacogenomics in Bipolar and Other Psychiatric Disorders 107
96. 4.3.2 Pharmacogenomics in Warfarin Treatment 109
97. 4.3.3 Pharmacogenomics and Breast Cancer Treatment 110
98. 4.3.4 Pharmacogenomics of Depression 110
99. 4.3.4.1 Tricyclic Antidepressants 110
100. 4.3.4.2 Serotonin Re-uptake Inhibitors 111
101. 4.3.4.3 Mirtazapine and Venlafaxine 111
102. 4.3.4.4 Nefazodone, Moclobemide, Reboxetine and Trazodone 111
103. 4.3.5 Pharmacogenomics of Cardiovascular Disease 112
104. 4.3.5.1 Beta-blockers 112
105. 4.3.5.2 Angiotensin II Type 1 Receptor Antagonists and AT1 Receptor Antagonists (Sartans) 112
106. 4.3.6 Pharmacogenomics of Thromboembolic Disorders 113
107. 4.3.6.1 Warfarin 113
108. 4.3.6.2 Acenocoumarol 113
109. 4.3.6.3 Phenprocoumon 113
110. 4.4 Gene Chips to Detect Cytochrome Variations 113
111. 4.4.1 AmpliChip CYP450-Roche Diagnostics 114
112. 4.4.2 GeneChip System-Affymetrix 114
113. 4.4.3 NanoChip Molecular Biology Workstation-Nanogen, Inc. 115
115. 5. Pharmacogenomic Testing: Development Issues 116
116. 5.1 Adoption of Pharmacogenomic Testing 116
117. 5.1.1 Pharmacogenomics Gatekeepers 116
118. 5.1.1.1 Industry 116
119. 5.1.1.1.1 Use of Pharmacogenomics in Drug Development 117
120. 5.1.1.1.2 Co-development of Pharmacogenomics Diagnostics and Drugs 117
121. 5.1.1.2 FDA as a Gatekeeper of Pharmacogenomics 118
122. 5.2 Factors Influencing the Integration of Pharmacogenomics into Clinical Trials 118
123. 5.3 Moderators of Growth 118
124. 5.3.1 Classification of Extensive vs. Poor Metabolizer 118
125. 5.3.2 Genetic Testing 119
126. 5.3.3 Cost-Benefit of Pharmacogenomic Testing 120
127. 5.3.4 Workforce Issues 121
128. 5.3.5 Reimbursement 121
129. 5.3.6 New CPT Test Codes and Payment Amounts 126
130. 5.3.7 CMS and Other Third-party Payers 127
131. 5.3.7.1 Reimbursement Challenges to Pharmacogenomic Testing 127
132. 5.3.7.2 CMS Regulatory Responsibilities 131
133. 5.3.7.3 Costs Associated with Pharmacogenomic Testing 132
134. 5.4 Clinical Guidelines and Pharmacogenomic Testing 133
135. 5.5 Good Laboratory Practice (GLP) 133
136. 5.6 Quality Assurance Issues 133
137. 5.6.1 Criteria Required to Establish a Genomic Test for Clinical Use 134
138. 5.6.2 Microarrays in Clinical Diagnostic Use 134
139. 5.7 Pre-therapeutic Pharmacogenomic Testing 135
140. 5.8 Regulatory Requirements 135
141. 5.9 Screening 136
142. 5.10 Cost of Phenotyping vs. Genotyping 137
143. 5.11 Pharmacogenomic Tests: New Product Development 138
144. 5.12 Underutilization of Pharmacogenomic Tests 138
146. 6. Business Trends in the Industry 140
147. 6.1 Pharmacogenomic Initiatives within Pharmaceutical Companies 140
148. 6.2 Pharmacogenomic Testing Growth Factors 146
149. 6.3 Acquisition, License Agreements, Internal Development and Partnerships 146
150. 6.4 Product Testing Depth in Pharmacogenomic Testing 149
151. 6.5 Government Regulation 150
152. 6.5.1 U.S. Regulations 151
153. 6.5.2 U.K. Regulations 151
154. 6.5.3 E.U. Regulations 153
155. 6.5.4 Japanese Regulations 154
156. 6.6 Increased Market Penetration in Pharmacogenomic Testing 155
157. 6.7 Legal Issues 155
158. 6.7.1 Federal Policy History 156
159. 6.7.2 State Policy History 157
160. 6.7.3 Federal Anti-Discrimination Laws and How They Apply to Genetics 157
161. 6.7.3.1 The Genetic Information Nondiscrimination Act of 2008 (GINA) 158
162. 6.7.4 Prescription Drug User Fee Act (PDUFA) 160
163. 6.7.5 Liability Concerns for Pharmacogenomics Drug and Diagnostic Developers 160
164. 6.8 Barriers to Growth 160
165. 6.9 Drivers of Growth 161
166. 6.10 Product Launches and Developments 162
167. 6.11 Investment Parameters for Diagnostic Companies 162
168. 6.12 Key Elements of the Pharmaceutical Value Chain 162
169. 6.13 An Evaluation of Successful Pharmacogenomic Business Models 162
170. 6.14 Ethical Considerations for Pharmacogenomic Applications 163
171. 6.15 Drug Repositioning Services 163
172. 6.16 Patent Protection of Pharmacogenomic Technology 165
173. 6.17 FDA Product Submission and Review Process 167
174. 6.18 FDA Pipeline for Pharmacogenomic Tests 167
175. 6.19 Adaptive Clinical Trial Design 168
177. 7. Important Technology Trends in Pharmacogenomics 170
178. 7.1 Trends in Pharmacogenomic Testing 170
179. 7.1.1 Toxicogenomics 170
180. 7.2 Drug Metabolism 171
181. 7.3 Personalized Medicine: the Genomic and Proteomic Approach 172
182. 7.4 Biomarkers 173
183. 7.4.1 Cancer 173
184. 7.4.1.1 Leukemia: Gleevec and Dasatinib (BMS-354825) 174
185. 7.4.1.2 Gefitinib (Iressa) 175
186. 7.4.1.3 Colorectal Cancer 175
187. 7.5 Cardiovascular Drugs 176
188. 7.5.1 Arrhythmia 177
189. 7.5.2 Hypertension 178
190. 7.5.3 Hyperlipidemia 179
191. 7.5.4 Myocardial Infarction 179
192. 7.5.5 Heart Failure 179
193. 7.6 Future Developments 181
194. 7.6.1 GSK's Pharmacogenomic Program 181
195. 7.6.2 Roche's Biomarker Strategy 181
196. 7.6.3 Hypertension Markets 182
197. 7.6.4 Expression Data to Integrate Pharmacology and Chemistry Data 182
198. 7.6.5 Metabolomics 183
199. 7.6.6 Theranostics 183
201. 8. Overview and Conclusions 185
202. 8.1 The Unrealized Promise of Pharmacogenomics 185
203. 8.2 The New Drug Pipeline 186
204. 8.3 Pharmacogenomics and Regulation 186
205. 8.4 Pharmacogenomics and Reimbursement 186
206. 8.5 Key Considerations for Realizing the Promise of Pharmacogenomics 187
207. 8.6 Development of Easy to Use Point of Care Pharmacogenomic Tests 188
208. 8.7 Development of Pharmacogenomic Tests during Drug Development 188
209. 8.8 Pharmacogenomics' Impact on Commercial Strategies 189
210. 8.9 Pharmacogenomics' Impact on the Blockbuster Model of Drug Development 189
211. 8.10 Pharmacogenomics' Impact on Clinical Trials 189
212. 8.11 Pharmacogenomic Business Models 190
213. 8.12 Structure of Pharmacogenomic Deals and Alliances 190
214. 8.13 Challenges to Pharmacogenomics 190
216. 9. Company Profiles 191
217. 9.1 Abbott Laboratories 191
218. 9.2 Affymetrix 192
219. 9.3 Agilent Technologies, Inc. 194
220. 9.4 Ambry Genetics 194
221. 9.5 ARCA Biopharma, Inc. 194
222. 9.6 Asper Biotech 195
223. 9.7 AstraZeneca 195
224. 9.8 Bayer 195
225. 9.9 BioTrove, Inc. 197
226. 9.10 Bristol-Myers Squibb 197
227. 9.11 Celera Group 198
228. 9.12 Clinical Data 199
229. 9.13 CombinatoRx, Inc. 200
230. 9.14 Complement Genomics Ltd. 201
231. 9.15 Covance Inc. 201
232. 9.16 CuraGen Corporation 202
233. 9.17 Cypress Bioscience, Inc. 203
234. 9.18 Dako (formerly DakoCytomation) 203
235. 9.19 deCODE Genetics 204
236. 9.20 DNAPrint Genomics 205
237. 9.21 DxS 206
238. 9.22 EraGen Biosciences 206
239. 9.23 EXACT Sciences 207
240. 9.24 Expression Analysis 207
241. 9.25 FivePrime Therapeutics 207
242. 9.26 GE Healthcare 208
243. 9.27 Gene Express, Inc. 208
244. 9.28 GeneGO Inc. 209
245. 9.29 Genelex Corporation 210
246. 9.30 Genentech 210
247. 9.31 Genizon Biosciences Inc. 212
248. 9.32 Genomic Health 212
249. 9.33 Gentris 213
250. 9.34 Genzyme 213
251. 9.35 GlaxoSmithKline 215
252. 9.36 g-Nostics Ltd. 217
253. 9.37 Hologic 217
254. 9.38 Human Genome Sciences 218
255. 9.39 Illumina 220
256. 9.40 Incyte, Inc. 221
257. 9.41 InterGenetics Inc. 222
258. 9.42 Interleukin Genetics 222
259. 9.43 Iris BioTechnologies Inc. 223
260. 9.44 Johnson & Johnson 223
261. 9.45 Lab21 224
262. 9.46 Life Technologies Corporation 225
263. 9.47 Luminex Corp. 225
264. 9.48 MediBIC Group 227
265. 9.49 Melior Discovery Inc. 227
266. 9.50 Merck & Co. 227
267. 9.51 Merck Serano 228
268. 9.52 Millennium Pharmaceuticals 229
269. 9.53 Monogram Biosciences, Inc. 229
270. 9.54 Myriad Genetics, Inc. 230
271. 9.55 Nanogen 231
272. 9.56 Nanosphere 232
273. 9.57 Nitromed 232
274. 9.58 Ocimum Biosolutions 233
275. 9.59 Orchid Cellmark 233
276. 9.60 Ore Pharmaceuticals 234
277. 9.61 PharmaSeq 234
278. 9.62 Prediction Sciences 234
279. 9.63 Predictive Biosciences 234
280. 9.64 Prometheus Laboratories 235
281. 9.65 Progeny Software, LLC 235
282. 9.66 Roche Diagnostics 236
283. 9.67 Response Genetics, Inc. 237
284. 9.68 Sequenom 238
285. 9.69 SimuGen Ltd. 239
286. 9.70 Sosei Group Corporation 239
287. 9.71 Transgenomic, Inc. 239
288. 9.72 TrimGen Corp. 239
289. 9.73 Tripos International 239
290. 9.74 Vertex Pharmaceuticals 240
291. 9.75 VIA Pharmaceuticals, Inc. 240
292. 9.76 Warnex 241
293. 9.77 Wyeth 241
294. 9.78 XDx, Inc. 242
297. INDEX OF FIGURES
299. Figure 2.1: Roche AmpliChip 20
300. Figure 2.2: FDA Approval Rates for NME Drug Applications vs. R&D Expenditures, 1998-2008 24
301. Figure 2.3: Steps Involved in Bringing a Drug to Market 26
302. Figure 2.4: CYP2C9 50
303. Figure 6.1: Total Spending on Healthcare in the U.S., 1960-2008 141
304. Figure 6.2: The Healthcare Dollar, 2008 142
307. INDEX OF TABLES
309. Table 1.1: The Success of Pharmacogenomics: Drugs that Utilize Companion Tests, 2008 16
310. Table 2.1: The Difference between Pharmacogenomics and Pharmacogenetics 18
311. Table 2.2: Clinical Applications of Diagnostic Pharmacogenomic Testing 20
312. Table 2.3: Comparison of New Molecular Entity Outcomes for FDA and EMEA (Jan 2006 - October 2008) 24
313. Table 2.4: Timeline for Development of Companion Diagnostics 27
314. Table 2.5: Valid Genomic Biomarkers in the Context of FDA-Approved Drug Labels 28
315. Table 2.6: Potential Benefits of Biomarkers as Companion Diagnostics in Drug Development 33
316. Table 2.7: Groups Participating in the International HapMap Project 36
317. Table 2.8: High-Profile Drug Withdrawals from the Marketplace 39
318. Table 2.9: Response Rates of Patients to a Major Drug for Selected Therapeutic Areas 41
319. Table 2.10 Factors That Determine a Successful Pharmacogenomic Test 43
320. Table 2.11: Pharmacogenomics' Influence on Drug Sales 43
321. Table 2.12: Pharmacogenomics' Effect on Maximizing R&D Productivity 44
322. Table 2.13: Prevalence of Metabolically-Active Enzymes 44
323. Table 2.14: Pharmacogenomics in Phase II and Phase III Trials 44
324. Table 2.15: Drug Testing 45
325. Table 2.16: Factors Affecting Variability in Individual Response to Drug Therapy 45
326. Table 2.17: CYP2D6 Characteristics 47
327. Table 2.18: CYP2D6 Metabolism of Drug Types 48
328. Table 2.19: CYP2C19 49
329. Table 2.20: CYP2C19 Metabolism of Drug Types 49
330. Table 2.21: CYP2C9 Characteristics 50
331. Table 2.22: CYP2C9 Metabolism of Drug Types 51
332. Table 2.23: CYP3A4/5/7 Metabolism of Drug Types 53
333. Table 2.24: CYP1A2 Metabolism of Drug Types 54
334. Table 2.25: CYP2B6 Metabolism of Drug Types 55
335. Table 2.26: Drivers of Pharmacogenomic Testing 56
336. Table 2.27: Markets for Pharmacogenomic Testing 57
337. Table 3.1: Worldwide Pharmacogenomic Market Size by Technology Segments, 2004-2012 61
338. Table 3.2: Total Pharmacogenomic Testing Market Size, 2001-2012 61
339. Table 3.3: Diagnostic Pharmacogenomic Testing Market Size, 2001-2012 63
340. Table 3.4: Benefits of Pharmacogenomic Diagnostics in Patient Care 64
341. Table 3.5: Genotyping Pharmacogenomic Testing Market Size, 2001-2012 64
342. Table 3.6: Benefits of Pharmacogenomics in Clinical Trials and Drug Development 64
343. Table 3.7: Five Key Action Points for Pharmaceutical Companies 65
344. Table 3.8: Global SNP Identification Tools Market Size, 2004-2012 65
345. Table 3.9: Pharmacogenomic Testing Market Structure 66
346. Table 3.10: P450 Isozymes and Pharmaceuticals 66
347. Table 3.11: List of Companies that Market Pharmacogenomic Tests 69
348. Table 3.12: Key Collaborations in the Pharmacogenomics Industry 70
349. Table 3.13: Prominent Drugs Withdrawn from the Market 70
350. Table 3.14: Key Elements in the Drug Development Process 70
351. Table 3.15: Major Suppliers of PCR-based Assays and PCR-based Technologies 70
352. Table 4.1: Methods for Performing NAT 74
353. Table 4.2: SNP Databases 80
354. Table 4.3: Myriad Genetics Predictive Medicine Sales, 2001-2008 89
355. Table 4.4: DNA-based Predictive Medicine Product Sales for Cancer, 2006-2010 89
356. Table 4.5: Developmental Atherosclerosis Drugs 94
357. Table 4.6: Summary of Assays for HIV Viral Load Testing 95
358. Table 4.7: U.S. Market Share of HIV Testing Kits 95
359. Table 4.8: Global HIV Statistics, 2007 96
360. Table 4.9: List of Approved HIV/AIDS Rapid Test Kits, 2009 97
361. Table 4.10: Monogram Bioscience, Inc. Products for HIV Testing 102
362. Table 4.11: CCR-5 Receptor Agonists in Development, 2009 103
363. Table 4.12: Asthma Therapeutic Drug Pipeline 105
364. Table 4.13: Psychiatric Case Studies, Organized Pharmacokinetically 108
365. Table 4.14: Antidepressant Drugs Decreased Clearance with DME CYP2D6 111
366. Table 4.15: Antidepressant Drugs with No Effect Clearance with DME CYP2D6 112
367. Table 5.1: Examples of Gene-Drug Pharmacogenomic Relationships 120
368. Table 5.2: Estimated Cost and Time for Typing of the BRCA1 Gene by Direct Sequencing vs. SNP Array 123
369. Table 5.3: Average Cost of Resistance Testing, 2007 138
370. Table 6.1: U.S. Prescription Drug Expenditures, 2003-2015 140
371. Table 6.2: U.S. Pharmaceutical Market, 1996-2009 142
372. Table 6.3: Top Ten Global Pharmaceutical Companies by Global Sales, 2007 143
373. Table 6.4: Pharmaceutical Companies Ranked by Total R&D Expenditures, 2007 143
374. Table 6.5: Leading Therapy Classes for R&D, 2008 143
375. Table 6.6: Leading Therapy Classes by Global Pharmaceutical Sales (Audited Market), 2007 144
376. Table 6.7: Number of NME Approvals and Mean Approval Times, 1984-2008 144
377. Table 6.8: Global Market for Tools and Consumables Used in Drug Discovery and Development, 1999-2010 145
378. Table 6.9: Leading Therapeutic Classes by U.S. Sales, 2006 and 2007 145
379. Table 6.10: Top Ten Therapeutic Classes by U.S. Dispensed Prescriptions, 2006 and 2007 145
380. Table 6.11: Top Ten Brand Drugs by U.S. Retail, 2007 146
381. Table 7.1: Select Companies Developing Cancer Diagnostics Available as Analyte Specific Reagents (ASRS) 174
382. Table 7.2: Emerging Fields in Biological Science with the Potential to Impact Personalized Medicine 184