Is Pharmacogenetic Testing a Vital Tool for Enhancing Therapeutic Management of Patients Worldwide?

IF 6.3 2区 医学 Q1 PHARMACOLOGY & PHARMACY
Kathleen M. Giacomini, Piet H. van der Graaf
{"title":"Is Pharmacogenetic Testing a Vital Tool for Enhancing Therapeutic Management of Patients Worldwide?","authors":"Kathleen M. Giacomini,&nbsp;Piet H. van der Graaf","doi":"10.1002/cpt.3404","DOIUrl":null,"url":null,"abstract":"<p>Clinical pharmacology is a discipline that includes education, research, and the implementation of knowledge into clinical practice, which ranges from precision dosing to therapeutic drug monitoring, and most recently, to the implementation of pharmacogenetic/pharmacogenomic (PGx) testing services to precisely administer drugs based on an individual's genetic make-up. In fact, PGx has become one of the core scientific pillars of the American Society for Clinical Pharmacology and Therapeutics (<i>ASCPT</i>) and its flagship journal, Clinical Pharmacology &amp; Therapeutics (<i>CPT</i>). PGx implementation services have been rapidly adopted in academic healthcare centers throughout the United States and in Europe. These services are grounded in the availability of new genetic technologies and a wealth of scientific discoveries, generally describing the influence of genetic variants on drug responses in European ancestral populations. With the availability of PGx information, the Clinical Pharmacogenetics Implementation Consortium (<i>CPIC</i>) was established to develop guidelines on drug and dose selection for individuals based on their genetic information.<span><sup>1</sup></span> These guidelines, published in <i>CPT</i>,<span><sup>2, 3</sup></span> are increasingly being incorporated into clinical decision support systems, and used to advise providers on how to use PGx information in drug or dose selection.<span><sup>1</sup></span> However, despite of their widespread adoption in academic medical centers, there remains a resistance to PGx testing among healthcare providers. This can be attributed to various factors, such as cost of testing, requirements for expensive infrastructure, lack of provider education, and skepticism that there is any major benefit of testing.<span><sup>4</sup></span>\n </p><p>With the goal of stimulating discussion among clinical pharmacologists and others, the editors of <i>CPT</i> sponsored a session at the 2024 annual meeting of <i>ASCPT</i>, entitled: “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?” (Colorado Springs CO, March 28, 2024). The session, which was moderated by <i>CPT</i> Editor-in-Chief, Piet van der Graaf, and Deputy Editor, Kathleen Giacomini, included four clinical pharmacologists or geneticists who brought different types of expertise to the panel discussion: Karen E. Brown, PharmD (University of Montana), David J. Greenblatt, MD (Tufts University School of Medicine), Henk-Jan Guchelaar, PharmD PhD (Leiden University Medical Center), and Neal Hanchard, MD PhD (National Institute of Health). To spark audience engagement, the moderators designed a survey (<b>Supplementary Materials</b> \n <b>S1</b>\n )—distributed to the membership of the ASCPT a month before the annual meeting—with the aim to gain insight into the attitudes of clinical pharmacologists towards PGx testing.</p><p>The results of the survey, with 42 respondents, were both interesting and surprising (<b>Supplementary Materials</b> \n <b>S1</b>\n ). Approximately half of the respondents felt that PGx testing was “useful but of little value,” and likewise the majority felt that prospective clinical trials were needed, though not obligate, before a genetic test was implemented in patient care (<b>Figure</b> \n1\n). Virtually, all respondents thought that more discovery research in PGx testing was needed, and a majority felt that PGx testing (excluding somatic cell mutations) benefited therapeutic management in oncology more than in other fields such as cardiology and neurology.</p><p>The issues of lack of diversity in clinical trials and in PGx testing were discussed by the panelists, who responded to this question. Dr. Hanchard pointed out that many genetic variants that are common in Europeans are extremely rare in other populations. Importantly, he described the tremendous variation in the allele frequencies of various genetic variants within the continent of Africa. Indeed, in their manuscript published in 2023 in <i>CPT</i>,<span><sup>6</sup></span> Dr. Hanchard and colleagues described the enormous variation in glucose-6-phosphate dehydrogenase (<i>G6PD</i>) across Africa. <i>G6PD</i>-deficiency is common in countries including African countries that experience malaria and when certain drugs are administered (for example primaquine), patients with <i>G6PD</i>-deficiency experience acute hemolytic anemia along with other symptoms such as fatigue and jaundice. Though <i>G6PD</i>-deficiency has been thought to be an X-linked recessive condition, occurring primarily in males, it can occur in both males and females: in hemizygous males, in homozygous females and in heterozygous females due to X-linked mosaicism. The <i>G6PD</i> A-haplotype (which includes the rs1050828 T allele, together with the rs1050829 C) is associated with <i>G6PD</i> deficiency in Africa. Interestingly within Africa, the frequency of rs1050828 T in the Tsonga (16%) is significantly higher than that in the Xhosa (0.8%) although both groups are found in South Africa. Dr. Hanchard and his team notes that <i>G6PD</i> testing is critical in Africa before these drugs are administered. <i>CYP2B6</i> alleles conferring reduced enzymatic function are also common in Africa and show wide variation in continental Africa. He and his group note that <i>CYP2B6</i> is a critical determinant of the pharmacokinetics of the HIV medication, efavirenz, again highlighting the need for pharmacogenetic testing in Africa.</p><p>All panelists agreed that more studies are clearly needed in non-European populations to identify common deleterious or gain-of-function alleles in drug metabolizing enzymes and transporters. A surprising finding of the survey was that the majority of survey responders felt that PGx testing affects global health equity in a positive way. The moderators interpreted this response as global health equity would be affected in a positive way if pharmacogenetic testing would be available in all parts of the world including low- and middle-income countries. Dr Brown highlighted the fact that even in developed countries such as the United States and Canada, there is a need to engage all communities, including indigenous peoples. She and her team have been involved in PGx studies of indigenous communities. She highlighted the importance of long-term partnerships between American Indian and Alaska Native peoples and researchers as being critical for the delivery of healthcare to people who have been historically under-represented in PGx research.<span><sup>7</sup></span>\n </p><p>Audience participation was high in the PGx session, with participants reminding panelists of the important need for studies of drug–drug interactions in the context of genetic variants, and the fact that therapeutic and adverse drug reactions are multi-factorial, influenced by a patient's underlying disease, concomitant medications and genetics. Overall, though there were diverse opinions expressed in response to the title and major question raised by the session titled “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?,” there was clear support for implementation of PGx tests in drug therapy. However, the need to address physician overload is critical, which may occur through other healthcare workers such as pharmacists. Further, the general agreement between the panelists, survey participants and audience members was that research was greatly needed including more discovery research, prospective clinical trials and studies addressing the cost–benefit ratios of PGx testing.</p><p>A series of articles in the current issue of <i>CPT</i> (<b>Figure</b> \n1\n) builds on the main conclusions and points of discussion from the <i>ASCPT</i> 2024 session described above. As pharmacogenomic testing services are increasingly adopted in healthcare systems, sharing best practices for implementation is critical to reduce disparities in health care. The Tutorial by Shugg and coworkers<span><sup>8</sup></span> from the Indiana University Precision Health Initiative details a multi-faceted PGx implementation program which can provide guidance for other clinical organizations and healthcare providers. Pharmacogenomic implementation services require interpretation of actionable pharmacogenomics variations through guidelines, such as those co-authored by CPIC, or expert consulting services. In this issue, the value and clinical impact of published PGx guidelines are debated by Donnelly <i>et al</i>.<span><sup>1</sup></span> and Ingelman-Sundberg<span><sup>4</sup></span> using two new CPIC guidelines<span><sup>2, 3</sup></span> as case studies.</p><p>As noted in the survey that preceded the ASCPT session entitled “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?,” discovery research in pharmacogenomics is needed to expand knowledge of the effects of genetic variation on clinical drug response. Two new “<i>GeneFocus</i>” reviews from the Pharmacogene Variation Consortium (PharmVar) provide comprehensive overviews of genetic variations in two important drug metabolizing enzymes, <i>CYP2A6</i>\n <span><sup>9</sup></span> and <i>CYP4F2</i>,<span><sup>10</sup></span> which should facilitate further work into their clinical impact. Pharmacogenomic testing has relied heavily on data generated from clinical studies in populations of European ancestry, often in populations of patients being treated with particular medications, such as patients with dyslipidemias on statins. However, special populations and under-represented groups remain understudied in pharmacogenomics research. In this issue of <i>CPT</i>, several manuscripts describe precision dosing in specific and under-represented patient groups. For example, two studies are focused on pharmacogenomics in African populations.<span><sup>11, 12</sup></span> One of the two studies involves both genetic polymorphisms and pregnant and postpartum patients, showing that both pregnancy status and <i>CYP2B6</i> polymorphisms affect exposure to efavirenez.<span><sup>12</sup></span> Finally two manuscripts describe precision dosing in pediatric populations.<span><sup>13, 14</sup></span> A limitation of genotyping is of course that in isolation it does not take into account the impact of external factors, such as co-medication. Such factors can result in so-called “phenoconversion,” that is, a discrepancy between predicted and observed phenotypes, as demonstrated in the study by Abouir <i>et al</i>.<span><sup>15</sup></span> for CYP2C19 subtrates. Therefore, increasingly, physiologically-based pharmacokinetic (PBPK) modeling is being used to quantify the clinical impact of PGx variability between patient groups.<span><sup>14</sup></span> In addition, other <i>in silico</i> tools are being developed to predict the consequences of variants in pharmacogenes. For example, AlSaeed <i>et al</i>.<span><sup>16</sup></span> present a case study that suggests that molecular dynamic simulations are better than conventional sequence- and structure-based tools for understanding the influences of non-synonymous single nucleotide polymorphisms (nsSNPs) on drug-protein interactions.</p><p>New discoveries have continued to expand our knowledge of the effects of genetic variants on drug response, enabling the transition of pharmacogenomics from a discovery-based science to a translational science in clinical pharmacology where genetic testing informs drug and dose selection in individual patients. There is little doubt that PGx will continue to develop as a vital tool for enhancing therapeutic management, however the jury is still out on the critical question of whether all patients worldwide will benefit from the scientific and clinical advancements. A recent analysis showed that only ~ 50% of the PGx studies published in this journal investigated study populations with diverse ethnic backgrounds.<span><sup>17</sup></span> We encourage authors to submit research in pharmacogenomics and precision dosing in underrepresented populations to better understand variability in drug response which can be the basis for developing more effective and safer therapies and treatment regimens for all patients.</p><p>No funding was received for this work.</p><p>The authors declared no competing interests for this work.</p>","PeriodicalId":153,"journal":{"name":"Clinical Pharmacology & Therapeutics","volume":"116 4","pages":"885-889"},"PeriodicalIF":6.3000,"publicationDate":"2024-09-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/cpt.3404","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Clinical Pharmacology & Therapeutics","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/cpt.3404","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"PHARMACOLOGY & PHARMACY","Score":null,"Total":0}
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Abstract

Clinical pharmacology is a discipline that includes education, research, and the implementation of knowledge into clinical practice, which ranges from precision dosing to therapeutic drug monitoring, and most recently, to the implementation of pharmacogenetic/pharmacogenomic (PGx) testing services to precisely administer drugs based on an individual's genetic make-up. In fact, PGx has become one of the core scientific pillars of the American Society for Clinical Pharmacology and Therapeutics (ASCPT) and its flagship journal, Clinical Pharmacology & Therapeutics (CPT). PGx implementation services have been rapidly adopted in academic healthcare centers throughout the United States and in Europe. These services are grounded in the availability of new genetic technologies and a wealth of scientific discoveries, generally describing the influence of genetic variants on drug responses in European ancestral populations. With the availability of PGx information, the Clinical Pharmacogenetics Implementation Consortium (CPIC) was established to develop guidelines on drug and dose selection for individuals based on their genetic information.1 These guidelines, published in CPT,2, 3 are increasingly being incorporated into clinical decision support systems, and used to advise providers on how to use PGx information in drug or dose selection.1 However, despite of their widespread adoption in academic medical centers, there remains a resistance to PGx testing among healthcare providers. This can be attributed to various factors, such as cost of testing, requirements for expensive infrastructure, lack of provider education, and skepticism that there is any major benefit of testing.4

With the goal of stimulating discussion among clinical pharmacologists and others, the editors of CPT sponsored a session at the 2024 annual meeting of ASCPT, entitled: “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?” (Colorado Springs CO, March 28, 2024). The session, which was moderated by CPT Editor-in-Chief, Piet van der Graaf, and Deputy Editor, Kathleen Giacomini, included four clinical pharmacologists or geneticists who brought different types of expertise to the panel discussion: Karen E. Brown, PharmD (University of Montana), David J. Greenblatt, MD (Tufts University School of Medicine), Henk-Jan Guchelaar, PharmD PhD (Leiden University Medical Center), and Neal Hanchard, MD PhD (National Institute of Health). To spark audience engagement, the moderators designed a survey (Supplementary Materials S1 )—distributed to the membership of the ASCPT a month before the annual meeting—with the aim to gain insight into the attitudes of clinical pharmacologists towards PGx testing.

The results of the survey, with 42 respondents, were both interesting and surprising (Supplementary Materials S1 ). Approximately half of the respondents felt that PGx testing was “useful but of little value,” and likewise the majority felt that prospective clinical trials were needed, though not obligate, before a genetic test was implemented in patient care (Figure 1 ). Virtually, all respondents thought that more discovery research in PGx testing was needed, and a majority felt that PGx testing (excluding somatic cell mutations) benefited therapeutic management in oncology more than in other fields such as cardiology and neurology.

The issues of lack of diversity in clinical trials and in PGx testing were discussed by the panelists, who responded to this question. Dr. Hanchard pointed out that many genetic variants that are common in Europeans are extremely rare in other populations. Importantly, he described the tremendous variation in the allele frequencies of various genetic variants within the continent of Africa. Indeed, in their manuscript published in 2023 in CPT,6 Dr. Hanchard and colleagues described the enormous variation in glucose-6-phosphate dehydrogenase (G6PD) across Africa. G6PD-deficiency is common in countries including African countries that experience malaria and when certain drugs are administered (for example primaquine), patients with G6PD-deficiency experience acute hemolytic anemia along with other symptoms such as fatigue and jaundice. Though G6PD-deficiency has been thought to be an X-linked recessive condition, occurring primarily in males, it can occur in both males and females: in hemizygous males, in homozygous females and in heterozygous females due to X-linked mosaicism. The G6PD A-haplotype (which includes the rs1050828 T allele, together with the rs1050829 C) is associated with G6PD deficiency in Africa. Interestingly within Africa, the frequency of rs1050828 T in the Tsonga (16%) is significantly higher than that in the Xhosa (0.8%) although both groups are found in South Africa. Dr. Hanchard and his team notes that G6PD testing is critical in Africa before these drugs are administered. CYP2B6 alleles conferring reduced enzymatic function are also common in Africa and show wide variation in continental Africa. He and his group note that CYP2B6 is a critical determinant of the pharmacokinetics of the HIV medication, efavirenz, again highlighting the need for pharmacogenetic testing in Africa.

All panelists agreed that more studies are clearly needed in non-European populations to identify common deleterious or gain-of-function alleles in drug metabolizing enzymes and transporters. A surprising finding of the survey was that the majority of survey responders felt that PGx testing affects global health equity in a positive way. The moderators interpreted this response as global health equity would be affected in a positive way if pharmacogenetic testing would be available in all parts of the world including low- and middle-income countries. Dr Brown highlighted the fact that even in developed countries such as the United States and Canada, there is a need to engage all communities, including indigenous peoples. She and her team have been involved in PGx studies of indigenous communities. She highlighted the importance of long-term partnerships between American Indian and Alaska Native peoples and researchers as being critical for the delivery of healthcare to people who have been historically under-represented in PGx research.7

Audience participation was high in the PGx session, with participants reminding panelists of the important need for studies of drug–drug interactions in the context of genetic variants, and the fact that therapeutic and adverse drug reactions are multi-factorial, influenced by a patient's underlying disease, concomitant medications and genetics. Overall, though there were diverse opinions expressed in response to the title and major question raised by the session titled “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?,” there was clear support for implementation of PGx tests in drug therapy. However, the need to address physician overload is critical, which may occur through other healthcare workers such as pharmacists. Further, the general agreement between the panelists, survey participants and audience members was that research was greatly needed including more discovery research, prospective clinical trials and studies addressing the cost–benefit ratios of PGx testing.

A series of articles in the current issue of CPT (Figure 1 ) builds on the main conclusions and points of discussion from the ASCPT 2024 session described above. As pharmacogenomic testing services are increasingly adopted in healthcare systems, sharing best practices for implementation is critical to reduce disparities in health care. The Tutorial by Shugg and coworkers8 from the Indiana University Precision Health Initiative details a multi-faceted PGx implementation program which can provide guidance for other clinical organizations and healthcare providers. Pharmacogenomic implementation services require interpretation of actionable pharmacogenomics variations through guidelines, such as those co-authored by CPIC, or expert consulting services. In this issue, the value and clinical impact of published PGx guidelines are debated by Donnelly et al.1 and Ingelman-Sundberg4 using two new CPIC guidelines2, 3 as case studies.

As noted in the survey that preceded the ASCPT session entitled “Is pharmacogenetic testing a vital tool for enhancing therapeutic management of patients worldwide?,” discovery research in pharmacogenomics is needed to expand knowledge of the effects of genetic variation on clinical drug response. Two new “GeneFocus” reviews from the Pharmacogene Variation Consortium (PharmVar) provide comprehensive overviews of genetic variations in two important drug metabolizing enzymes, CYP2A6 9 and CYP4F2,10 which should facilitate further work into their clinical impact. Pharmacogenomic testing has relied heavily on data generated from clinical studies in populations of European ancestry, often in populations of patients being treated with particular medications, such as patients with dyslipidemias on statins. However, special populations and under-represented groups remain understudied in pharmacogenomics research. In this issue of CPT, several manuscripts describe precision dosing in specific and under-represented patient groups. For example, two studies are focused on pharmacogenomics in African populations.11, 12 One of the two studies involves both genetic polymorphisms and pregnant and postpartum patients, showing that both pregnancy status and CYP2B6 polymorphisms affect exposure to efavirenez.12 Finally two manuscripts describe precision dosing in pediatric populations.13, 14 A limitation of genotyping is of course that in isolation it does not take into account the impact of external factors, such as co-medication. Such factors can result in so-called “phenoconversion,” that is, a discrepancy between predicted and observed phenotypes, as demonstrated in the study by Abouir et al.15 for CYP2C19 subtrates. Therefore, increasingly, physiologically-based pharmacokinetic (PBPK) modeling is being used to quantify the clinical impact of PGx variability between patient groups.14 In addition, other in silico tools are being developed to predict the consequences of variants in pharmacogenes. For example, AlSaeed et al.16 present a case study that suggests that molecular dynamic simulations are better than conventional sequence- and structure-based tools for understanding the influences of non-synonymous single nucleotide polymorphisms (nsSNPs) on drug-protein interactions.

New discoveries have continued to expand our knowledge of the effects of genetic variants on drug response, enabling the transition of pharmacogenomics from a discovery-based science to a translational science in clinical pharmacology where genetic testing informs drug and dose selection in individual patients. There is little doubt that PGx will continue to develop as a vital tool for enhancing therapeutic management, however the jury is still out on the critical question of whether all patients worldwide will benefit from the scientific and clinical advancements. A recent analysis showed that only ~ 50% of the PGx studies published in this journal investigated study populations with diverse ethnic backgrounds.17 We encourage authors to submit research in pharmacogenomics and precision dosing in underrepresented populations to better understand variability in drug response which can be the basis for developing more effective and safer therapies and treatment regimens for all patients.

No funding was received for this work.

The authors declared no competing interests for this work.

Abstract Image

药物基因检测是加强全球患者治疗管理的重要工具吗?
临床药理学是一门包括教育、研究和将知识应用于临床实践的学科,其范围从精确用药到治疗药物监测,以及最近的药物基因学/药物基因组学(PGx)检测服务,以根据个人的基因构成精确用药。事实上,PGx 已成为美国临床药理学与治疗学学会(ASCPT)及其旗舰期刊《临床药理学与治疗学》(CPT)的核心科学支柱之一。PGx 实施服务已在美国和欧洲的学术医疗保健中心迅速普及。这些服务的基础是新基因技术的可用性和大量科学发现,这些发现通常描述了欧洲祖先人群中基因变异对药物反应的影响。随着 PGx 信息的出现,临床药理遗传学实施联合会(CPIC)成立了,目的是根据遗传信息为个人制定药物和剂量选择指南。1 这些指南发表在《CPT》2, 3 上,正被越来越多地纳入临床决策支持系统,并用于指导医疗服务提供者如何在药物或剂量选择中使用 PGx 信息。1 然而,尽管 PGx 检测已在学术医疗中心广泛采用,但医疗服务提供者对 PGx 检测仍有抵触情绪。这可归因于多种因素,如检测成本、对昂贵基础设施的要求、缺乏对医疗服务提供者的教育,以及对检测是否有任何重大益处持怀疑态度。4 为了激发临床药理学家及其他人士的讨论,CPT 编辑在 2024 年 ASCPT 年会上赞助了一场题为 "药物基因检测是加强全球患者治疗管理的重要工具吗?(科罗拉多斯普林斯,2024 年 3 月 28 日)。会议由 CPT 主编皮特-范德格拉夫(Piet van der Graaf)和副主编凯瑟琳-贾科米尼(Kathleen Giacomini)主持,包括四位临床药理学家或遗传学家,他们为小组讨论带来了不同类型的专业知识:Karen E. Brown,药学博士(蒙大拿大学)、David J. Greenblatt,医学博士(塔夫茨大学医学院)、Henk-Jan Guchelaar,药学博士(莱顿大学医学中心)和 Neal Hanchard,医学博士(美国国立卫生研究院)。为了激发听众的参与热情,主持人设计了一份调查问卷(补充材料 S1),在年会召开前一个月分发给 ASCPT 的会员,目的是深入了解临床药理学家对 PGx 试验的态度。大约一半的受访者认为 PGx 检测 "有用但价值不大",同样,大多数受访者认为在对患者进行基因检测之前,需要进行前瞻性临床试验,尽管这并非必须(图 1)。实际上,所有受访者都认为需要在 PGx 检测方面开展更多发现性研究,大多数人认为 PGx 检测(不包括体细胞突变)对肿瘤学的治疗管理比对心脏病学和神经病学等其他领域的治疗管理更有益。Hanchard 博士指出,欧洲人常见的许多基因变异在其他人群中极为罕见。重要的是,他描述了非洲大陆各种遗传变异等位基因频率的巨大差异。事实上,在 2023 年发表于《CPT》6 的手稿中,Hanchard 博士及其同事描述了葡萄糖-6-磷酸脱氢酶(G6PD)在非洲的巨大差异。G6PD 缺乏症在包括非洲国家在内的疟疾多发国家很常见,当服用某些药物(如伯氨喹)时,G6PD 缺乏症患者会出现急性溶血性贫血,并伴有疲劳和黄疸等其他症状。虽然 G6PD 缺乏症一直被认为是一种 X 连锁隐性遗传病,主要发生在男性身上,但它也可发生在男性和女性身上:半合子男性、同卵双生女性和由于 X 连锁嵌合而导致的杂合子女性。在非洲,G6PD A 组型(包括 rs1050828 T 等位基因和 rs1050829 C)与 G6PD 缺乏症有关。有趣的是,在非洲,尽管聪加人(16%)和科萨人(0.8%)都分布在南非,但他们的 rs1050828 T 频率明显高于科萨人。Hanchard 博士及其团队指出,在非洲,在使用这些药物之前进行 G6PD 检测至关重要。 CYP2B6等位基因导致酶功能减弱在非洲也很常见,而且在非洲大陆差异很大。他和他的研究小组指出,CYP2B6 是决定艾滋病药物依非韦伦的药代动力学的关键因素,这再次强调了在非洲进行药物基因检测的必要性。所有小组成员一致认为,显然需要在非欧洲人群中开展更多研究,以确定药物代谢酶和转运体中常见的有害等位基因或功能增益等位基因。调查的一个惊人发现是,大多数调查对象认为 PGx 检测对全球健康公平产生了积极影响。主持人将这一回答解释为,如果包括中低收入国家在内的世界各地都能进行药物基因检测,全球健康公平性将受到积极影响。布朗博士强调,即使在美国和加拿大等发达国家,也需要让包括土著居民在内的所有社区参与进来。她和她的团队参与了土著社区的 PGx 研究。她强调了美国印第安人和阿拉斯加原住民与研究人员之间长期合作的重要性,认为这对于向历来在 PGx 研究中代表性不足的人群提供医疗保健服务至关重要。7 PGx 会议的听众参与度很高,与会者提醒专家组成员注意在基因变异的背景下研究药物间相互作用的重要必要性,以及治疗和药物不良反应受患者基础疾病、伴随药物和遗传学影响的多因素事实。总之,尽管与会者对题为 "药物基因检测是否是加强全球患者治疗管理的重要工具?然而,解决医生超负荷工作的问题至关重要,这可能会通过药剂师等其他医护人员来实现。此外,小组成员、调查参与者和听众普遍认为亟需开展研究,包括更多的发现研究、前瞻性临床试验和针对 PGx 检测成本效益比的研究。随着药物基因组学检测服务越来越多地被医疗保健系统采用,分享实施的最佳实践对于减少医疗保健中的差异至关重要。印第安纳大学精准健康计划(Indiana University Precision Health Initiative)的舒格(Shugg)和同事8 的教程详细介绍了一个多方面的 PGx 实施计划,可为其他临床机构和医疗服务提供者提供指导。药物基因组学实施服务需要通过指南(如 CPIC 共同撰写的指南)或专家咨询服务对可操作的药物基因组学变异进行解释。在本期杂志中,Donnelly 等人1 和 Ingelman-Sundberg4 以两份新的 CPIC 指南2、3 为案例,对已发布的 PGx 指南的价值和临床影响进行了讨论。正如在 ASCPT 会议之前进行的题为 "药物基因检测是加强全球患者治疗管理的重要工具吗?药物基因变异联盟(PharmVar)最新发布的两篇 "GeneFocus "综述全面概述了两种重要药物代谢酶 CYP2A6 9 和 CYP4F2 10 的基因变异,这将有助于进一步研究它们对临床的影响。药物基因组学检测在很大程度上依赖于欧洲血统人群的临床研究数据,通常是针对接受特定药物治疗的人群,如服用他汀类药物的血脂异常患者。然而,特殊人群和代表性不足的群体在药物基因组学研究中仍未得到充分研究。在本期的《CPT》中,有几篇手稿介绍了在特殊和代表性不足的患者群体中进行精准用药的情况。例如,有两项研究关注非洲人群的药物基因组学。11, 12 这两项研究中的一项涉及基因多态性和妊娠及产后患者,结果显示妊娠状态和 CYP2B6 多态性都会影响依非韦伦的暴露量。
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来源期刊
CiteScore
12.70
自引率
7.50%
发文量
290
审稿时长
2 months
期刊介绍: Clinical Pharmacology & Therapeutics (CPT) is the authoritative cross-disciplinary journal in experimental and clinical medicine devoted to publishing advances in the nature, action, efficacy, and evaluation of therapeutics. CPT welcomes original Articles in the emerging areas of translational, predictive and personalized medicine; new therapeutic modalities including gene and cell therapies; pharmacogenomics, proteomics and metabolomics; bioinformation and applied systems biology complementing areas of pharmacokinetics and pharmacodynamics, human investigation and clinical trials, pharmacovigilence, pharmacoepidemiology, pharmacometrics, and population pharmacology.
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