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DOI: 10.1055/a-1655-9500
Life-time Actionable Pharmacogenetic Drug Use: A Population-based Cohort Study in 86 040 Young People With and Without Mental Disorders in Denmark
- Abstract
- Introduction
- Aims of the study
- Materials & Methods
- Results
- Discussion
- Data Availability Statement
- References
Abstract
Objective To describe life-time use of current actionable pharmacogenetic (PGx) somatic and psychotropic drugs according to international PGx consortia in people with and without hospital-diagnosed mental disorders in the Danish population.
Methods Population- and register-based observational drug utilization study in 56 065 individuals with mental disorders, i. e. attention-deficit/hyperactivity disorder, autism, bipolar disorder, depression and schizophrenia, and a random, representative sample of 29 975 individuals of the Danish population, born between 1981 and 2005. Individuals were followed from 1995 or birth until 2016 (for a maximum of 22 years). We report prevalence and incidence rates of PGx drug use by age, sex and mental disorders based on redeemed prescriptions between 1995 and 2016.
Results Of the 69 PGx drugs, prescriptions of 39 drugs had been redeemed by the study population by 35 years of age. The use of at least 1 PGx drug varied between 23.1% in males without mental disorders and 97.2% in females with schizophrenia. Males with ADHD or autism were the youngest first-time PGx drug users at a mean of 11.6 years. The mean number of different PGx drugs used was 1.2 in males without mental disorders and 5.6 in individuals with schizophrenia. The prevalence of different PGx drugs linked to more than one gene was 25.3% in males without mental disorders to 94.1% in females with schizophrenia.
Conclusion PGx drugs are commonly used by younger people, more often by individuals with mental disorders and by females. Panel-based PGx testing could contribute to treatment decisions at a very young age.
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Introduction
Pharmacogenetics (PGx) is the study of the genetic predisposition of individuals, which can result in variability in drug metabolism, pharmacodynamics, or immunogenicity linked to treatment (non-)response or adverse events [1]. PGx aims at optimising treatment outcomes (i. e. increased efficacy or reduced risk of adverse events) by personalising treatment for patients based on their genetic makeup. Actionable PGx drugs are those for which drug or dosing recommendations have been made available by international PGx consortia in evidence-based PGx guidelines [2] [3] [4]. PGx guidelines have been provided for a proportionally higher number of psychotropic drugs than other drug classes [5]. Consequently, PGx testing could be of specific benefit for individuals with mental disorders, who often experience adverse events and delayed, insufficient, or non-response to psychopharmacological treatment [6] [7]. Nevertheless, the implementation of PGx testing in psychiatry is lagging behind other specialities such as oncology [5] [8] [9]. The reasons for this have been discussed in recent review articles with a common ground of identified numerous barriers including perceived missing clinical evidence and utility, and knowledge and consensus about PGx testing among psychiatrists [5] [9].
Recently, several observational drug utilization studies of both somatic and psychotropic drugs with actionable PGx implications (PGx drugs) in different populations have contributed to a broader understanding of the potential impact of PGx testing based on the frequency of PGx drug use in larger populations [10] [11] [12] [13] [14] [15]. The findings of these studies indicate, for example, that 50% of people using prescription drugs received one or more actionable PGx drug(s) during a 4-year period, 23% of first-time drug prescriptions included actionable drug-gene interactions (DGIs) and in approximately 25% of prescriptions, dose adjustments were recommended [11] [12] [13] [14]. A preponderance of actionable psychotropic PGx drug use and the involvement of cytochrome-P450 (CYP) enzymes 2C19 and 2D6 DGIs were commonly observed [10] [11] [12] [13] [14] [15]. Although people with mental disorders have not been the focus of these studies and thus, the incidence and prevalence of PGx drug use in people with mental disorders in comparison with an unselected population have not been investigated in detail yet.
One of the reasons for the low implementation of PGx guided dosing in psychiatry is a lack of consensus and specific advice regarding when to test to obtain the optimum and timely benefits. Several options regarding the timing of PGx testing are available, e. g. i) the currently often used ˋreactive testingˊ when a patient experiences drug toxicity or non-response, ii) ˋreactive prospective testingˊ by executing a PGx test at the time of prescribing to know the PGx status of the patient prior to the start of treatment, and iii) ˋpre-emptive testingˊ by executing a panel-based PGx test at a certain time in a personˊs life, to know his or her PGx status prior to all future PGx drug prescriptions [11]. A panel-based PGx test including multiple variants in different genes has advantages over single-gene testing in that PGx guided dosing can be applied to PGx drugs with more than one established associated gene (i. e. actionable DGI), or when multiple PGx drugs are used subsequently with different DGIs or concomitantly resulting in drug-drug-gene interactions (DDGI). In addition, panel-based testing offers combinatorial PGx, in which multiple variants of different genes can be interpreted simultaneously to provide a more accurate personal PGx based dosing advice [16] [17]. While panel-based testing has been advocated more recently [5] [9] [13] [18], guidance on whether to test pre-emptively or at which age first PGx drug use can be expected is still missing, which could be supported by observational studies investigating the exposure of actionable PGx drugs since birth.
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Aims of the study
To describe prescription drug use of current actionable somatic and psychotropic PGx drugs according to international PGx consortia in people with and without hospital diagnosed mental disorders in the Danish population. The specific aims were to investigate (1) the (life-time) incidence and prevalence of PGx drug use, (2) age at first PGx drug prescription, (3) the mean number of different PGx drugs per individual considering panel-based PGx testing (versus single-gene) and (4) the frequency of PGx drug use related to different genes regarding combinatorial PGx interpretation.
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Materials & Methods
Study design
This was a population- and register-based cohort study of individuals born between 1981 and 2005 investigating prescription drug use of PGx drugs in Denmark between 1995 and 2016. The study used data of the Integrative Psychiatric Research (iPSYCH) consortium, which has established a large, unique Danish psychiatry-focused population-based case-cohort study sample (iPSYCH2012), hereafter referred to as iPSYCH sample [19].
Details on the iPSYCH sample have been described previously [19]. In brief, the iPSYCH sample is nested within the entire Danish population of singleton births born to known mothers between 1981 and 2005 (study base: 1 472 762 individuals), who were alive and resided in Denmark on their first birthday [19]. The iPSYCH sample contains five cohorts of a combined total of 57 377 individuals with at least one diagnosis of one of five selected mental disorders, further referred to as case cohorts, i. e. affective/mood disorder(depression), attention-deficit/hyperactivity disorder (ADHD), autism, bipolar affective disorder (BD) and schizophrenia (SZ), and a representative, randomly selected cohort of the general population of 30 000 individuals corresponding to 2.04% of the study base. The members of the population-based cohort are representative of the entire Danish population born between 1981 and 2006, and are at risk of developing the disorder of interest during follow-up.
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Data sources
The iPSYCH sample is linked via the anonymized personal identification number, since birth or immigration, to drug prescription data and clinical and socio-demographic information from several Danish national registers, including i) the Danish Civil Registration System (CPR) including information since 1968 on e. g. birth registration, vital status and citizenship [20]; ii) the Danish National Prescription Registry including information on all prescription drugs dispensed at pharmacies since 1994, including e. g. the anatomical therapeutic chemical (ATC) classification code, date and quantity of dispensed drugs [21]; iii) the Danish National Patient Registry including inpatient care information in Denmark since 1977 and outpatient care information since 1995 [22]; iv) the Danish Psychiatric Central Research Register including e. g. diagnosis at and dates of admission and discharge of patients treated at psychiatric departments in Denmark since 1969 [23]; and v) the Danish Register of Causes of Death including cause-specific mortality statistics, with computerized individual records since 1970 [24].
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Study population and study period
An overview of the study design and the included individuals with mental disorders and the population sample is shown in [Fig. 1], panel a. The study period was from January 1st, 1995 until December 31st, 2016. As prescription drug information from birth was not available for individuals born between 1981 and 1994, and to assess life-time exposure to prescription drugs, we created two birth cohorts including birth cohort81 born in 1981–1994 and birth cohort95 born in 1995–2005 (with life-time prescription drug exposure). The follow-up time of the individuals started in 1995 (or at birth after 1995), and ended at the date of emigration, death, or December 31st, 2016, whatever came first ([Fig. 1], panel b). Individuals of the population cohort developing mental disorders during follow-up were censored from the population sample at the date of diagnosis. If these individuals had received a diagnosis of one of the included mental disorders before December 31, 2012, they were, by study design, included in the case cohorts. These individuals contributed observation time and drug use in both cohorts prior to their diagnoses but accounted only for a small proportion of the population cohort due to low incidence rates [37]. Thus, in this study, the population-based cohort represents the part of the Danish population without the selected psychiatric disorders diagnosed at psychiatric hospitals.
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Pharmacogenetic drugs of interest
The international Clinical Pharmacogenetics Implementation Consortium (CPIC) and the Dutch Pharmacogenetics Working Group (DPWG) execute literature reviews on PGx and provide peer-reviewed, evidence-based, updatable and detailed PGx guidelines [2] [3] [4]. National Danish PGx guidelines do not exist. CPIC and DPWG recommendations partially overlap with labelling recommendations of drugs, such as pimozide and warfarin regarding PGx testing, but PGx testing, in general, is not routinely/widely integrated in Danish clinical practice. We combined information from both CPIC and DPWG PGx guidelines and identified 69 drugs for which actionable PGx recommendations were provided until February 2020 (i. e. actionable PGx drugs, Supplement Table 1) [25] [26]. The list includes drugs from the following drug classes: anaesthetics, antibiotics, analgesics, anti-cancer drugs, anticoagulants, cardiovascular drugs, proton-pump inhibitors (PPIs) and psychotropic drugs. Of the 69 PGx drugs, 20 drugs (29%) have more than one actionable DGI, and thus have more than one actionable PGx guideline. Seven drugs have DGIs related to both CYP2C19 and CYP2D6, three drugs to TPMT and NUDT15, seven drugs to RYR1 and CACNA1S, one drug to HLA-A and HLA-B, one drug to CYP2C9 and HLA-B and one drug to VKORC1, CYP2C9 and CYP4F2 (Supplement Table 1). We identified the use of actionable PGx using their ATC classification codes from the Danish National Prescription Registry (Supplement Table 1). The retrieved data thus describes drug prescriptions redeemed by the patients at community pharmacies, but the terms ‘drug use’ and ‘drug users’ are applied as well in this study.
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Data accessibility
The iPSYCH study was approved by the Danish Scientific Ethics Committee (EC: 1-10-72-287-12), the Danish National Board of Health (Sundhedsdatastyrelsen, SDS, FSEID 1999) and the Danish Data Protection Agency (Journal number 2015-57-0002, 62908, umbrella permission Aarhus University). All data is stored at Statistics Denmark and was available in an anonymous form, by remote online access, with special permission in compliance with the Danish Data Privacy Act.
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Statistical analyses
We have presented measures of drug use e. g. incidence rates and prevalence, means, standard deviations, separately for two birth cohorts, males and females, and mental disorders case cohorts and the population cohort. We divided the number of users with at least one prescription of a respective PGx drug by the number of total underlying person-years (PY) during follow-up (incidence rates) and by the number of total underlying individuals at the beginning of follow-up (prevalence). The mean age of first-time PGx drug use and the mean number of prescribed different PGx drugs were tested with a t-test to examine whether the mean differences between males and females were statistically significant. A p-value <0.05 was considered statistically significant. We used SAS %Lexis macro to calculate incidence rates [27]. Individuals with mental disorders might have received a first actionable psychotropic PGx drug prescription prior to their diagnosis of mental disorders, hence, we have reported descriptive statistics for those individuals who used PGx drugs prior to their first psychiatric hospital diagnosis within each cohort. The number of different DGIs per individual was calculated as the sum of all unique DGIs during follow-up. Concomitant drug use was considered if two or more different drugs had at least one day of overlap of their drug prescriptions. To assess if panel-based testing is more favourable than single-gene testing, we identified the number of prescribed PGx drugs which have more than one actionable DGI, and the total number of users for those drugs.
Due to a restriction from Statistics Denmark and the General Data Protection Regulations, data can only be reported if the number of individuals contributing to aggregated measures exceeds four, which can result in the grouping of data. For sub-analyses to avoid too few counts in individual categories, we grouped mental disorders into mental disorders (A) including predominantly childhood onset disorders and (B) including predominantly adult-onset disorders. All data were processed and analysed using SAS statistical software version 9.4 (SAS Institute Inc, Cary, NC USA) and proportions were compared using MedCalc for Windows, version 19.4 (MedCalc Software, Ostend, Belgium).
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Results
[Table 1] shows the characteristics for both the randomly selected population cohort (N=29 975) and the combined mental disorders case cohorts (N=56 065) born between 1981–2005 in Denmark, further divided into the two birth cohorts. Males and females were equally distributed in all cohorts, except in the mental disorders case birth cohort95, which included more males due to a higher prevalence of the young-onset of ADHD and autism in males. Individuals can have a diagnosis of more than one mental disorder and can therefore contribute to several mental disorder case cohorts. During the total follow up of 1 664 266 PY (average of 19.3 years), 115 individuals (0.13%) died and 3260 individuals (3.8%) emigrated (0.19 and 6.1% in the population cohort, and 0.10 and 2.6% in the mental disorders cohorts, respectively).
|
Birth cohort81 (1981–1994) † Total=53,331 |
Birth cohort95 (1995–2005) † Total=32 709 |
|||||||
|---|---|---|---|---|---|---|---|---|
|
Population (N=15 894) |
MD case cohorts (N=37 437) |
Population (N=14 081) |
MD case cohorts (N=18 628) |
|||||
|
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
|
|
Age in groups (y) |
||||||||
|
<18 |
- |
- |
- |
- |
8876 |
(63.0) |
9705 |
(52.1) |
|
18-23 |
2636 |
(16.6) |
5605 |
(15.0) |
5205 |
(37.0) |
8923 |
(47.9) |
|
24-29 |
7349 |
(46.2) |
17 494 |
(46.7) |
- |
- |
- |
- |
|
30-35 |
5909 |
(37.2) |
14 338 |
(38.3) |
- |
- |
- |
- |
|
Sex |
||||||||
|
Female |
7817 |
(49.2) |
19 619 |
(52.4) |
6866 |
(48.8) |
4971 |
(26.7) |
|
Male |
8077 |
(50.8) |
17 818 |
(47.6) |
7215 |
(51.2) |
13 657 |
(73.3) |
|
Ethnicity ‡ |
||||||||
|
Africa |
65 |
(0.4)* |
73 |
(0.2) |
218 |
(1.5)* |
192 |
(1.0) |
|
Asia |
176 |
(1.1)* |
146 |
(0.4) |
206 |
(1.5)* |
143 |
(0.8) |
|
Australia/Greenland/N.&S.America/Unknown |
16 |
(0.1)* |
16 |
(0.0) |
14 |
(0.1) |
14 |
(0.1) |
|
Denmark |
13 861 |
(87.2)* |
33 001 |
(88.2) |
11 294 |
(80.2)* |
15 638 |
(83.9) |
|
Europe |
308 |
(1.9)* |
403 |
(1.1) |
360 |
(2.6)* |
271 |
(1.5) |
|
Middle East |
145 |
(0.9)* |
161 |
(0.4) |
339 |
(2.4)* |
256 |
(1.4) |
|
Mixed |
1298 |
(8.2)* |
3601 |
(9.6) |
1609 |
(11.4) |
2088 |
(11.2) |
|
Scandinavia |
25 |
(0.2)* |
36 |
(0.1) |
41 |
(0.3)* |
26 |
(0.1) |
|
Region in Denmark |
||||||||
|
Capital Region |
4629 |
(29.1) |
10 925 |
(29.2) |
4609 |
(32.7) |
7011 |
(37.6) |
|
Middle Jutland |
3580 |
(22.5) |
8764 |
(23.4) |
2991 |
(21.2) |
3407 |
(18.3) |
|
North Jutland |
2178 |
(13.7) |
4626 |
(12.4) |
1863 |
(13.2) |
2647 |
(14.2) |
|
Southern Denmark |
1804 |
(11.4) |
3180 |
(8.5) |
1453 |
(10.3) |
1257 |
(6.7) |
|
Zealand |
3703 |
(23.3) |
9942 |
(26.6) |
3165 |
(22.5) |
4306 |
(23.1) |
|
Diagnosis with MD § |
||||||||
|
ADHD |
271 |
(1.7) |
9402 |
(25.1) |
292 |
(2.1) |
10 303 |
(55.3) |
|
Affective disorders |
558 |
(3.5) |
23 840 |
(63.7) |
72 |
(0.5) |
2228 |
(12.0) |
|
Bipolar disorder |
50 |
(0.3) |
2014 |
(5.4) |
<5 |
(0.0) |
87 |
(0.5) |
|
Depression |
516 |
(3.2) |
22 025 |
(58.8) |
67 |
(0.5) |
2085 |
(11.2) |
|
Autism |
134 |
(0.8) |
6548 |
(17.5) |
223 |
(1.6) |
9564 |
(51.3) |
|
Schizophrenia |
140 |
(0.9) |
4271 |
(11.4) |
8 |
(0.1) |
214 |
(1.1) |
† Birth cohort81 includes individuals born in 1981-1994 and birth cohort95 includes individuals born in 1995-2005; ‡ Ethnicity defined based on parental place of birth as described by Pedersen et al.[18] Europe means countries other than Denmark/Scandinavia and Scandinavia means only Norway, Sweden, Finland, and Iceland. If one parent was born outside of Denmark, that region was used. If both parents were born outside of Denmark, but in different regions, mixed was used. § Summing the percentages of individual disorders might add up to more than 100%, as individuals can carry multiple diagnoses; *Significant difference at a p-value= <0.05. Presented are the characteristics of individuals in the population cohort and combined MD case cohort assessed in 2016. The data is presented in two separate birth cohorts. Data with a number below 5 is presented as ‘<5’ for privacy safety reasons. Abbreviations: ADHD: attention-deficit/hyperactivity disorder, MD: mental disorders.
Incidence rates of pharmacogenetic drug use
Of the 69 drugs with actionable PGx recommendations, we identified 45 PGx drugs for which prescriptions were redeemed at community pharmacies, 10 of which were used by less than five users each, but were included in further analyses of cumulative or combined use ([Table 2]). In the population cohort, the highest incidence rates of PGx drug use per 10 000 PY were recorded for oestrogens (429 in females), the analgesics codeine (27 in males and 55 in females) and tramadol (34 in males and 45 in females), followed by PPIs (lansoprazole, omeprazole and pantoprazole) and the antidepressant citalopram ([Table 2]). In the mental disorders case cohorts, the incidence rates of any of the PGx drugs use per 10 000 PY were higher compared with the population cohort, in particular, psychotropic drugs matching their main indications, e. g. atomoxetine (160 in males and 188 in females) in ADHD, citalopram (248 in males and 306 in females) in depression, aripiprazole (229 in males and 316 in females) in SZ, and lamotrigine (211 in males and 330 in females) in BD. Individuals in the mental disorders case cohorts were prescribed at least one psychotropic PGx drug before their first mental disorders diagnosis with proportions of 50.4% (ADHD), 38.2% (autism), 86.9% (SZ), 86.1% (BD), and 83.3% (depression).
|
Drug name |
Population (N=29 975) N/10 000 PY |
ADHD (N=19 705) N/10 000 PY |
Autism (N=16 112) N/10 000 PY |
Bipolar disorder (N=2101) N/10 000 PY |
Depression (N=24 110) N/10 000 PY |
Schizophrenia (N=4485) N/10 000 PY |
PGx DGI |
|||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Females |
Males |
Females |
Males |
Females |
Males |
Females |
Males |
Females |
Males |
Females |
Males |
|||
|
Allopurinol |
- |
- |
- |
- |
- |
- |
1 |
1 |
1 |
1 |
2 |
1 |
HLA-B a,b |
|
|
Amitriptyline |
P |
6 |
2 |
11 |
5 |
6 |
3 |
21 |
10 |
24 |
16 |
23 |
9 |
CYP2D6 a,b, CYP2C19 a |
|
Aripiprazole |
P |
1 |
1 |
47 |
31 |
56 |
38 |
143 |
116 |
51 |
54 |
316 |
229 |
CYP2D6 b |
|
Atomoxetine |
P |
2 |
4 |
188 |
160 |
49 |
51 |
32 |
57 |
23 |
40 |
27 |
38 |
CYP2D6 a,b |
|
Atorvastatin |
1 |
- |
1 |
1 |
1 |
1 |
2 |
3 |
2 |
3 |
5 |
7 |
SLCO1B1 b |
|
|
Azathioprine |
2 |
2 |
3 |
2 |
2 |
2 |
4 |
3 |
4 |
4 |
4 |
3 |
TPMT a,b, NUDT15a,b |
|
|
Carbamazepine |
P |
1 |
1 |
5 |
7 |
10 |
6 |
9 |
18 |
3 |
6 |
8 |
10 |
HLA-A a,b, HLA-B a,b |
|
Citalopram |
P |
31 |
14 |
135 |
51 |
84 |
42 |
314 |
214 |
306 |
248 |
274 |
185 |
CYP2C19 a,b |
|
Clomipramine |
P |
- |
- |
2 |
1 |
3 |
1 |
12 |
4 |
7 |
6 |
9 |
5 |
CYP2D6 a,b, CYP2C19 a,b |
|
Clopidogrel |
- |
- |
- |
- |
- |
- |
1 |
2 |
1 |
- |
2 |
- |
CYP2C19 a,b |
|
|
Codeine |
55 |
27 |
89 |
38 |
48 |
24 |
125 |
76 |
128 |
67 |
128 |
62 |
CYP2D6 a,b |
|
|
Doxepin |
P |
- |
- |
- |
- |
- |
- |
- |
1 |
- |
1 |
- |
- |
CYP2D6 a,b, CYP2C19 a |
|
Escitalopram |
P |
9 |
4 |
46 |
18 |
33 |
15 |
145 |
105 |
113 |
101 |
124 |
87 |
CYP2C19 a,b |
|
Oestrogens |
429 |
- |
484 |
- |
292 |
- |
735 |
- |
716 |
- |
600 |
- |
F5/FvL b |
|
|
Flucloxacillin |
10 |
10 |
22 |
16 |
17 |
14 |
14 |
20 |
20 |
15 |
28 |
17 |
HLA-B b HLA-B b |
|
|
Fluvoxamine |
P |
- |
- |
6 |
- |
- |
- |
1 |
1 |
1 |
- |
1 |
- |
CYP2D6 a |
|
Haloperidol |
P |
- |
- |
2 |
2 |
4 |
1 |
7 |
12 |
2 |
2 |
20 |
12 |
CYP2D6 b |
|
Imipramine |
P |
1 |
1 |
2 |
1 |
2 |
1 |
3 |
4 |
3 |
4 |
8 |
6 |
CYP2C19 a,b, CYP2D6 a,b |
|
Lamotrigine |
P |
6 |
4 |
65 |
25 |
51 |
23 |
330 |
211 |
81 |
49 |
116 |
41 |
HLA-B b |
|
Lansoprazole |
35 |
20 |
84 |
36 |
39 |
21 |
107 |
60 |
99 |
64 |
129 |
74 |
CYP2C19 b |
|
|
Metoprolol |
7 |
2 |
9 |
5 |
9 |
3 |
15 |
10 |
17 |
9 |
22 |
11 |
CYP2D6 b |
|
|
Nortriptyline |
P |
2 |
1 |
8 |
3 |
5 |
2 |
33 |
23 |
25 |
22 |
20 |
13 |
CYP2D6 a,b, CYP2C19 a |
|
Omeprazole |
38 |
20 |
70 |
31 |
50 |
23 |
86 |
41 |
86 |
53 |
107 |
55 |
CYP2C19 b |
|
|
Ondansetron |
4 |
1 |
7 |
1 |
3 |
2 |
13 |
2 |
10 |
2 |
10 |
2 |
CYP2D6 a |
|
|
Oxcarbazepine |
P |
2 |
2 |
5 |
6 |
11 |
8 |
6 |
6 |
3 |
4 |
8 |
5 |
HLA-B a,b |
|
Pantoprazole |
35 |
21 |
82 |
39 |
45 |
24 |
108 |
69 |
98 |
68 |
137 |
85 |
CYP2C19 b |
|
|
Paroxetine |
P |
3 |
2 |
16 |
6 |
11 |
6 |
26 |
19 |
27 |
23 |
32 |
24 |
CYP2D6 a,b |
|
Pimozide |
P |
- |
1 |
3 |
6 |
2 |
4 |
1 |
4 |
2 |
4 |
6 |
8 |
CYP2D6 b |
|
Risperidone |
P |
2 |
3 |
60 |
63 |
73 |
69 |
111 |
110 |
53 |
70 |
237 |
226 |
CYP2D6 b |
|
Sertraline |
P |
22 |
12 |
132 |
56 |
133 |
64 |
217 |
148 |
226 |
179 |
235 |
142 |
CYP2C19 a,b |
|
Simvastatin |
1 |
1 |
4 |
3 |
4 |
2 |
12 |
10 |
7 |
9 |
22 |
23 |
SLCO1B1 a,b |
|
|
Tramadol |
45 |
34 |
106 |
57 |
41 |
22 |
148 |
107 |
147 |
104 |
163 |
86 |
CYP2D6 b |
|
|
Venlafaxine |
P |
10 |
4 |
66 |
24 |
36 |
15 |
158 |
104 |
152 |
128 |
146 |
88 |
CYP2D6 b |
|
Warfarin |
2 |
1 |
2 |
1 |
1 |
1 |
4 |
3 |
3 |
2 |
8 |
2 |
VKORC1 a,b, CYP2C9 a,b, CYP4F2 |
|
|
Zuclopenthixol |
P |
- |
- |
6 |
5 |
7 |
3 |
21 |
19 |
8 |
8 |
59 |
46 |
CYP2D6 b |
Incidence rates of PGx drug prescriptions in the population cohort and for the five individual MD case cohorts are shown as number of users per 10,000 PY of the total observed follow-up time. Ten drugs though identified in the study population, but not included in this table are flecainide, fluorouracil, mercaptopurine, phenprocoumon, phenytoin, propafenone, tacrolimus, tamoxifen, trimipramine and voriconazole because these drugs were used by less than 10 individuals in the total population or MD case cohorts. a Actionable PGx guideline from CPIC. b Actionable PGx guideline from DPWG. Abbreviations: ADHD: attention-deficit/hyperactivity disorder, ATC: Anatomical Therapeutic Chemical, CPIC: Clinical Pharmacogenetics Implementation Consortium, DPWG: Dutch Pharmacogenetics Working Group, DGI: drug-gene interaction, MD: mental disorders, PY: person-years, P: psychotropic drug, PGx: pharmacogenetics.
#
Prevalence of pharmacogenetic drug use
In the population birth cohort81, besides oestrogens used by 80.7% of females, tramadol (11.7%), codeine (11.3%) and lansoprazole (7.7%) were the most frequently prescribed PGx drugs. In the younger population birth cohort95, the most used PGx drugs besides oestrogens were omeprazole (3.1%), codeine (2.7%) and pantoprazole (2.4%) (Supplement Table 2). In general, the prevalence of drug users was higher in both the mental disorders case birth cohorts compared with the population cohorts. In the mental disorders case birth cohort81, the most prevalent prescribed PGx drugs besides oestrogens were citalopram (39.3%), sertraline (30.7%) and tramadol (23.5%). In the mental disorders case birth cohort95, the most prevalent prescribed PGx drugs were atomoxetine (17%), oestrogens (12.8%) and sertraline (10%) (Supplement Table 3).
#
Age of first-time pharmacogenetic drug use
Age of first-time PGx drug use (life-time use) differed between sex in all cohorts born since 1995 ([Table 3], upper part). The mean age of starting a PGx drug for the first-time ranged from 11.6–15.0 years for males and 13.1–15.2 years for females. The youngest individuals starting a first-time PGx drug on average were 11.6 years old males with ADHD or autism, compared with nearly 13 years of age in females with ADHD or autism.
|
Age at first-time PGx drug use |
||||||||
|---|---|---|---|---|---|---|---|---|
|
Cohort |
Birth cohort81 (1981–1994) † |
Birth cohort95 (1995–2005) † |
||||||
|
Females (N=25 726) |
Males (N=16 005) |
Females (N=6299) |
Males (N=5949) |
|||||
|
Mean |
±SD |
Mean |
±SD |
Mean |
±SD |
Mean |
±SD |
|
|
Population |
17.8 |
3.5 |
21.6 |
5.7 |
15.2 |
3.3 |
12.9 |
5.1 |
|
ADHD |
16.1 |
3.0 |
19.0 |
4.9 |
13.2 |
3.6 |
11.6 |
4.1 |
|
Autism |
16.2 |
4.0 |
17.4 |
5.4 |
13.1 |
4.3 |
11.6 |
4.4 |
|
Bipolar disorder¥ |
17.0 |
2.8 |
20.0 |
4.2 |
15.0 |
1.8 |
14.1 |
3.9 |
|
Depression |
16.8 |
2.8 |
19.9 |
4.2 |
14.7 |
2.6 |
13.8 |
3.5 |
|
Schizophrenia¥ |
16.9 |
2.9 |
19.8 |
4.1 |
14.3 |
2.9 |
15.0 |
2.8 |
|
Mean number of different PGx drugs prescribed |
||||||||
|
Cohort |
Birth cohort81 (1981–1994) † |
Birth cohort95 (1995–2005) † |
||||||
|
Females (N=25 726) |
Males (N=16 005) |
Females (N=6299) |
Males (N=5949) |
|||||
|
Mean |
±SD |
Mean |
±SD |
Mean |
±SD |
Mean |
±SD |
|
|
Population |
2.0 |
1.4 |
1.6 |
1.1 |
1.4 |
0.8 |
1.2 |
0.6 |
|
ADHD |
4.4 |
2.5 |
2.8 |
2.0 |
2.1 |
1.3 |
1.6 |
1.0 |
|
Autism |
3.5 |
2.3 |
2.4 |
1.6 |
2.0 |
1.2 |
1.7 |
1.0 |
|
Bipolar disorder |
5.3 |
2.6 |
3.6 |
2.2 |
3.4 |
1.8 |
2.3 |
1.3 |
|
Depression |
4.4 |
2.4 |
3.1 |
2.0 |
2.6 |
1.5 |
2.0 |
1.2 |
|
Schizophrenia |
5.6 |
2.9 |
3.6 |
2.2 |
3.5 |
1.6 |
2.2 |
1.1 |
† Birth cohort81 includes individuals born between 1981 and 1994, birth cohort95 includes individuals born between 1995 and 2005. ¥ The differences between males and females in all cohorts are statistically significant, except for the birth cohort95 with bipolar disorder or schizophrenia. Mean age of drug users at their first-time PGx drug prescription and the mean of the number of PGx drugs prescribed in the population and for five individual MD diagnoses are presented. The table is split based on birth cohorts, as we do not have life-time drug use available for individuals in birth cohort81. Individuals who were not prescribed any PGx drug prior to death or data capping are not included in this table. Abbreviations: MD: mental disorders; ADHD: attention-deficit/hyperactivity disorder; iPSYCH: Integrative Psychiatric Research (iPSYCH) consortium, SD: standard deviation.
#
Multiple (different) pharmacogenetic drugs per user
Individuals used on average more than one PGx drug over a maximum follow-up time of 22 years ([Table 3], lower part) with sex and birth cohort differences in both the population and mental disorders case cohorts. Overall, higher means of different PGx drugs were seen in the mental disorders case cohorts compared with the population cohorts, with maximum means of more than four different PGx drugs in females of the mental disorders birth cohort81.
The prevalence of individuals using different PGx drugs (0 – > 9) is mentioned in [Table 4]. Within the population cohort, 23.1% of males and 65.4% of females used one or more PGx drugs during the follow-up time. Among individuals of the mental disorders case birth cohorts combined, 56.2% of males and 84.9% of females with ADHD, 43.8% and 72.3% with autism, 87% and 96% with BD, 86.5% and 96.9% with depression, and 87.3% and 97.2% with SZ, respectively, used one or more PGx drugs during the follow-up time. The highest prevalence of individuals using more than three different PGx drugs exceeded 80% in females with BD or SZ. The highest prevalence of individuals using six or more PGx drugs was approximately 40% in females with BD or SZ.
|
No. of different PGx drugs |
Population |
ADHD |
Autism |
Bipolar disorder |
Depression |
Schizophrenia |
||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
|||||||||||||
|
(N=14 683) |
(N=15 292) |
(N=5289) |
(N=14 416) |
(N=3525) |
(N=12 587) |
(N=1292) |
(N=809) |
(N=16 476) |
(N=7634) |
(N=2083) |
(N=2402) |
|||||||||||||
|
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
|
|
0 |
5081 |
(34.6) |
11 766 |
(76.9) |
799 |
(15.1) |
6317 |
(43.8) |
976 |
(27.7) |
7079 |
(56.2) |
52 |
(4.0) |
105 |
(13.0) |
518 |
(3.1) |
1028 |
(13.5) |
58 |
(2.8) |
305 |
(12.7) |
|
1 |
5409 |
(36.8) |
2374 |
(15.5) |
1029 |
(19.5) |
3662 |
(25.4) |
854 |
(24.2) |
2641 |
(21.0) |
76 |
(5.9) |
125 |
(15.5) |
1430 |
(8.7) |
1600 |
(21.0) |
87 |
(4.2) |
377 |
(15.7) |
|
2 |
2263 |
(15.4) |
732 |
(4.8) |
822 |
(15.5) |
1878 |
(13.0) |
588 |
(16.7) |
1383 |
(11.0) |
125 |
(9.7) |
154 |
(19.0) |
2534 |
(15.4) |
1565 |
(20.5) |
201 |
(9.6) |
398 |
(16.6) |
|
3 |
1002 |
(6.8) |
239 |
(1.6) |
712 |
(13.5) |
1097 |
(7.6) |
397 |
(11.3) |
732 |
(5.8) |
144 |
(11.1) |
122 |
(15.1) |
2949 |
(17.9) |
1222 |
(16.0) |
262 |
(12.6) |
426 |
(17.7) |
|
4 |
489 |
(3.3) |
114 |
(0.7) |
590 |
(11.2) |
593 |
(4.1) |
289 |
(8.2) |
366 |
(2.9) |
210 |
(16.3) |
99 |
(12.2) |
2684 |
(16.3) |
887 |
(11.6) |
289 |
(13.9) |
320 |
(13.3) |
|
5 |
228 |
(1.6) |
37 |
(0.2) |
448 |
(8.5) |
358 |
(2.5) |
182 |
(5.2) |
192 |
(1.5) |
189 |
(14.6) |
85 |
(10.5) |
2116 |
(12.8) |
558 |
(7.3) |
293 |
(14.1) |
204 |
(8.5) |
|
6 |
125 |
(0.9) |
19 |
(0.1) |
355 |
(6.7) |
241 |
(1.7) |
102 |
(2.9) |
107 |
(0.9) |
141 |
(10.9) |
49 |
(6.1) |
1600 |
(9.7) |
341 |
(4.5) |
247 |
(11.9) |
152 |
(6.3) |
|
7 |
45 |
(0.3) |
11 † |
(0.0) |
177 |
(3.3) |
118 |
(0.8) |
54 |
(1.5) |
43 |
(0.3) |
116 |
(9.0) |
35 |
(4.3) |
1028 |
(6.2) |
203 |
(2.7) |
186 |
(8.9) |
92 |
(3.8) |
|
8 |
17 |
(0.1) |
158 |
(3.0) |
76 |
(0.5) |
34 |
(1.0) |
26 |
(0.2) |
93 |
(7.2) |
13 |
(1.6) |
722 |
(4.4) |
123 |
(1.6) |
150 |
(7.2) |
62 |
(2.6) |
||
|
9 |
16 |
(0.1) |
77 |
(1.5) |
42 |
(0.3) |
20 |
(0.6) |
12 |
(0.1) |
65 |
(5.0) |
9 |
(1.1) |
387 |
(2.3) |
65 |
(0.9) |
110 |
(5.3) |
37 |
(1.5) |
||
|
>9 |
8 |
(0.1) |
122 |
(2.3) |
34 |
(0.2) |
29 |
(0.8) |
6 |
(0.0) |
81 |
(6.3) |
13 |
(1.6) |
508 |
(3.1) |
42 |
(0.6) |
200 |
(9.6) |
29 |
(1.2) |
||
† This number is grouped with data from >7 different PGx drugs, due to data otherwise being <5. The number of individuals who were prescribed different numbers of PGx drugs in the population cohort and for five individual MD case cohorts over a mean follow-up time of 19-21 years is shown. Mean (±SD) follow-up times were 19 years in the male population (±4.1), male patients with ADHD (±3.7) and patients with autism (±3.8), 20 years in the female population (±4) and female patients with ADHD (±3.5) and 21 years in patients with BD (F ±3.6, M ±3.4), depression (F ±3.1, M ±3) and SZ (F ±3, M ±3.1). Abbreviations: MD: mental disorders; ADHD: attention-deficit/hyperactivity disorder; iPSYCH: Integrative Psychiatric Research, PGx: pharmacogenetics, SD: standard deviation, F: females, M: males.
#
Pharmacogenetic drug use relevant to panel-based testing and combinatorial PGx
Of the 39 PGx drugs, nine drugs (23%) with more than one actionable DGI, including genes coding for CYP2D6, CYP2C19, HLA-A, HLA-B, CYP2C9, CYP4F2 or VKORC1 were used by 3.9% of the PGx drug users of the population and 9.7% of the PGx drug users of the combined mental disorders case cohorts.
The prevalence of individuals using different PGx drugs of different DGIs at any time during the follow-up was 43% in females and 25.3% in males in the population cohort ([Table 5]). In individuals with mental disorders, these numbers ranged between 39.6% in males with autism and 94.1% in females with SZ. The involved DGIs are listed in the legend of [Table 5].
|
No. of different types of genes |
Population |
ADHD |
Autism |
Bipolar disorder |
Depression |
Schizophrenia |
||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
Female |
Male |
|||||||||||||
|
(N=9602) |
(N=3526) |
(N=4490) |
(N=8099) |
(N=2549) |
(N=5508) |
(N=1240) |
(N=704) |
(N=15 958) |
(N=6606) |
(N=2025) |
(N=2097) |
|||||||||||||
|
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
N |
(%) |
|
|
1 |
5473 |
(57.0) |
2635 |
(74.7) |
1113 |
(24.8) |
4720 |
(58.3) |
960 |
(37.7) |
3328 |
(60.4) |
83 |
(6.7) |
182 |
(25.9) |
1695 |
(10.6) |
2382 |
(36.1) |
120 |
(5.9) |
600 |
(28.6) |
|
2 |
2703 |
(28.2) |
765 |
(21.7) |
1237 |
(27.6) |
2682 |
(33.1) |
821 |
(32.2) |
1768 |
(32.1) |
207 |
(16.7) |
269 |
(38. 2) |
4575 |
(28.7) |
3258 |
(49.3) |
458 |
(22.6) |
1127 |
(53.7) |
|
3 |
1237 |
(12.9) |
98 |
(2.8) |
1538 |
(34.3) |
536 |
(6.6) |
544 |
(21.3) |
334 |
(6.1) |
404 |
(32.6) |
217 |
(30.8) |
6991 |
(43.8) |
793 |
(12.0) |
942 |
(46.5) |
291 |
(13.9) |
|
4 |
142 |
(1.5) |
21 |
(0.6) |
532 |
(12.1) |
145 |
(1.8) |
185 |
(7.3) |
78 † |
(1.4) |
493 |
(39.8) |
28 |
(4.0) |
2345 |
(14.7) |
144 |
(2.2) |
399 |
(19.7) |
68 |
(3.2) |
|
5 |
47 † |
(0.5) |
7 |
(0.2) |
58 |
(1.3) |
16 † |
(0.2) |
39 † |
(1.5) |
- |
- |
39 |
(3.2) |
8 † |
(1.1) |
291 |
(1.8) |
29 † |
(0.4) |
84 |
(4.2) |
11 |
(0.5) |
|
≥6 |
- |
- |
- |
- |
12 † |
(0.3) |
- |
- |
- |
- |
- |
- |
14 † |
(1.1) |
- |
- |
61 † |
(0.4) |
- |
- |
22 † |
(1.1) |
- |
- |
† This number is grouped with data from the immediate cell below, due to data otherwise being <5. The numbers of individuals are shown for different numbers of genes involved in the prescribed PGx drugs in the population and for five individual MD diagnoses over a mean follow-up time of 20-22 years. Mean (±SD) follow-up times were 20 years in the population (F ±3, M ±3.1), patients with ADHD (F ±2.7, M ±3) and autism (F ±2.7, M ±3), 21 years in patients with BD (F ±2.5, M ±2) and female patients with depression (±2.2), and 22 years in male patients with depression (±1.7) and patients with SZ (F ±2, M ±1.7). Percentages are calculated only among PGx drugs users. Genes linked to drug use per cohort: Population (CYP2C19, CYP2D6, CYP4F2, F5/FvL, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1, CYP3A5); ADHD (CYP2C19, CYP2D6, CYP4F2, F5/FvL, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1); Autism (CYP2C19, CYP2D6, CYP4F2, F5/FvL, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1, CYP3A5*, DPYD* (* only in males); BD (CYP2C19, CYP2D6, CYP4F2, F5/FvL*, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1 (* only in females); MDD (CYP2C19, CYP2D6, CYP4F2, F5/FvL, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1); SZ (CYP2C19, CYP2D6, CYP4F2, F5/FvL, HLA-A, HLA-B, NUDT15, SLCO1B1, TPMT, VKORC1). Abbreviations: MD: mental disorders; ADHD: attention-deficit/hyperactivity disorder; iPSYCH: Integrative Psychiatric Research, PGx: pharmacogenetics, SD: standard deviation; F: females; M: males.
Concerning combinatorial PGx, the prevalence of individuals who used concomitantly different PGx drugs affected by different DGIs ranged between 24.4% of the individuals without mental disorders, 41.3% of individuals with autism or ADHD to 69.2% of individuals with BD, SZ or depression ([Table 6]). In over 80% of these users, the PGx drugs were linked to two different DGIs, in 8.1% to three, and in 1.1% of these users, to four DGIs.
|
Cohorts† |
Number of individuals with concomitant drugs N (%)‡,§ |
One gene N (%)¶ |
Two genes N (%)¶ |
Three genes N (%)¶ |
Four genes N (%)¶,ͳ |
||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Total |
Female |
Male |
Total |
Female |
Male |
Total |
Female |
Male |
Total |
Female |
Male |
Total |
Female |
Male |
|
|
Population (N=13 128) (F=9602/M=3526) |
3199 (24.4) |
2727 (28.4) |
472 (13.4) |
728 (22.8) |
501 (18.4) |
227 (48.1) |
2887 (90.2) |
2589 (95.0) |
298 (63.1) |
198 (6.2) |
162 (5.9) |
36 (7.6) |
36 (1.1) |
29 (1.1) |
7 (1.5) |
|
MD-A ψ (N=18 531) (F=6570/M=11 961) |
7653 (41.3) |
3818 (58.1) |
3835 (32.1) |
3800 (49.7) |
1588 (41.6) |
2212 (57.7) |
6419 (83.9) |
3587 (93.9) |
2832 (73.8) |
441 (5.8) |
250 (6.5) |
191 (5.0) |
48 (0.6) |
22 (0.6) |
26 (0.7) |
|
MD-B χ (N=25 355) (F=17 255/M=8100) |
17 546 (69.2) |
13 349 (77.4) |
4197 (51.8) |
8499 (48.4) |
6083 (45.6) |
2416 (57.6) |
16 137 (92.0) |
12 769 (95.7) |
3368 (80.2) |
1418 (8.1) |
1205 (9.0) |
213 (5.1) |
148 (0.8) |
116 (0.9) |
32 (0.8) |
† Only those individuals who had a history of using PGx drugs were included; ‡ The percentages are estimated out of the total number of individuals in each cohort; § Concomitant drug use implies at least two different drugs overlapping for at least one day; ¶ The percentages are estimated out of the number of individuals using concomitant PGx drugs; ͳ Only a few individuals used concomitant drugs metabolized by five genes (all less than five observations); ψ MD-A includes ADHD and autism; χ MD-B includes schizophrenia, bipolar disorder and depression. The number of individuals using PGx drugs concomitantly is shown, followed by the number of involved genes related to the PGx drugs. The mean (±SD) days of overlap were 676 (±2,300); 2,584 (7,510) and 3,045 (7,732) for the population cohort, MD-A MD-B case cohorts, respectively. Abbreviations: MD: mental disorders; ADHD: attention-deficit/hyperactivity disorder; SD: standard deviation; F: female; M: male.
#
#
Discussion
This is the first population-based PGx drug utilization study in 86 040 young people with and without mental disorders in Denmark describing (life-time) incident use of 39 of the 69 actionable PGx drugs according to international guidelines. We found that, by the age of 35 years, at least one actionable PGx had been used by up to 97% of individuals with mental disorders, i. e. with SZ, and by 65% of females and 23% of males of the population cohort (without mental disorders). In individuals with mental disorders, the most frequent actionable PGx drugs corresponded to their psychiatric indications, i. e. atomoxetine in ADHD, citalopram in depression, aripiprazole in SZ, and lamotrigine in BD, related to DGIs involving CYP2D6, CYP2C19, and HLA-B. Moreover, the high use of oestrogens in oral contraceptives related to Factor V Leiden (FvL), the weak opioid analgesics codeine and tramadol, the PPIs lansoprazole, omeprazole, and pantoprazole, and citalopram in both the mental disorders and population cohorts also related to the CYP2D6, CYP2C19, and HLA-B indicate the broad applicability of PGx testing in the general population. The first-time users of PGx drugs were as young as (mean age of) 11 years in males with ADHD. Panel-based testing including at least the most commonly identified DGIs could be applicable for 95% of females with SZ down to approximately 25% of males in the general population. Combinatorial PGx testing, considering several different drugs and different DGIs at the same time, could be relevant for up to 70% of individuals with mental disorders and 24% of the general population without mental disorders.
Life-time incidence and prevalence of pharmacogenetic drug use
Recently several studies in different settings have investigated the incidence and prevalence of actionable PGx drug use, but they neither addressed life-time use or age at first PGx drug prescription nor were they conducted in unselected case cohorts with mental disorders or population-based, thus comparisons are hampered [7] [11] [12] [13] [14] [15] [28] [29] [30]. Still, the pattern of prevalence of PGx drug use in our study, e. g., the most frequent use of oestrogens, followed by codeine, tramadol, PPIs and citalopram, is similar to the patterns reported by a previous study in Denmark based on publically available prescription sales data of the general population by age 44 years in 2017 [14]. In comparison with studies in other populations, our observations are in line with findings from the US, UK and the Netherlands applying similar actionable PGx drug criteria. In the US, Samwald et al. found in individuals below 40 years that weak opioids, PPIs, SSRIs, atomoxetine and selected antipsychotics were among the top 8 of incident PGx drugs [11]. In UK, Youssef et al. investigated sales data of overall prescriptions dispensed in 2018, where patients by age 39 years most commonly dispensed prescriptions for antidepressants, oral contraceptives, anti-infectives, and PPIs [10]. Of note, we found generally frequent use of oestrogens, i. e. oral contraceptives related to FvL, which is similar to frequencies of prescriptions reported from the UK and the Netherlands [10] [13]. Although oestrogen-containing oral contraceptives are included in the uPGx panel of PGx drugs, which we applied in this study, it should be noted that oral contraceptives containing oestrogens are currently only considered actionable in females with a previous personal or family history of thrombosis or additional risk factors for thrombosis such as smoking, diabetes, and obesity according to DWPG [4]. This may lead to the impression that the number of women where PGx actions should be considered is inflated in our study, with 8647 female users of oestrogens in the population cohort, and 18908 female users with psychiatric disorders, and among those, an estimated 6.6% were heterozygous and 0.1% were homozygous carriers of FvL [31] [32]. We did not assess additional risk factors, thus the actual number of females where PGx would be applicable is unknown. However, among females with psychiatric disorders considering oestrogen-containing oral contraceptives, PGx guidance could be considered applicable to a larger extent due to common (comorbid) conditions, including diabetes, obesity and smoking [33] [34] [35]. Moreover, it has been previously studied that establishing FvL testing in all women before initiating oral contraceptives is unfeasible due to costs and a low predictive value of FvL testing [32]. Now, considering the increasing utility of PGx in general and panel-based testing decreasing costs, the cost-benefit of FvL testing should be revisited for inclusion in core panels of actionable PGx tests and multifactorial treatment decisions.
While overall patterns of actionable PGx drugs were similar across the different cohorts, the prevalence of any of the investigated actionable PGx drugs was higher among people with mental disorders than in the population without these conditions. This is mainly due to the preponderance of psychotropic drugs among actionable PGx drugs matching the psychiatric disorders, but the more frequent use of PGx drugs such as analgesics and PPIs with indications for somatic conditions also indicates a higher burden of somatic disorders in younger people with mental disorders compared with their peers.
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Age of first pharmacogenetic drug use and timing of PGx testing
We found that the mean age of the earliest PGx drug use in the cohort born between 1995–2006 was 11 years in males and 13 years in females with ADHD or autism, and of 13 years in males and 15 years in females without mental disorders, suggesting earliest reactive prospective testing around these ages. We are not aware of any other study assessing life-time incident use of PGx drugs.
Considering pre-emptive PGx testing, which is unlike reactive prospective testing unrelated to a prescription of a PGx drug in the first place, our PGx drug prevalence findings indicate that pre-emptive testing could support pharmacological treatment decisions in 23% of males and 65% of females of the general population (without mental disorders) by the age of 35 years. In individuals with mental disorders, pre-emptive PGx could be applicable in, e. g. up to 87% of males and 97% of females. We further estimate that pre-emptive testing and test results could be applied for a mean of 3.1 PGx drugs in young individuals with mental disorders and a mean of 1.6 PGx drugs in young individuals without mental disorders by age of 35 years. Several other studies have investigated the potential of pre-emptive testing, but not based on life-time use, in different patient populations across disorders, age ranges, settings and study set-ups (e. g. follow-up times) leading to a wider range of 11.2% to 97% of individuals exposed to one or more PGx drugs over a 2–20 year follow-up period, thus are not directly comparable with our findings [11] [28] [36] [37] [38].
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Panel-based and combinatorial pharmacogenetic testing
Our results indicate, as discussed earlier, the utility of panel-based testing due to the frequent use of several PGx drugs related to different DGIs. Panel-based testing in particular, of a core panel including variants of CYP2D6 and CYP2C19 has been endorsed by many PGx societies and implementation initiatives [14] [15] [30] [39]. These efforts are now being further supported by a recent meta-analysis finding that plasma levels of various antidepressant and antipsychotic drugs are associated with CYP2D6/CYP2C19 genotype-predicted metabolizer status supporting genotype-based dosing recommendations and ultimately PGx testing in people with mental disorders initiating psychotropic treatment [40].
An additional benefit of panel-based PGx testing is the opportunity to execute combinatorial PGx, which considers the effect of multiple variants in different genes for PGx-based dose adjustments. This is of importance when a single drug has multiple actionable DGIs or when multiple PGx drugs are used concomitantly. The substantial number (a third) of individuals affected by multiple DGIs and 24.4% (population) to 69.2% (BD, SZ, depression cohorts) using multiple PGx drugs concomitantly in our study indicates the potential benefit from combinatorial PGx. Multiple PGx drugs acting on the same enzyme affected by genetic variation leading to DDGIs and related PGx guided drug dosage recommendations are yet not provided in international public guidelines and rarely transparently in commercial combinatorial PGx tests but are under development [41] [42] [43]. In addition, the difference between the number of individuals using a drug and the number of individuals who require necessary action vary from<1% to 50% with divergent geno-phenotypes [14], which is largely dependent on the combination of actionable PGx guidelines for geno- or phenotypes and frequencies of these geno- and phenotypes.
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Strengths and limitations
The strengths of the current study are that it presents data of a large population-based case-cohort of individuals with mental disorders and a population cohort representative for the entire Danish population of young age. The study has no bias in the selection of individuals, very little missing data and little loss to follow-up due to the registry-based study set-up using the Danish Civil Registration System. All these strengths allow a valid estimation of first-time as well as life-time PGx drug use in Denmark, and these estimates are likely to extrapolate to countries with similar drug utilization patterns and health care systems. This study has some limitations. First, a considerable number of individuals have no drug data registered from birth until 1995 solely affecting birth cohort81. By dividing the cohort into two birth cohorts, we were able to present PGx drug use from birth up to the end of the study for the remaining individuals born since 1995 (ages 11–21). This affects the interpretation of the age of first PGx drug use and the mean number of PGx drug use. We lack data of the youngest years of individuals in birth cohort81, with a maximum of the first 11 years of an individual born in 1984. This might result in a higher mean age for birth cohorts81 due to the left-truncation. We have data until a maximum age of 11 years for individuals born in 2005, thus individuals starting a first PGx drug at age 12 or older are not included in the calculations. This might result in a lower mean age for birth cohorts95 due to right-truncation. Yet, since we know the average age of onset of disease, we expect that the real answer, e. g., ADHD and autism lies close to the mean age identified in birth cohorts95, compared to the other disorders with a real age of first PGx drug use in between the results for birth cohorts 1 and 2 [39] [40] [44] [45]. Another limitation is that hospital-based data is missing from the drug registries, excluding some actionable PGx drugs such as anti-infectives and drugs used in anaesthesia. Moreover, we present a drug utilization study of current actionable PGx drugs. The results presented in this study might be affected in the future by changing trends in drug use or updated PGx guidelines, for example including new PGx drugs. Lastly, the iPSYCH population is rather homogeneous with 88% of Danish or European ancestry, 10% mixed ancestry, and only up to 2% of Non-European ancestry, partially due to the design of the study including individuals born in Denmark since 1981. Among the commonly used PGx drugs identified in the current study, this may affect estimates for the even greater utility of PGx testing of drugs affected by CYP2C19 variations or HLA-B variants, both of which are more frequent in individuals with Asian ancestry; or CYP2C9 variations in individuals with African ancestry and should be considered in PGx adjusted dosing recommendations of relevant drugs [46] [47].
In conclusion, PGx drugs are commonly used by young individuals, with more frequent PGx drug use among young individuals with mental disorders and females. PGx testing could be beneficial already at a very young age (adolescent). Panel-based PGx testing would be preferable over single-gene testing, based on the number of individuals using PGx drugs subsequently or concomitantly and the number of different drug-gene interactions involved.
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Data Availability Statement
The data that support the findings of this study are available from Statistics Denmark. Restrictions apply to the availability of these data, which were used under license for this study. Data are available in an anonymous form, by remote online access with the permission of Statistics Denmark, the National Centre for Register-based Research (NCRR) and the Centre for Integrated Register-Based Research at Aarhus University (CIRRAU).
FundingThe study was funded by unrestricted grants received by C. Gasse of the Alfred Benzon Foundation, Denmark, and NovoNordisk Foundation, Denmark (NNF17OC0029488) and by C. Lunenburg of the Lundbeck Foundation, Denmark (R322-2019-2404). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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Conflict of Interest
The authors declare no conflict of interest.
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Correspondence
Publication History
Received: 19 April 2021
Received: 31 August 2021
Accepted: 08 September 2021
Article published online:
09 November 2021
© 2019. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/).
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References
- 1 Weinshilboum RM, Wang L. Pharmacogenomics: Precision medicine and drug response. Mayo Clin Proc 2017; 92: 1711-1722 DOI: 10.1016/j.mayocp.2017.09.001.
- 2 Swen JJ, Wilting I, de Goede AL. et al. Pharmacogenetics: From bench to byte. Clin Pharmacol Ther 2008; 83: 781-787 DOI: 10.1038/sj.clpt.6100507.
- 3 Swen JJ, Nijenhuis M, de Boer A. et al. Pharmacogenetics: From bench to byte--an update of guidelines. Clin Pharmacol Ther 2011; 89: 662-673 DOI: 10.1038/clpt.2011.34.
- 4 Relling MV, Klein TE. CPIC: Clinical Pharmacogenetics Implementation Consortium of the Pharmacogenomics Research Network. Clin Pharmacol Ther 2011; 89: 464-467 DOI: 10.1038/clpt.2010.279.
- 5 Lunenburg CATC, Gasse C. Pharmacogenetics in psychiatric care, a call for uptake of available applications. Psychiatry Res 2020; 292: 113336 DOI: 10.1016/j.psychres.2020.113336.
- 6 Stern S, Linker S, Vadodaria KC. et al. Prediction of response to drug therapy in psychiatric disorders. Open Biol 2018; 8. doi:10.1098/rsob.180031
- 7 Hahn M, Müller DJ, Roll SC. Frequencies of genetic polymorphisms of clinically relevant gene-drug pairs in a German psychiatric inpatient population. Pharmacopsychiatry 2020. doi:10.1055/a-1312-7175
- 8 Henricks LM, Lunenburg CATC, de Man FM. et al. DPYD genotype-guided dose individualisation of fluoropyrimidine therapy in patients with cancer: A prospective safety analysis. Lancet Oncol 2018; 19: 1459-1467 DOI: 10.1016/S1470-2045(18)30686-7.
- 9 Bousman CA, Bengesser SA, Aitchison KJ. et al. Review and consensus on pharmacogenomic testing in psychiatry. Pharmacopsychiatry 2021; 54: 5-17 DOI: 10.1055/a-1288-1061.
- 10 Youssef E, Kirkdale CL, Wright DJ. et al. Estimating the potential impact of implementing pre-emptive pharmacogenetic testing in primary care across the UK. Br J Clin Pharmacol 2021; 87: 2907-2925 DOI: 10.1111/bcp.14704.
- 11 Samwald M, Xu H, Blagec K. et al. Incidence of exposure of patients in the United States to multiple drugs for which pharmacogenomic guidelines are available. PLoS One 2016; 11: e0164972 DOI: 10.1371/journal.pone.0164972.
- 12 Bank PCD, Swen JJ, Guchelaar HJ. Estimated nationwide impact of implementing a preemptive pharmacogenetic panel approach to guide drug prescribing in primary care in The Netherlands. BMC Med 2019; 17: 110 DOI: 10.1186/s12916-019-1342-5.
- 13 Alshabeeb MA, Deneer VHM, Khan A. et al. Use of pharmacogenetic drugs by the Dutch population. Front Genet 2019; 10: 567 DOI: 10.3389/fgene.2019.00567.
- 14 Lunenburg C, Hauser A, Ishtiak-Ahmed K. et al. Primary care prescription drug use and related actionable drug-gene interactions in the Danish population. Clin Transl Sci 2020; 13: 798-806 DOI: 10.1111/cts.12768.
- 15 Westergaard N, Sogaard Nielsen R, Jorgensen S. et al. Drug use in Denmark for drugs having pharmacogenomics (PGx) based dosing guidelines from CPIC or DPWG for CYP2D6 and CYP2C19 drug-gene pairs: Perspectives for introducing PGx test to polypharmacy patients. J Pers Med 2020; 10. doi:10.3390/jpm10010003
- 16 Benitez J, Jablonski MR, Allen JD. et al. The clinical validity and utility of combinatorial pharmacogenomics: Enhancing patient outcomes. Appl Transl genomics 2015; 5: 47-49 DOI: 10.1016/j.atg.2015.03.001.
- 17 Brown L, Vranjkovic O, Li J. et al. The clinical utility of combinatorial pharmacogenomic testing for patients with depression: a meta-analysis. Pharmacogenomics 2020; 21: 559-569 DOI: 10.2217/pgs-2019-0157.
- 18 Bousman C, Maruf AAl, Muller DJ. Towards the integration of pharmacogenetics in psychiatry: A minimum, evidence-based genetic testing panel. Curr Opin Psychiatry 2019; 32: 7-15 DOI: 10.1097/YCO.0000000000000465.
- 19 Pedersen CB, Bybjerg-Grauholm J, Pedersen MG. et al. The iPSYCH2012 case-cohort sample: New directions for unravelling genetic and environmental architectures of severe mental disorders. Mol Psychiatry 2018; 23: 6-14 DOI: 10.1038/mp.2017.196.
- 20 Pedersen CB. The Danish civil registration system. Scand J Public Health 2011; 39: 22-25 DOI: 10.1177/1403494810387965.
- 21 Kildemoes HW, Sorensen HT, Hallas J. The Danish National Prescription Registry. Scand J Public Health 2011; 39: 38-41 DOI: 10.1177/1403494810394717.
- 22 Lynge E, Sandegaard JL, Rebolj M. The Danish National Patient Register. Scand J Public Health 2011; 39: 30-33 DOI: 10.1177/1403494811401482.
- 23 Mors O, Perto GP, Mortensen PB. The Danish Psychiatric Central Research Register. Scand J Public Health 2011; 39: 54-57 DOI: 10.1177/1403494810395825.
- 24 Helweg-Larsen K. The Danish Register of Causes of Death. Scand J Public Health 2011; 39: 26-29 DOI: 10.1177/1403494811399958.
- 25 Clinical Pharmacogenetics Implementation Consortium (CPIC). CPIC Guidelines. Last Update 04-06-2020
- 26 KNMP (Royal Dutch Pharmacists Association). Pharmacogenetic Recommendations. Last Update May 2020
- 27 Carstensen B, Dickman P. Lexis macro for splitting follow-up. 2003: http://bendixcarstensen/Lexis/Lexis.sas
- 28 Kimpton JE, Carey IM, Threapleton CJD. et al. Longitudinal exposure of English primary care patients to pharmacogenomic drugs: An analysis to inform design of pre-emptive pharmacogenomic testing. Br J Clin Pharmacol 2019; 85: 2734-2746 DOI: 10.1111/bcp.14100.
- 29 Hicks JK, El Rouby N, Ong HH. et al. Opportunity for genotype-guided prescribing among adult patients in 11 U.S. health systems. Clin Pharmacol Ther 2021; 110: 179-188 DOI: 10.1002/cpt.2161.
- 30 Ramsey LB, Ong HH, Schildcrout JS. et al. Prescribing prevalence of medications with potential genotype-guided dosing in pediatric patients. JAMA Netw open 2020; 3: e2029411 DOI: 10.1001/jamanetworkopen.2020.29411.
- 31 Lunenburg CATC, Thirstrup JP, Bybjerg-Grauholm J. et al. Pharmacogenetic genotype and phenotype frequencies in a large Danish population-based case-cohort sample. Transl Psychiatry 2021; 11: 294 DOI: 10.1038/s41398-021-01417-4.
- 32 McDaid A, Logette E, Buchillier V. et al. Risk prediction of developing venous thrombosis in combined oral contraceptive users. PLoS One 2017; 12: e0182041 DOI: 10.1371/journal.pone.0182041.
- 33 Dickerson F, Schroeder J, Katsafanas E. et al. Cigarette smoking by patients with serious mental illness, 1999-2016: An increasing disparity. Psychiatr Serv 2018; 69: 147-153 DOI: 10.1176/appi.ps.201700118.
- 34 Köhler-Forsberg O, Petersen L, Ishtiak-Ahmed K. et al. Medical diseases prior to first-time depression diagnosis and subsequent risk of admissions for depression: A nationwide study of 117,585 patients. J Affect Disord 2020; 276: 1030-1037 DOI: 10.1016/j.jad.2020.07.057.
- 35 Laursen TM, Munk-Olsen T, Gasse C. Chronic somatic comorbidity and excess mortality due to natural causes in persons with schizophrenia or bipolar affective disorder. PLoS One 2011; 6: e24597 DOI: 10.1371/journal.pone.0024597.
- 36 Schildcrout JS, Denny JC, Bowton E. et al. Optimizing drug outcomes through pharmacogenetics: a case for preemptive genotyping. Clin Pharmacol Ther 2012; 92: 235-242 DOI: 10.1038/clpt.2012.66.
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