The Precision HYpertenSIon Care (PHYSIC) study: a double-blind, randomized, repeated cross-over study


ARTICLE

The Precision HYpertenSIon Care (PHYSIC) study: a double-blind, randomized,
repeated cross-over study

Johan Sundstr€oma,b, Lars Linda, Shamim Nowrouzia, Per Lytsya , Kerstin Marttalaa, Inger Ekmanb,
Patrik €Ohagenb and Ollie €Ostlundb

aDepartment of Medical Sciences, Uppsala University, Uppsala, Sweden; bUppsala Clinical Research Center (UCR), Uppsala, Sweden

ABSTRACT
High blood pressure is the leading risk factor for premature deaths and a major cost to societies
worldwide. Effective blood pressure-lowering drugs are available, but patient adherence to them is
low, likely partly due to side effects. To identify patient-specific differences in treatment effects, a
repeated cross-over design, where the same treatment contrasts are repeated within each patient, is
needed. Such designs have been surprisingly rarely used, given the current focus on precision medi-
cine. The Precision HYpertenSIon Care (PHYSIC) study aims to investigate if there is a consistent
between-person variation in blood pressure response to the common blood pressure-lowering drug
classes of a clinically relevant magnitude, given the within-person variation in blood pressure. The
study will also investigate the between-person variation in side effects of the drugs. In a double-blind,
randomized, repeated cross-over trial, 300 patients with mild hypertension will be treated with four
blood pressure-lowering drugs (candesartan, lisinopril, amlodipine, and hydrochlorothiazide) in mono-
therapy, with two of the drugs repeated for each patient. If the study indicates that there is a potential
for precision hypertension care, the most promising predictors of blood pressure and side effect
response to the drugs will be explored, as will the potential for development of a biomarker panel to
rank the suitability of blood pressure-lowering drug classes for individual patients in terms of antici-
pated blood pressure effects and side effects, with the ultimate goal to maximize adherence. The study
follows a protocol pre-registered at ClinicalTrials.gov with the identifier NCT02774460.

ARTICLE HISTORY
Received 17 June 2018
Revised 2 July 2018
Accepted 5 July 2018

KEYWORDS
Hypertension; blood
pressure; randomised
clinical trial;
precision medicine

Background
High blood pressure is the leading risk factor for premature
deaths worldwide (1) and accounts for more than 10% of all
health care costs in some developed countries, with a mere
fifth of that attributable to medication costs, and four-fifths
to complications (2). Less than half of those who have high
blood pressure are aware of it, and, of those receiving blood
pressure-lowering drug treatment, only one-third have their
blood pressure at target levels (3).

Effective blood pressure-lowering drugs are available, with
the first-line drug classes—angiotensin-converting enzyme
(ACE)-inhibitors, angiotensin receptor blockers, calcium chan-
nel blockers, and thiazide diuretics—considered equally
effective on average. Most of their protective effects depend
on the amount of blood pressure reduction achieved, and
there are few class-specific protective effects (4). They do,
however, have class-specific side effects.

Poor adherence is likely the main cause of poor blood
pressure control, with as little as 1 in 2 patients estimated to
be adherent to prescribed treatment in developed countries
(5). Because poorly controlled blood pressure is such an
important burden on patients and health care systems,
improving adherence is imperative.

The concept of precision medicine promises maximization
of treatment benefit and minimization of treatment harm
using subtle characteristics (typically involving, but not
limited to, gene variants) of patients with the same trait to
guide treatment decisions. If the promise holds true widely,
hypertension would be an optimal field, with a handful of
first-line drug classes that all have similar average blood
pressure-lowering effects, and each has common side effects
that hamper adherence.

For hypertension, the concept needs answers to several
important questions. The most important question is if there
is a clinically relevant and repeatable between-person differ-
ence in blood pressure response or side effects to a given
drug (6). If there is not, then there is no potential for preci-
sion medicine. Analysing variance components in parallel
group trials (which cannot disentangle all of the relevant
variance components) (7), a clinically irrelevant between-per-
son difference in blood pressure response has been sug-
gested to be the scenario for ACE-inhibitors (8), but this is
unconfirmed and unknown for other drug classes. It is also
unknown if between-person differences in blood pressure
response are different for different drugs (9,10), and magni-
tudes of within- and between-person variations in side

CONTACT Johan Sundstr€om Uppsala University, Department of Medical Sciences, Uppsala, Sweden. E-mail: johan.sundstrom@medsci.uu.se
� 2018 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use,
distribution, and reproduction in any medium, provided the original work is properly cited.

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effects are particularly unknown. Resolving these issues is
imperative for the possibilities of precision blood pressure-
lowering treatment, and the present study, the Precision
HYpertenSIon Care (PHYSIC) study, aims to answer those
questions. Proper methods for that purpose have been pro-
posed (7,11) and are used in this study.

If this study indicates that there is a potential for person-
alized blood pressure-lowering treatment, we will explore
the most promising predictors of blood pressure and side
effect response to the drugs, using peripheral blood analyses
in combination with clinical data. If feasible, we will then
explore the potential for development of a biomarker panel
to rank the suitability of each of the blood pressure-lowering
drug classes for the individual patient in terms of both antici-
pated blood pressure effect and side effects, with the ultim-
ate goal to maximize adherence.

Objectives

Primary objective

The primary objective is to establish the potential for preci-
sion hypertension care, by investigating if there is a consist-
ent between-person variation in blood pressure response to
the common blood pressure-lowering drug classes of a clin-
ically relevant magnitude, given the within-person variation
in blood pressure.

Secondary objectives

a. To investigate the between-person variation in side
effects of blood pressure-lowering drugs in contrast to
the within-person variation in side effects.

b. To investigate patient treatment preferences when pre-
sented with: i) their individual ratings for each drug
class; ii) a combination of their individual ratings and
blood pressure effect of each drug class.

c. To develop a prediction model based on biomarkers
and clinical characteristics for patient treatment
preferences.

d. To develop and evaluate a point-of-care tool using this
prediction model, in order to inform treatment decisions
in the clinical setting.

Tertiary objectives

a. To evaluate between- and within-person variation in
response in mean and standard deviation of daytime,
nighttime, and 24-h blood pressure and heart rate to
the common blood pressure-lowering drug classes.

b. To evaluate between- and within-person variation in
self-reported symptoms and quality of life in response
to the common blood pressure-lowering drug classes.

c. To evaluate between- and within-person variation in
pulse wave characteristics and estimated central blood
pressure in response to the common blood pressure-
lowering drug classes.

d. To evaluate between- and within-person variation in
DNA methylation, RNA, proteins, and metabolites in
response to the common blood pressure-lowering
drug classes.

e. To investigate associations of DNA genomic variation,
DNA methylation, RNA, proteins, and metabolites with
blood pressure effects and self-reported symptoms and
quality of life.

f. To investigate the associations of self-reported symp-
toms and quality of life collected using an electronic
diary with patients’ treatment preferences and adverse
events reported in the clinic.

Study design

Rationale

To identify the patient-by-treatment interactions and hence
investigate the patient-specific differences in treatment
effects, a repeated cross-over design, where the same treat-
ment contrasts are repeated within each patient, is needed.
This has been convincingly suggested for decades (12), but
such designs have been surprisingly rarely used given the
current focus on precision medicine. In the PHYSIC trial,
each patient is given all four first-line hypertension drugs,
one at a time, and in addition repeats two of the treat-
ments. This allows us to quantify whether there is consistent
preference of one treatment over another within a blinded
patient over different treatment periods. Separation of
period effects and drug effects is key. Without pairwise
repetition of treatments, a trial cannot assess whether a
patient that preferred a certain treatment over another did
so because of the treatment or because of an external factor
such as the season or normal day-to-day variation. It would
also have been impossible to assess whether a variation in
treatment effects was due to differences between drugs in
on-treatment within-patient variation, such as patients hav-
ing larger day-to-day or season-to-season variations when
on one of the drugs.

The study needs to be double-blind, and the order of the
treatment periods randomized, in order to avoid obvious
sources of bias.

Evidence-based titration and target doses have been
chosen for all four drug classes included in this protocol (13).
Within each drug class a compound that fitted the gelatin
capsules was chosen. The suggested treatment duration per
treatment arm is based on recent guidelines (14).

The study is outlined in Table 1, examples of treatment
sequences illustrated in Figure 1, and the sequence of events
described in Table 2.

The first patient was randomized in the first quarter of
2017; last patient out is expected in the fourth quarter
of 2021.

Study visits and periods

Visit 1. The screening visit (visit 1) will occur at least two weeks
before randomization (visit 2). Written informed consent is

52 J. SUNDSTR€OM ET AL.



obtained, eligibility criteria (described in Table 3) checked, and
assessments are made of weight, height, waist, hip circumfer-
ence; a physical examination is carried out, concomitant medi-
cation is noted, office blood pressure is measured, and blood
is sampled. The patient fills out two questionnaires covering
medical history and beliefs about medicine. All questionnaires
in the study are summarized in Table 4.

Written lifestyle advice (physical activity, weight loss, diet-
ary changes, stress management, etc.) in accordance with
national guidelines (SBU 2007) is provided to all participants.

Placebo run-in period. After the screening visit, the patient
stops taking any concomitant blood pressure-lowering drugs
and starts on a placebo run-in period of two weeks to estab-
lish an untreated baseline to be used for characterization of
the study sample.

Visit 2. At visit 2, eligibility criteria are checked once again.
Assessments made at this visit include fasting venous and

capillary blood sampling, questionnaires, and pulse wave ana-
lysis, and 24-h blood pressure and ECG monitoring is initiated.

If all criteria are met, the patient is randomized and given
the first study drug. The study drug is to be taken once daily.

The day after visit 2, the patient returns the 24-h blood
pressure and ECG equipment to the clinic.

Treatment period. Between visits 2 and 3 patients are dos-
ing study drug at home, and fill out the side effects ques-
tionnaire at home at specific time points.

Visit 3. At visit 3 of each treatment period (which occurs
after 4–6 weeks on the target dose of the study drug,
7–9 weeks after the previous visit 3) the patient comes fast-
ing to the clinic for blood sampling, body weight, concomi-
tant medication, and adverse events (AE) checks, office BP
measurement, and initiation of 24-h blood pressure and ECG
measurement. The patient fills out two paper questionnaires:
the side effect questionnaire (identical to the questionnaire

Figure 1. Study design. Each patient is randomly assigned to a treatment sequence created from one of the six possible combinations, by random permutation of
the order in which the active treatments are given (the figure is a mere illustration of a few examples of possible sequences). Hence, 1/6 of the patients receive
ACEi and ARB in two periods each, 1/6 of patients repeat the ACEi and CCB periods, 1/6 of the patients repeat the ACEi and Diuretic periods, 1/6 repeat the ARB
and CCB periods, 1/6 repeat the ARB and Diuretic periods, and 1/6 repeat the CCB and Diuretic periods. Block randomization is used to ensure that approximately
the same number of patients are assigned to each of the six combinations of active treatments. ACEi ¼ angiotensin-converting enzyme inhibitor;
ARB ¼ angiotensin receptor blocker; CCB ¼ calcium channel blocker; Diuretic ¼ thiazide diuretic. Blank arrows indicate placebo run-in and wash-out.

Table 1. Study outline.

Setting Patients diagnosed with hypertension with a systolic blood pressure between 140 and 159 mmHg within five years before the
start of the trial. Patients must be pharmacologically untreated or use blood pressure-lowering monotherapy at the time of
recruitment to the present study.

Design Double-blind, randomized, repeated cross-over, single-centre study.
Number of patients

(planned)
300 patients included to obtain 240 evaluable patients.

Interventions Candesartan: 8 mg weeks 1–2; 16 mg weeks 3–8 Lisinopril: 10 mg weeks 1–2; 20 mg weeks 3–8 Amlodipine: 5 mg weeks 1–2;
10 mg weeks 3–8 Hydrochlorothiazide: 12.5 mg weeks 1–2; 25 mg weeks 3–8.

Treatment duration The study consists of six active treatment periods: four classes of blood pressure-lowering drugs will be tested, treatment with two
classes are repeated for each patient. Patients will be assigned a treatment order based on block randomization ensuring that
the same number of patients will repeat each treatment. Active drug is given during 6–8 weeks of each treatment period
(titration dose week 1–2, target dose week 3–8). Placebo will be administered during 2 weeks of placebo run-in (between visit
1 and 2) and during 7 days’ wash-out between treatment periods. This gives a total duration of treatment of 47–59 weeks for
each included patient.

Outcome The primary analysis of individual variation in treatment differences in visit 4 daytime (10.00–20.00) ambulatory systolic blood
pressure will be performed using a random effects model with correlated random intercept and treatment contrasts, allowing
correlation between all random effects, and with treatment period as a fixed effect. All available periods with >90% treatment
adherence from all randomized patients will be used.

UPSALA JOURNAL OF MEDICAL SCIENCES 53



for home use) and a treatment preference rating question-
naire. The patient returns all unused study drug (ensuring
that they have full coverage of study drug until the comple-
tion of visit 4) and receives the next treatment kit, which
starts with a 7-day placebo wash-out period before the next
active drug treatment period starts.

In rare cases, if a patient due to unbearable side effects of
a specific treatment so wishes, bailout visits 3 and 4 can be
carried out and the treatment period terminated prematurely
so that the next treatment period can begin.

Visit 4. At visit 4, the day after visit 3, the 24-h blood
pressure and ECG measurement ends and the patient returns
the equipment to the clinic. The treatment periods and visits
3 and 4 are repeated for a total of 6 times.

Visit 5. Visit 5 occurs 1–2weeks after the sixth and last visit
4. At visit 5, the patient is asked by an independent physician
to do an overall treatment preference rating including all treat-
ment periods, based on a summary of the patient’s own

reported side effects, treatment preference ratings for all treat-
ment periods, and ambulatory daytime blood pressures. All
data in the summary have been validated by data management
personnel, signed by the PI and locked before being presented
to the patient. As a final step, the independent physician breaks
the randomization code for each completed patient, and pre-
scribes the drug preferred by the patient for continuous use.

Statistical considerations

Analysis population

Intention-to-treat analyses will be used for all side effects,
including all patients taking at least one dose of the study
drug in a new treatment period. As-randomized analyses will
be used for blood pressure endpoints, including all patients
having had a treatment adherence of more than 90% during
that treatment period.

Table 2. Sequence of events.

Visit 1 Placebo run-in (�2 weeks) 2
Treatment period

5Dosing at home 3 4

Week –1 –(–2) 1 1–7 7 8
Day –7 –(–14) 1 2–54 55 56
Informed consent �
Inclusion/exclusion criteria � �
Anthropometrya �
Physical examination �
Office BPb � � �
Concomitant medication � � �
Safety samplesc � � �d

DNA genomic samplese �
Medical history Qg �
Beliefs about medicine Q �
Placebo dosing � �
Randomization �
Study drug dosingh � � � �
Staff train patients in electronic diaryf �
Self-reporting of symptoms in electronic diaryi � �
PERSYVE Q � �
Pulse wave analysis �
Capillary blood sampling and dried blood spots �
Venous blood samples for DNA methylation, RNA, other biomarkersj � �
AE/SAE recordingk � �q

Treatment preference rating Ql �
24-h BP/ECGm �n � �
Return of unused study drug by patients �
Supply next study drug and 7-day placebo �
Overall treatment preference ratingo �
Prescription of preferred drug for continuous useo �
a Measured using standard field protocols.
b Prior to measurement patient will rest sitting for 10 min. Measurement twice within 5 min in-between measurements using a sphygmomanometer.
c The following safety samples will be analysed: Hb, HbA1c, sodium, potassium, calcium, creatinine, ASAT, ALAT, c-GT, and pregnancy test.
d Last safety samples are taken and analysed at visit 3, in the last treatment period only.
e Whole blood sample taken in two 7/6 ml EDTA VacutainersV

R
.

f Patient fills in the electronic diary (PERSYVE Q) under supervision of study staff.
g Q covering demographic items, medical history, smoking, and physical activity.
h Dosing once daily in all treatment periods.
i When patients are dosing at home (between visit 2 and 3) symptoms will be recorded in PERSYVE Q using an electronic diary. Patients will report
spontaneously but will also be prompted via SMS at three occasions: after 3, 5, and 7 weeks of dosing.
j Details specified in a laboratory manual.
k Adverse events recorded by clinical staff at visits 2 and 3 in each treatment period (observations, open questions, and reporting of symptoms spontaneously
mentioned by patients). PERSYVE Q completed before the open AE question.
l At visit 3 in each treatment period patients will fill out a treatment preference rating Q consisting of five questions covering willingness to pay, treatment
preference, safety, and motivation.
m 24-h BP/ECG at the end of each treatment period, between visits 3 and 4. Applied at visit 3 and removed the same time at visit 4.
n 24-h BP/ECG also at the end of placebo run-in to get a baseline assessment.
o Overall patient preference rating and prescription of preferred study drug for continuous use.
Q ¼ questionnaire.

54 J. SUNDSTR€OM ET AL.



Primary analyses: individual variation in treatment
differences

The primary analysis of individual variation in treatment differ-
ences in visit 4 daytime systolic blood pressure will be

performed using a random effects model with correlated ran-
dom intercept and treatment contrasts, allowing correlation
between all random effects, and with treatment period as a
fixed effect. All available periods with >90% treatment adher-
ence from all randomized patients will be used. The global
hypothesis—that there is a contribution from patient-specific
differences in relative treatment response to the variation in
on-treatment blood pressure in the analysis set—will be
tested using a likelihood ratio test based on the maximum-
likelihood fit of that model compared to a model with random
intercept (only) and treatment contrasts and treatment period
as fixed effects. Since variance parameters must be non-nega-
tive, the null hypothesis lies on the border of the parameter
space of the larger model. Hence the usual assumption of chi-
square distribution in the likelihood ratio test is not valid, and
the test statistic will be compared to a reference distribution
obtained by parametric bootstrapping to obtain a p values.
P < 0.05 will be considered statistically significant.

Appropriate methods will be used to present estimates of
treatment contrast variances, covariances, and residual vari-
ance. Homoscedasticity of the residual variance will be inves-
tigated. A detailed statistical analysis plan for pre-defined
analyses will be finalized before unblinding. Problems with
model convergence or other changes to the analysis will be
recorded in a statistical report.

For each pair of treatment regimens (say X and Y),
descriptive plots and tables will be produced based on the
patients that had repeated periods with both treatment X
and Y. A pre-defined pairing of the periods for each patient,
into what amounts to two cross-over trials in the same
patient, will be used to produce two independent measure-
ments of the treatment contrast X–Y within each patient.

Corresponding analyses will be performed for other blood
pressure measurements. Similar analyses, adapted for type and
distribution of the variable, will be performed for visit 3 meas-
urements of other outcome variables, as appropriate. Pre-
defined analyses will be described in the SAP. No formal adjust-
ment for multiplicity will be performed in the primary analyses.

Secondary analyses: exploratory biomarker analyses

If the primary analyses indicate that there may be a substantial
between-person variation in effect of treatment on blood pres-
sure, exploratory analyses will be conducted developing pre-
diction models for individual effects on blood pressure.
Prediction models for side effects will be pursued irrespectively
of results of the primary models. Models will be developed
using DNA, RNA, and other biomarkers to predict individual
treatment effects on blood pressure and side effects. The
Institute of Medicine guidelines for development and valid-
ation of omics-based tests will be used (15). Because of the
limited sample size, the cross-validation approach will be pri-
oritized over training/test set sample division approaches.
Similar models as in the primary analyses will be used, typic-
ally involving mixed models with fixed effects for most of the
independent variables, and random effects across patients and
other structural elements. Significance level correction for mul-
tiple testing approaches such as 5% FDR will be applied.

Table 3. Inclusion and exclusion criteria.

Inclusion criteria
� Male or female aged �40 years and �75 years
� Previously diagnosed with hypertension with systolic blood pressure

between 140 and 159 mmHg within 5 years prior to the start of the trial
� Pharmacologically untreated or using blood pressure-lowering

monotherapy at visit 1. No blood pressure-lowering medication taken
during the placebo run-in period

� Office systolic blood pressure between 140 and 179 mmHg and diastolic
blood pressure at or below 109 mmHg at visit 2

� Patients must give informed consent to participate in the study
Exclusion criteria
� Medical history, clinical signs, or laboratory results indicating

secondary hypertension, including primary aldosteronism or renal
artery stenosis

� Evidence of serious hematological, respiratory immunological, renal,
hepatic, gastrointestinal, endocrinological, metabolic, neurologic, malig-
nant, psychiatric, or other diseases as revealed by medical history, physical
examination, and/or laboratory assessments

� Active gout
� Previous or present arterial occlusive diseases such as myocardial infarction

(MI), stroke or acute arterial insufficiency (unstable angina pectoris or
transient ischemic attacks [TIA]), or heart failure (NYHA class III or IV, or
left ventricular systolic dysfunction irrespectively of function class)

� Moderate or severe aortic or mitral insufficiency
� Renal failure, including hemodialysis or kidney transplant(s)
� Atrial fibrillation in need of rate control
� Symptomatic hypotension, defined as weakness or syncope upon

rising to an erect position associated with a decrease in systolic
blood pressure

� Diabetes requiring insulin or oral glucose-lowering drugs
� Any history of serious abnormal drug reaction to active or inactive com-

pounds in the study drugs, including angioedema
� Any condition associated with poor compliance including alcoholism or

drug dependence
� Patients who will not comply with the study protocol as judged by the

investigator
� Women who are pregnant or lactating or not using appropriate contracep-

tion for at least 3 months prior to visit 1. Acceptable contraceptive meth-
ods are: combined (estrogen and progesterone containing) hormonal
contraception associated with inhibition of ovulation (oral, intravaginal,
transdermal), progesterone-only hormonal contraception associated with
inhibition of ovulation (oral, injectable, implantable), intrauterine device,
intrauterine hormone-releasing system, bilateral tubal occlusion, and
vasectomized partner

� Continuous use of concomitant medication that can interfere with
study medication, i.e. digitalis glucosides, sotalol, cholestyramine,
colestipol, NSAID, lithium, carbamazepine, CYP3A4-inhibitors, CYP3A4-
inducers, dantrolene, diuretics, aliskiren, gold, sympathomimetics, tricyclic
antidepressants, antipsychotics, anaesthetics, and potassium supplements

� Clinical laboratory assessment outside normal range at visit 1 and judged
clinically significant by the investigator

� Previous randomization in present study

Table 4. Questionnaires.

At visit 1 the patients complete a questionnaire covering demographic items,
medical history, smoking, and physical activity.

At visit 1 the patients complete a ‘Beliefs about medicine’ questionnaire.
At visit 2 after placebo run-in and at visit 3 after each treatment period,

patients fill out a modified section 2.1 of the ‘PERSYVE’ questionnaire on
paper in the clinic. Patients are also prompted via SMS to fill out the ques-
tionnaire at home at specific time points—at week 3, week 5, and week 7
of each treatment period, on paper or using an electronic diary (provided
by Symptoms Europe AB, filled out via smartphone).

At visit 3 in each treatment period patients will fill out a ‘Treatment prefer-
ence rating questionnaire’ consisting of five questions covering willingness
to pay, treatment preference, safety, and motivation.

At visit 5 patients fill out an ‘Overall treatment preference rating’.

UPSALA JOURNAL OF MEDICAL SCIENCES 55



In further exploratory analyses we will use instrumental
variable regression techniques combining genomic DNA with
DNA methylation/RNA/protein/metabolite data (Mendelian
randomization) to address the causal role of the identified
biomarkers for blood pressure response and side effects,
which is unimportant for prediction purposes, but key for
further investigation of new druggable targets.

Determination of sample size

Statistical power for detecting between-patient variation in
treatment effects was simulated using R v. 3.2.2 (R Foundation
for Statistical Computing, Vienna, Austria), and packages lme4
v. 1.1–10 (16) and pbkrtest v. 0.4–4 (17). Altogether 500 trials
were simulated for each alternative hypothesis, and for each
simulated trial a p values was computed using 1000 bootstrap
iterations for the reference distribution of the test statistic
(Table 5). P < 0.05 was considered a significant outcome. The
trials were simulated without period effects, and the analysis
model did not include period as a factor. The validity of the
method was investigated by simulating power under the null
hypothesis. The on-treatment standard deviation of between-
and within-patient variation in systolic blood pressure was
assumed to be 14 and 12mmHg, respectively, based on
repeated measurements about 1 month apart in 21 patients.

Two scenarios were simulated. In the first, normally dis-
tributed uncorrelated individual treatment effects were
added to between one and four of the treatment arms, with
a standard deviation of 5, 7.5, or 10 mmHg. With n ¼ 240
patients, the trial has a power of 82% for detecting individ-
ual treatment effects if only one treatment arm differs from
the others by having an individual variation in effect with SD
¼7.5 mmHg, and a very high power if two or three treat-
ments have patient-specific effects on that level.

The second scenario is intended to describe a simplified
on/off switch for effect. We assume that for one of the treat-
ments 20%, or 50%, of the patients experience an effect that
is 10, 20, or 30 mmHg higher (or lower) than the remaining

patients. The trial has 90% power to show if a subgroup of
20% of patients has an effect that differs by 20 mmHg on
one of the treatments. In terms of SD of treatment effects,
the power is similar to the simulations under normal distribu-
tion (the SD is the subgroup effect times 0.5 for the 50%
case and times 0.4 for the 20% case).

Study conduct

Permissions

The study was approved by the Ethics Committee of Uppsala
University (Dnr 2016/135) and the Swedish Medical Products
Agency (Dnr 5.1–2016-25102; EudraCT 2015–003049-24). The
study follows a protocol pre-registered at ClinicalTrials.gov with
the identifier NCT02774460. The study is conducted in accordance
with the protocol, applicable regulatory requirements, GCP, and
the ethical principles of the Declaration of Helsinki as adopted by
the 18th World Medical Assembly in Helsinki, Finland, in 1964 and
subsequent versions. Written informed consent will be obtained
from all patients prior to enrolment in the study.

Randomization and blinding

The study will be patient-, investigator-, study nurse-, UCR
study team-, and sponsor-blinded. Clinical examinations,
interpretations of 24-h blood pressure and ECG measure-
ments, and assessments of side effects, treatment preferen-
ces, and other questionnaires will be performed by persons
unaware of the treatment allocation.

The order of the different active treatments is randomized
for each patient. The patients are assigned consecutive random-
ization numbers according to their inclusion order, and clinical
staff will record the numbers being used. The randomization
list is prepared at Uppsala Clinical Research Center (UCR).

The investigational products are manufactured and packaged
in inconspicuous blister packaging and labelled by Apotek

Table 5. Summary of power simulation.

Simulation model (mmHg):
SBPi ¼ Intercepti þ IndTreatA � TreatAi þ IndTreatB � TreatBi þ IndTreatC � TreatCi þ IndTreatD � TreatDi þ ei; period
Between-patient variation assumption: Intercepti � N 0; 14ð Þ
Within-patient variation assumption: ei;period � Nð0; 12Þ

Null hypothesis with N ¼ 240 (for validation purpose, should be 5%)
TreatAi ¼ TreatBi ¼ TreatCi ¼ TreatDi ¼ 0
5.2%

Normally distributed individual treatment effects with SD ¼ x mmHg
TreatAi � N 0; að Þ; TreatBi � N 0; bð Þ; TreatCi � N 0; cð Þ; TreatDi � N 0; dð Þ
N ¼ 240

x ¼ 5 x ¼ 7:5 x ¼ 10
a ¼ b ¼ c ¼ 0; d ¼ x 29% 82% >99%
a ¼ b ¼ 0; c ¼ d ¼ x 46% 97% >99%
a ¼ 0; b ¼ c ¼ d ¼ x 57% >99% >99%
a ¼ b ¼ c ¼ d ¼ x 64% >99% >99%

A fraction p of patients have x mmHg uniformly higher BP on treatment D
(note that SD TreatDið Þ ¼

ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
p � 1�pð Þ

p
� x, maximum SD¼x/2 at 50% fraction)

TreatDi � Bð1; pÞ � x
N ¼ 240

x ¼ 10 x ¼ 20 x ¼ 30
p ¼ 20% 12% 90% >99%
p ¼ 50% 27% >99% >99%

56 J. SUNDSTR€OM ET AL.



Produktion och Laboratorier AB (APL) in accordance with good
manufacturing practice (GMP) and local regulatory guidelines.

Data management and monitoring

Electronic case report forms (eCRF) are used for all data col-
lection, in accordance with a pre-specified data management
plan. In accordance with GCP principles, monitoring of the
study is arranged by the sponsor, and carried out by UCR, in
accordance with a pre-specified monitoring plan.

This study uses two study databases, database #1 for the
majority of the study, and database #2 for visit 5. On an indi-
vidual patient level, after the last visit 4, database #1 is vali-
dated by data management personnel, signed by the PI, and
locked, before being presented to the patient by an inde-
pendent physician. After each patient has provided a new
overall treatment preference rating, the independent phys-
ician signs the eCRF, breaks the randomization code for that
patient, and enters the eCRF data into database #2. Upon
study completion databases #1 and #2 are merged.

Perspective

In the PHYSIC trial, we use the only design that can study
the potential for precision medicine for blood pressure-low-
ering treatment (12). The crucial disentangling of all variance
components has not been possible in previous studies of
this research question (8–10). We reproduce a previous trial
(9), removing several important sources of bias, increasing
the sample size 5-fold, and using ambulatory blood pressure
measurements that further increase power. The concept of
n-of-1 trials to guide treatment decisions has been advo-
cated (18), and it is akin to the PHYSIC study design but on
an individual level (19). Because the evaluation of blood
pressure effects should not be done until after a month on
the target dose, n-of-1 trials of four classes of blood pres-
sure-lowering drugs would be prohibitively long if all treat-
ment contrasts were to be repeated in an individual patient.
Hence the appeal of a biomarker panel to guide treatment
choice. Importantly, our study design has the power to rule
out any potential for biomarker-based precision hypertension
care, in which case research resources are better spent else-
where. It can also inform on the sensibleness of n-of-1 trials
in hypertension, or, simply put, the usefulness of trying
another drug if a patient experiences side effects or ques-
tionable blood pressure effects of the first drug.

Disclosure statement

The authors report no conflicts of interest.

Notes on contributors

Johan Sundstr€om, MD PhD, specialist physician at Uppsala University
Hospital, professor of epidemiology at Uppsala University; principal
investigator and designer of the trial.

Lars Lind, MD PhD, specialist physician at Uppsala University Hospital,
professor of medicine at Uppsala University; co-principal investigator
and co-designer of the trial.

Shamim Nowrouzi, MD, resident in internal medicine at Uppsala
University Hospital; co-investigator and co-designer of the trial.

Per Lytsy, MD PhD, specialist physician, associate professor, medical
advisor at the Swedish agency for health technology assessment and
assessment of social services; co-designer of the trial.

Kerstin Marttala, RN, research nurse at Uppsala University Hospital;
study nurse and co-designer of the trial.

Inger Ekman, project manager at Uppsala Clinical Research Center;
co-designer of the trial.

Patrik €Ohagen, biostatistician at Uppsala Clinical Research Center;
co-designer of the trial.

Ollie €Ostlund, PhD, biostatistician at Uppsala Clinical Research Center;
co-designer of the trial.

ORCID

Per Lytsy http://orcid.org/0000-0003-1949-6299

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58 J. SUNDSTR€OM ET AL.


	Abstract
	Background
	Objectives
	Primary objective
	Secondary objectives
	Tertiary objectives

	Study design
	Rationale
	Study visits and periods

	Statistical considerations
	Analysis population
	Primary analyses: individual variation in treatment differences
	Secondary analyses: exploratory biomarker analyses
	Determination of sample size

	Study conduct
	Permissions
	Randomization and blinding
	Data management and monitoring

	Perspective
	Disclosure statement
	Notes on contributors
	References