BACKGROUND: The fixed dose antimalarial combination of dihydroartemisinin-piperaquine (DP) is a promising new artemisinin-based combination therapy (ACT). We present an individual patient data analysis of efficacy and tolerability in acute uncomplicated falciparum malaria, from seven published randomized clinical trials conducted in Africa and South East Asia using a predefined in-vivo protocol. Comparator drugs were mefloquine-artesunate (MAS3) in Thailand, Myanmar, Laos and Cambodia; artemether-lumefantrine in Uganda; and amodiaquine+sulfadoxine-pyrimethamine and artesunate+amodiaquine in Rwanda. METHODS AND FINDINGS: In total 3,547 patients were enrolled: 1,814 patients (32% children under five years) received DP and 1,733 received a comparator antimalarial at 12 different sites and were followed for 28-63 days. There was no significant heterogeneity between trials. DP was well tolerated with 1.7% early vomiting. There were less adverse events with DP in children and adults compared to MAS3 except for diarrhea; ORs (95%CI) 2.74 (2.13 to 3.51) and 3.11 (2.31 to 4.18), respectively. DP treatment resulted in a rapid clearance of fever and parasitaemia. The PCR genotype corrected efficacy at Day 28 of DP assessed by survival analysis was 98.7% (95%CI 97.6-99.8). DP was superior to the comparator drugs in protecting against both P.falciparum recurrence and recrudescence (P = 0.001, weighted by site). There was no difference between DP and MAS3 in treating P. vivax co-infections and in suppressing the first relapse (median interval to P. vivax recurrence: 6 weeks). Children under 5 y were at higher risk of recurrence for both infections. The proportion of patients developing gametocytaemia (P = 0.002, weighted by site) and the subsequent gametocyte carriage rates were higher with DP (11/1000 person gametocyte week, PGW) than MAS3 (6/1000 PGW, P = 0.001, weighted by site). CONCLUSIONS: DP proved a safe, well tolerated, and highly effective treatment of P.falciparum malaria in Asia and Africa, but the effect on gametocyte carriage was inferior to that of MAS3.
BACKGROUND: The fixed dose antimalarial combination of dihydroartemisinin-piperaquine (DP) is a promising new artemisinin-based combination therapy (ACT). We present an individual patient data analysis of efficacy and tolerability in acute uncomplicated falciparum malaria, from seven published randomized clinical trials conducted in Africa and South East Asia using a predefined in-vivo protocol. Comparator drugs were mefloquine-artesunate (MAS3) in Thailand, Myanmar, Laos and Cambodia; artemether-lumefantrine in Uganda; and amodiaquine+sulfadoxine-pyrimethamine and artesunate+amodiaquine in Rwanda. METHODS AND FINDINGS: In total 3,547 patients were enrolled: 1,814 patients (32% children under five years) received DP and 1,733 received a comparator antimalarial at 12 different sites and were followed for 28-63 days. There was no significant heterogeneity between trials. DP was well tolerated with 1.7% early vomiting. There were less adverse events with DP in children and adults compared to MAS3 except for diarrhea; ORs (95%CI) 2.74 (2.13 to 3.51) and 3.11 (2.31 to 4.18), respectively. DP treatment resulted in a rapid clearance of fever and parasitaemia. The PCR genotype corrected efficacy at Day 28 of DP assessed by survival analysis was 98.7% (95%CI 97.6-99.8). DP was superior to the comparator drugs in protecting against both P.falciparum recurrence and recrudescence (P = 0.001, weighted by site). There was no difference between DP and MAS3 in treating P. vivax co-infections and in suppressing the first relapse (median interval to P. vivax recurrence: 6 weeks). Children under 5 y were at higher risk of recurrence for both infections. The proportion of patients developing gametocytaemia (P = 0.002, weighted by site) and the subsequent gametocyte carriage rates were higher with DP (11/1000 person gametocyte week, PGW) than MAS3 (6/1000 PGW, P = 0.001, weighted by site). CONCLUSIONS:DP proved a safe, well tolerated, and highly effective treatment of P.falciparum malaria in Asia and Africa, but the effect on gametocyte carriage was inferior to that of MAS3.
Over 80 countries worldwide have now implemented WHO recommendations to use
artemisinin-based combination therapy (ACT) as first-line treatment of
Plasmodium falciparummalaria [1], [2]. Dihydroartemisinin-piperaquine (DP) is a fixed
dose co-formulated ACT used increasingly in South East Asia, although it is not yet
registered by most national drug authorities. Most experience of the use of DP comes
from Vietnam, where it is the recommended first-line treatment. The bisquinoline
compound piperaquine as a monotherapy was used extensively in China where it
replaced chloroquine as the first-line treatment of falciparum and vivax malaria.
Between 1976 and 1994 over 300 tons of piperaquine were used in China in
antimalarial prophylaxis and treatment. The first combination of DHA and piperaquine
(China-Vietnam 8, CV8), also included primaquine and trimethoprim and was first
evaluated in Vietnam in 1990 [3]. CV8 was effective, and became part of national
treatment policy but, because of primaquinetoxicity concerns and uncertainty
whether trimethoprim contributed to treatment efficacy, these two component drugs
were eventually removed. The new two drugs combination became first line treatment
in Vietnam in 2007.Piperaquine has a terminal half-life of several weeks [4]. It is highly active
against chloroquine-resistant Plasmodium falciparum, and
vivax
[5].
Dihydroartemisinin (DHA) is the active metabolite of artesunate and artemether.
Recently, several clinical trials have been carried out to study the safety and
efficacy of DP for the treatment of P.falciparum malaria. The
randomized trials included in this individual patient data analysis [6]–[12] were conducted
between October 2003 and June 2006 using a prospectively predefined protocol with a
follow-up of at least 28 days and use of PCR parasite genotyping to distinguish new
infections from recrudescences.
Methods
The trials were conducted in North-western Thailand, Rakhine state, Myanmar, Southern
Laos, and Western Cambodia, where mefloquine combined with a three day course of
artesunate (MAS3) was the comparator drug, in Uganda where artemether-lumefantrine
(AL) was the comparator, and in Rwanda, where artesunate+amodiaquine
(AS+AQ) and a non-ACT group amodiaquine+sulfadoxine-pyrimethamine
(AQ+SP) were the comparator antimalarial drugs. In Rwanda, following high
levels of chloroquine (CQ) resistance, the combination AQ+SP was adopted as
the first-line anti-malaria treatment in 2001. However, AQ+SP has always
been considered an interim strategy and different artemisinin-based combination
treatments (ACT) have been tested in the past few years as possible alternatives.Patients presenting with acute uncomplicated falciparum malaria were recruited into
the treatment studies provided they gave fully informed consent. Eligible patients
were 12 to 59 months old patients weighing more than 10 kg in Rwanda, 6 months to 10
years old, weight >5 kg in Uganda, and all patients between 1 and 65 years in
Myanmar, Laos, Cambodia, and Thailand. Only uncomplicated cases of
P.falciparum monoinfections were included in Laos, Rwanda, and
Uganda, while in Cambodia, Thailand and Myanmar patients with mixed
(P.falciparum and P. vivax) infections were
included. Studies excluded pregnant or breastfeeding women, patients with HIV-AIDS
or severe malaria. Malaria on admission and reappearance were confirmed by
microscopy examination of blood smears. All sites screened actively for adverse
events until Day 28.
Study design and treatment regimens
Trials were open label randomized comparative studies. Lengths of follow-up
varied from 28 days in Rwanda, to 42 days in Laos, Myanmar, Uganda, and 63 days
in Cambodia and Thailand. Patients received a total dose of approximately 7
mg/kg bw dihydroartemisinin and 56 mg/kg bw piperaquine divided into 3 daily
doses, except in Cambodia and in the first trial in Thailand in which an earlier
dose regimen was used where the same total dose was divided into 4 doses given
at 0, 8, 24 and 48 h. One tablet of DP (Artekin®, Holleykin
Pharmaceutical Co., and in Uganda: Duo-cotecxin®, HolleyPharm) contained
40 mg of dihydroartemisinin and 320 mg of piperaquine phosphate. Comparator drug
doses were MAS3 3 days: artesunate 4 mg/kg/day, and mefloquine 8 mg/kg/day, or
AQ+SP: AQ 10 mg/kg/day for 3 days and SP 25 mg/kg of sulfadoxine and
1.25 mg/kg of pyrimethamine the first day or AS+AQ 3 days: artesunate 4
mg/kg/day, and amodiaquine 10 mg/kg/day, and AL, 20 mg artemether/120 mg
lumefantrine tablets according to weight as one (5–14 kg), two
(15–24 kg), three (25–34 kg), or four (≥35 kg)
tablets given twice daily for 3 days.Drug administration was observed directly by study investigators, except for one
arm in Myanmar where effectiveness was assessed [8]. The doses were
crushed and mixed with water and given in a syringe or on a spoon for children
unable to swallow tablets, and if vomiting occurred within one hour of dosing
(defined as early vomiting), the medication was re-administered. Drugs were
given with food in Cambodia, and Laos, and a glass of milk in Uganda. In
Myanmar, Thailand, and Rwanda no food was given.
Reappearance of falciparum malaria during the follow-up period
Polymerase chain reaction (PCR) parasite genotyping was performed on paired
samples for parasite genotyping to distinguish between new infections and
recrudescent cases. Allelic variation within MSP1, MSP2, and GLURP was used in
Asia as described previously [13]. In Rwanda, DNA was purified [14] and
two polymorphic markers MSP1 and MSP2 were analyzed [15]. In Uganda where
transmission intensity is very high, selected regions of MSP1 and MSP2 and 4
microsatellite markers were amplified using PCR and characterized based on
sequence and size polymorphisms identified by gel electrophoresis [16].
Ethical Approval
The clinical trials from each country were approved by appropriate authorities.
The Thai studies were approved by the Faculty of Tropical Medicine, Mahidol
University Ethical Committee (Bangkok, Thailand). Approval for the Laos study
was granted by the Ethical Committee of the Faculty of Medical Sciences,
National University of Laos; both of these studies were also approved by the
Oxford Tropical Research Ethics Committee (OXTREC), University of Oxford, UK.
The protocol for the trial in Myanmar was approved by the Myanmar Department of
Health and by the Médecins Sans Frontières (MSF) Ethical
Review Board. In Rwanda, the study was reviewed and approved by the Ministry of
Health of Rwanda and by the Ethical Committee of the Prince Leopold Institute of
Tropical Medicine, Antwerp, Belgium. The Cambodian study received ethical
clearance from the Cambodian National Ethical Review Committee (Ministry of
Health, Cambodia), and the MSF Ethical Review Board. In Uganda, approval came
from the Makerere University Research and Ethics Committee, the Uganda National
Council of Science and Technology, and the University of California, San
Francisco Committee for Human Research.
Data pooling
The databases of randomized controlled trials were sent by the investigators. The
following aspects of the quality of trial methodology were evaluated: generation
of the allocation sequence, adequacy of concealment of the allocation of
treatment, degree of blinding, and completeness of follow-up. Generation of the
allocation sequence and allocation concealment was classified as adequate,
inadequate, or unclear [17].Blinding was classified as open, single or double. The proportion of patients
lost to follow-up (regardless of failures) was computed and considered
acceptable if <10% within 28 days. Other markers of quality
assessed were whether a sample size was determined using power calculations and
whether an intention-to-treat (ITT) analysis could be computed.
Study endpoints and statistical analysis
The analysis was by modified intention-to-treat where patients who did not
complete the study were censored on their last day of follow-up, but they were
not regarded as a failure as in a “pure” ITT analysis.The primary endpoint was the treatment efficacy by Day 28. Patients lost to
follow-up (or missing a weekly visit) or with a new P.
falciparum infection were censored for the primary outcome at the time
they were last seen. All studies followed patients for at least 28 days and the
primary endpoint was defined prospectively as the parasitological treatment
failure (PCR confirmed: recrudescence, and PCR not corrected: recurrence).
Treatment failure was considered as the sum of early and late treatment
failures, as defined by the WHO [1] as one of the following: (i) danger signs,
death, or severe malaria at Days 1, 2 or 3 with parasitaemia; (ii) parasite
density at Day 2>Day 0; (iii) parasitemia at Day 3>25%
than Day 0, and recurrent parasitaemia after Day 4. Patients could be given less
than the full dose if they received rescue treatment or withdrew consent from
follow-up. Adequate Clinical and Parasitological Response (ACPR) was defined as
no parasitaemia until the end of the follow-up without previously meeting any of
the criteria for failure.The efficacy was measured using Kaplan-Meier survival analysis. We applied a
statistical correction for cases where PCR genotyping gave an indeterminate
result or was unavailable, computing adjusted quotients by determining the
probability by site and at any time of a parasite reappearance being either a
recrudescence or a new infection [18].The risks of recrudescence (reappearance of the same genotype)
in the DP groups compared to the comparator groups (stratified by
study), using the different lengths of follow-up of each studies.The risks of recurrence (defined as recrudescence as above and
new infections) in the DP groups compared to the comparator groups
(stratified by study), using the different length of follow-up of each
studies.The risk of new infection (excluding recrudescences) in DP
groups compared to the comparator groups per study and overall result
(stratified by study) at Day 28.The risks of treatment failure (i, ii, iii) were compared in multivariate
analysis (Cox regression models) individually and overall by stratifying by
site in an attempt to account for potential statistical heterogeneity.The predictors of recrudescence or new infection or recurrence
by Day 28 were assessed by Cox regression models. The covariates
examined were: sex, age (continuous), food absorption with the drug,
anaemia on admission (haematocrit <30%), parasite
count on admission (log transformed), elevated temperature on admission
(temperature measured by any method at ≥37.5°). As the
age groups were different between Africa (under 5 years old) and Asia
(children and adults), we conducted this part of analysis separately for
the 2 continents.Gametocyte carriageThe predictors of gametocyte prevalence on admission were
measured using a logistic regression and controlling for
site.The time to clearance of gametocytes already present on admission
with data censored at the time of gametocyte clearance was
calculated based on the results of blood smears. Within each
study, the same sampling schedules were used for all the
patients, but between trials parasite counts were performed at
different times so any analysis was stratified by site to
account for these differences. For patients who cleared
gametocytaemia, time of the first negative count (followed by
further negative counts) was taken as time of clearance.
Differentials in gametocytes clearance were calculated using
Kaplan-Meier method using logrank test, stratified by site, and
a Cox regression model stratified by site measured the risks of
gametocytes carriage between treatment groups.The predictors of gametocyte appearance during the follow-up in
patients without gametocytaemia on admission were assessed by a
Cox regression model stratified by site. The presence of
gametocytaemia after starting treatment was analysed as a binary
variable: the Mantel-Haenszel method and the homogeneity test
stratified by site were used to estimate a combined odds ratio
between treatments. One positive gametocyte count at any time
after treatment during the follow-up period was enough to define
gametocyte carriage, while a complete set of negative counts
during follow-up was required to confirm no carriage.Gametocyte carriage rates were measured in
person-gametocyte-weeks, using binary variable calculated within
42 days of follow-up. Person-gametocyte-weeks (PGW expressed per
1000) were defined as the number of weeks in which blood slides
were positive for gametocyte divided by the total number of
weeks followed up in patients with gametocyte results [19]. Mantel-Haenszel rate ratios
(RR) weighted by site were used to measure to the risks between
treatment groups.Haematological changes were measured using the paired t-test.
Anaemia was defined as haematocrit <30%, and anaemia
recovery during the follow-up by the time for the haematocrit to reach
30% or more.Adverse events: defined as any sign, symptom, or disease that
was not present on admission and was associated with the use of a
medicinal product, whether or not it was considered as related to the
medicinal product. A serious adverse event was defined as a sign or
symptom that was fatal, life threatening or required admission to
hospital. Adverse events were standardised and expressed as an incidence
density, in person-days at risk within 28 days. The incidence rate ratio
test was used to compare the incidence of adverse events. We assumed
that young children (<5 years old) were unable to answer
questions about dizziness, nausea, headache, confusion, numbness,
hearing disturbance, tinnitus or visual disturbance.The effects of DP on P. vivax recurrences in
the Asian trials with longer follow-up (63 days) was calculated by
censoring the data at the time of P. vivax appearance
(binary variable). The predictors of P.vivax appearance
were measured by using Cox regression, and the incidence density of
P. vivax appearance was calculated in
person-day.
Secondary outcomes were:
Heterogeneity was assessed by the Cochran Q test, and I2 test.
Chi-square, Mann-Whitney, Kruskall-Wallis tests were used as appropriate.
Confidence intervals (CI) were measured at 95% by the binomial
distribution, or the Wilcoxon procedure, or the Taylor series estimate as
appropriate [20]. The statistical programme used was STATA v10
(STATA corp.).
Results
Characteristics of included studies
A total of 3,547 patients were enrolled in six countries from 12 different sites
between October 2003 and June 2006. Individually, the trials enrolled between 75
and 303 patients treated with DP
(total = 1,814), 1,475 patients treated with
other ACTs, and 258 in the non-ACT (AQ+SP) group (figure 1). The proportion of patients lost to
follow-up was <10% in all the trials (4%, 110/3,547
at Day 28).
Figure 1
Note: DP; dihydroartemisinin-piperaquine, MAS3;
mefloquine-artesunate, AQ+SP;
amodiaquine+sulfadoxine-pyrimethamine, AL;
artemether-lumefantrine, AS+AQ;
artesunate+amodiaquine, Pf; P. falciparum,
loss; loss to follow-up, ACR; adequate clinical response, ACT;
artemisinin combination therapy.
Heterogeneity
In all the trials the methodological quality was high and the randomisation
sequence was computer-generated. All trials were open label, and the basis for
the sample size studied was provided in all studies. In all studies, the primary
treatment outcome was the parasitological treatment failure. All trials reported
data on haemoglobin levels during follow-up, and recorded gametocyte carriage at
study enrolment and during follow-up. All studies assessed adverse events and 10
different adverse events were documented in all trials. Although there were
differences in geographical location, transmission intensity (ranging from low
and seasonal in Thailand to very high in the African trial settings), age,
treatment and supervision, heterogeneity between trials was not significant
(I2 test = 26%,
P = 0.15, Cochran Q test for heterogeneity),
and regarded as low [21].
Baseline characteristics
The median age of the recruited patients was 13 years (range 1 to 65) (Table 1). Overall
32% of patients were under five years of age, 28% were
5–14, and 40% were adults. In Asia, age distributions were
similar in Cambodia, and in Thailand. The patients were younger in Laos and
Myanmar, while in Rwanda and Uganda only children were enrolled. There were no
differences detected in admission characteristics between DP groups and
comparator treatment groups, except for baseline gametocytaemia in Myanmar [8].
Overall 54.6% of patients were febrile (≥37.5°C) on
admission. This decreased to 8.8% at 24 h (i.e. median fever
clearance <24 hours) and 2.1% at 48 h. No difference was
detected between treatment groups. The median time for the spleen to be no
longer palpable was 14 days (range 1–42). There was no difference in
the time to resolution of splenomegaly between the treatment groups
(P = 0.70).
Parasitological efficacy
Of the 1,814 DP treated patients, 126 patients (6.9%) were lost to
follow-up by Day 28. Of the 221 patients with recurrent infections, 9 cases had
indeterminate PCR genotyping results, and 3 results were not available (lost
samples). The results of parasitological efficacy per study site are shown in
table 2, the number of
patients followed-up, recurrent and recrudescent cases, and the daily results by
category of follow-up are shown for a hypothetical cohort of 1000 persons with
and without the PCR correction (table 3). On Day 1 (24 hours after starting treatment),
31% (95%CI 29–34) of the patients had cleared
their parasitaemia, on Day 2, 89% (95%CI 87–90),
on Day 3, 98% (95%CI 97–99). All patients had
cleared their parasitaemia by Day 7.
Table 2
Dihydroartemisinin-piperaquine efficacy by country and site, Day 28,
survival analysis (Kaplan-Meier).
Country and site
Efficacy (%) Day 28 *
PCR uncorrected
PCR corrected
Efficacy
Lower 95% confidence interval
Upper 95% confidence interval
Efficacy
Lower 95% confidence interval
Upper 95% confidence interval
Uganda, site Apac, Day 28
89.0
84.8
93.2
98.0
92.9
98.8
Rwanda all sites, Day 28
88.4
83.7
91.8
95.2
91.6
97.3
Rwanda site MA
94.2
86.5
96.6
96.6
89.5
98.9
Rwanda site KI
97.3
89.4
99.3
97.3
89.4
99.3
Rwanda site RU
75.2
64.4
89.7
89.7
82.7
95.8
Thailand all sites, Day 28
98.2
97.2
99.2
99.5
98.0
99.7
Thailand site KT
97.0
95.1
98.9
99.0
95.9
99.3
Thailand site MT
100.0
98.7
100.0
100.0
98.7
100.0
Thailand site TR
97.8
91.1
98.5
100.0
97.8
100.0
Cambodia all sites, Day 28
98.6
94.3
99.1
99.1
95.5
99.3
Cambodia site AV
99.0
95.3
99.3
99.0
95.3
99.3
Cambodia site KV
98.1
90.6
98.6
99.1
95.4
99.3
Myanmar all sites, Day 28
98.1
97.2
99.0
99.3
95.4
99.4
site MN
98.4
93.8
100.0
100.0
97.2
100.0
site DB
97.4
93.8
98.8
99.5
98.1
99.9
Laos, Day 28
100.0
96.6
100.0
100.0
96.6
100.0
Total, Day 28
96.1
95.0
97.2
98.7
97.6
99.8
Efficacy based on randomised trials was assessed by modified intent
to treat analysis for recurrent and recrudescent cases. The
Kaplan-Meier results were expressed as percentages.
Table 3
Pooled efficacy of dihydroartemisinin-piperaquine against falciparum
malaria based on randomised trials assessed by survival analysis
(Kaplan-Meier).
Day group
Followed up
New infections
Recurrence (new
infection+recrudescence)
Recrudescence
N
N
Quotient
Population free of recurrence *
N
Quotient
Population free of recurrence *
N
Quotient **
population free of recrudescence *
0
1814
100.0
100.0
100.0
7
1797
2
0.0011
99.9
2
0.0011
99.9
0.0000
100.0
14
1779
2
0.0011
99.8
3
0.0017
99.7
1
0.0006
99.9
21
1758
8
0.0046
99.3
12
0.0068
99.0
4
0.0023
99.8
28 ***
1736
35
0.0206
97.3
51
0.0298
96.1
16
0.0104
98.7
35
1453
42
0.0298
94.4
52
0.0364
92.6
10
0.0069
98.1
42 ****
1388
47
0.0350
91.1
49
0.0359
89.3
2
0.0014
98.0
49
799
10
0.0127
89.9
11
0.0138
88.0
1
0.0013
97.8
56
777
22
0.0291
87.3
23
0.0300
85.4
1
0.0013
97.7
63 *****
745
18
0.0248
85.1
18
0.0245
83.3
0
0.0000
97.7
Total
186
221
35
Pooled efficacy based on randomised trials was assessed by intent to
treat analysis for recurrent and recrudescent cases. The
Kaplan-Meier analysis was computed for an hypothetical cohort of 100
persons (the population free of disease per 100 is equivalent to
efficacy expressed per 100).
CI = confidence interval.
Quotients adjusted for indeterminate cases.
Endpoint Rwanda.
Endpoint Laos, Uganda, Myanmar.
Endpoint Cambodia, Thailand.
Efficacy based on randomised trials was assessed by modified intent
to treat analysis for recurrent and recrudescent cases. The
Kaplan-Meier results were expressed as percentages.Pooled efficacy based on randomised trials was assessed by intent to
treat analysis for recurrent and recrudescent cases. The
Kaplan-Meier analysis was computed for an hypothetical cohort of 100
persons (the population free of disease per 100 is equivalent to
efficacy expressed per 100).
CI = confidence interval.Quotients adjusted for indeterminate cases.Endpoint Rwanda.Endpoint Laos, Uganda, Myanmar.Endpoint Cambodia, Thailand.
Primary endpoint: parasitological efficacy at Day 28
In DP groups, the overall observed parasitological efficacy using results from
survival analysis at Day 28, corrected by PCR was 98.7%
(95%CI 96.8–98.3). In children under 5 years old, the
corresponding efficacy was lower: 94.2% (95%CI
91.9–96.5, P = 0.001). For the
overall recurrence of P. falciparum parasitaemia the
corresponding results were 96.1% (95%CI
95.0–97.2) and 90.4% (95%CI 87.8–93.0)
in children (P = 0.001).
Secondary endpoints
i) Risk of recrudescence for the full length of follow-up by treatment
group
Based on randomised comparisons by country and using the full length of
follow-up of the different trials, DP recipients were at lower risk for a
PCR confirmed failure compared to MAS3 in Thailand
(P = 0.001), AL in Uganda
(P = 0.004), and AQ+SP in Rwanda
(P = 0.001)(figure 2, table
S1). Overall, using multivariate analysis stratified by site and
controlling for age, patients receiving DP had a lower risk of PCR confirmed
treatment recrudescence than with the comparator treatments
(AHR = 0.32, 95%CI
0.21–0.48, P = 0.001).
Figure 2
Note: HR; hazard ratio, CI; confidence interval.
DP; dihydroartemisinin-piperaquine, MAS3; mefloquine-artesunate,
AQ+SP; amodiaquine+sulfadoxine-pyrimethamine, AL;
artemether-lumefantrine, AS+AQ;
artesunate+amodiaquine. NC: not computable because of no
recrudescent cases. *Overall number of failures does not add
up because two comparators were used in Rwanda. Note: the forest
plot represents the risk of parasite reappearance (PCR corrected;
i.e. recrudescence, and not corrected i.e.
recrudescence+new infection) of DP versus comparators in
comparative studies. Groups size are equivalent except in Thailand
where the DP group was twice as large
(N = 686). Endpoints were assessed
on Day 28 in Rwanda, Day 42 in Laos, Myanmar, and Uganda, and Day 63
in Cambodia, and Thailand. Overall results were stratified by site,
and drugs. The size of the boxes is proportional to the number of
patients included and thus to the overall effect. The diamond
represents the overall hazard ratio and 95% CI.
Note: HR; hazard ratio, CI; confidence interval.
DP; dihydroartemisinin-piperaquine, MAS3; mefloquine-artesunate,
AQ+SP; amodiaquine+sulfadoxine-pyrimethamine, AL;
artemether-lumefantrine, AS+AQ;
artesunate+amodiaquine. NC: not computable because of no
recrudescent cases. *Overall number of failures does not add
up because two comparators were used in Rwanda. Note: the forest
plot represents the risk of parasite reappearance (PCR corrected;
i.e. recrudescence, and not corrected i.e.
recrudescence+new infection) of DP versus comparators in
comparative studies. Groups size are equivalent except in Thailand
where the DP group was twice as large
(N = 686). Endpoints were assessed
on Day 28 in Rwanda, Day 42 in Laos, Myanmar, and Uganda, and Day 63
in Cambodia, and Thailand. Overall results were stratified by site,
and drugs. The size of the boxes is proportional to the number of
patients included and thus to the overall effect. The diamond
represents the overall hazard ratio and 95% CI.
ii) Risk of recurrence for the full length of follow-up, by treatment
group
Using multivariate analysis and the full length of follow-up stratified by
site and controlling for age and anaemia, the overall risk of recurrence was
lower in the DP groups than in the comparator groups
(AHR = 0.60, 95%CI
0.51–89, P = 0.001)(figure 2). DP provided a
better protective effect against P. falciparum recurrence
than its comparator groups in Rwanda; compared to AQ+SP
(P = 0.006) and AS+AQ
(P = 0.006); to AL in Uganda
(P = 0.005); and MAS3 in Thailand
(P = 0.016).There was a longer interval from primary infection to recurrence (suggesting
a greater duration of suppressive prophylaxis) compared to MAS3 in Thailand
(median: 49 days vs. 37 days, respectively,
P = 0.001); in Uganda compared to AL
(median 35 vs. 28 days, respectively,
P = 0.001); in Rwanda compared to
AQ+SP (median 28 vs. 21 days, respectively,
P = 0.035), but was not different to
AS+AQ (P = 0.23).
iii) Risk of new infections (PCR confirmed) by Day 28
At 28 days the risk of new infection was greater in African compared to Asian
settings (P = 0.001) reflecting the higher
transmission intensity. In these high transmission areas, patients treated
with DP were at lower risk for a new infection within 28 days compared to
AQ+SP (HR = 0.38, 95%CI
0.19–0.76, P = 0.006),
AS+AQ (HR = 0.42, 95%CI
0.21–0.86, P = 0.018) in Rwanda
and AL (HR = 0.38, 95%CI
0.22–0.65, P = 0.001) in Uganda.
Overall, in the multivariate analysis stratified by site, DP had a greater
post treatment prophylactic effect (against new infections) at Day 28
against P. falciparum compared to the other treatments
(AHR = 0.47, 95%CI
0.33–0.67, P = 0.001).
iv) Predictors of recrudescence, new infection, and recurrence of
P. falciparum in DP groups by Day 28
In the DP groups, using multivariate analysis stratified by site at Day 28,
age (as continuous variable) was the only predictor of recurrence and
recrudescence in Africa or Asia when analyzed separately. In African
children, younger patients (per 1 year increase in age) were at higher risks
for recurrence (AHR = 0.86,
95%CI 0.77–96,
P = 0.006), and recrudescence
(AHR = 0.80, 95%CI
0.68–96, P = 0.018), as well as
in Asian patients (AHR = 0.93,
95%CI 0.90–0.96,
P = 0.001; and
AHR = 0.81, 95%CI
0.73–0.89, P = 0.001,
respectively).No significant predictors of new infections were detected in African
children, but in Asian patients younger patients were at higher risks for
new infections (AHR = 0.96,
95%CI 0.93–0.99,
P = 0.025).
v) Gametocyte carriage
Admission pre-treatment gametocytaemia was present in a median (range) of
6.1% (0.9–41.9) of the patients. Using multivariate
analysis in DP groups, and controlling by site, younger patients, admission
anaemia, and a lower admission parasite count were related to a higher risk
of patent gametocytaemia (table 4).
Table 4
Predictors of patent gametocytaemia, and gametocyte appearance,
dihydroartemisinin-piperaquine groups.
Independent variables
Gametocyte on admission
Gametocyte appearance
Age continuous
AOR = 0.97,
95%CI 0.95–0.98,
p = 0.001
Anaemia (ref: no anaemia)
AOR = 1.83,
95%CI 1.43–2.34,
p = 0.001
Parasite count (continuous)
AOR = 0.69,
95%CI 0.58–0.82,
p = 0.001
Model 1 for recurrence
Anemia on admission
AHR = 2.71,
95%CI 1.56–4.73,
p = 0.001
Recurrence during follow-up
AHR = 2.66,
95%CI 1.32–5.39,
p = 0.001
Model 2 for recrudescence
Anemia on admission
AHR = 2.83,
95%CI 2.61–8.66,
p = 0.001
Recrudescence during follow-up
AHR = 2.90,
95%CI 0.68–12.45,
p = 0.152
Note: Age was per 1 year increase in age, and parasite count was
per 1 unit increase in the log transformed parasite density.
AOR; adjusted odds ratio. AHR; adjusted hazard ratio. CI;
confidence interval.
Note: Age was per 1 year increase in age, and parasite count was
per 1 unit increase in the log transformed parasite density.
AOR; adjusted odds ratio. AHR; adjusted hazard ratio. CI;
confidence interval.Clearance of gametocytaemia was slower in DP groups than in the comparators,
overall and in individual sites. In Cambodia in the DP treatment arm,
82(95%CI 55–94)% of patients presenting with
gametocytaemia still had gametocytaemia on Day 3 compared to only
27(7–54)% in the comparator arm. On Day 14 of the
follow-up in Thailand 24(10–39)% in DP arm and
11(2–30)% in the other arm, in Uganda
7.4(2.4–16)% in DP arm compared to
1.8(0.3–13)% in the other arm, in Myanmar
31(23–38)% in DP arm as compared to none in the
comparator arm. Overall, using multivariate analysis, the risk of gametocyte
carriage by Day 14 was lower in comparators than in DP groups
(P = 0.002, stratified by site)(figure 3, table
S2).
Figure 3
Note: the forest plot represents the risk of clearing gametocytes
comparing DP versus comparator drugs in randomised studies.
The endpoint was assessed at Day 14. Overall result was stratified by
site. The size of boxes is proportional to the number of patients
included and thus to the overall effect. The diamond represents the
overall hazard ratio and 95% CI.
Note: the forest plot represents the risk of clearing gametocytes
comparing DP versus comparator drugs in randomised studies.
The endpoint was assessed at Day 14. Overall result was stratified by
site. The size of boxes is proportional to the number of patients
included and thus to the overall effect. The diamond represents the
overall hazard ratio and 95% CI.Overall 178 (8.4%) out of 2125 patients presenting without
gametocytes developed gametocytaemia after starting treatment. Recurrent
parasitaemia as well as anaemia on admission were associated with gametocyte
appearance (Table 4).
There were no significant overall differences in the risk of developing
gametocytaemia during follow-up between DP and all comparator arms
(Mantel-Haenszel OR = 1.02
[95%CI 0.75–1.40],
P = 0.89;
P = 0.035 for homogeneity between studies).
However, there were significant differences in appearance of gametocytes in
3 Asian countries (Cambodia, Myanmar, Thailand) between DP and MAS3
(Mantel-Haenszel OR = 1.89,
95%CI 1.23–2.91,
P = 0.003;
P = 0.643 for homogeneity between studies).
Including the Laos results, which only recorded if the patients had
gametocyte after admission as a sole binary variable, the proportion of
patients with gametocyte appearance within 42 days was higher in DP groups
(6.5%, 76/1164) compared to MAS3 groups (4.0%, 35/873)
(OR = 1.96, 95%CI
1.28–3.09, P = 0.002,
Mantel-Haenszel weighted by site)(figure 4).
In Cambodia, Myanmar, and Thailand, the overall gametocyte carriage rate
within 42 days was greater in the DP (56/1000 PGW, 260/4675,
95%CI 49–62) compared to MAS3 groups (36/1000 PGW,
100/2772, 95%CI
29–43)(RR = 1.36,
95%CI 1.06–1.76,
P = 0.017, Mantel-Haenszel weighted by
site). In patients without gametocytaemia on admission and who developed
gametocytaemia during the follow-up, the carriage rate was also greater with
DP (11/1000 PGW) than MAS3 (6/1000
PGW)(RR = 2.88, 95%CI
1.51–6.28, P = 0.001,
Mantel-Haenszel weighted by site).When using available data (from Thailand, Cambodia, Myanmar, and Uganda)
there was no relationship between the dose of DHA actually received by the
patient and the proportion of patients remaining with gametocytaemia on Day
14 (P = 0.382).
vi) Haematological changes
On admission, 537 out of 1,797 (29.9%) DP recipients with
available data were anaemic (Hct<30%). Of these
29.8% (74/537) had severe anaemia (Hct<20%).
Using multivariate analysis, anaemia on admission was strongly associated
with age and varied by country (Table 1). Children under 15 y were at
higher risk for anaemia compared to adults as well as patients from
Cambodia, Uganda, and Myanmar compared to Thailand
(P = 0.001, for all comparisons). By Day
28, 55% (162/293) of the anaemic patients had recovered from
anemia and 2.8% (24/851) who were not anaemic on admission became
anaemic. Overall, in anaemic patients, the median time to recovery (defined
as haematocrit ≥30%) ranged from 7 to 42 days. On Day 42,
the prevalence of anaemia was 3.4% (34/985). There were no
treatment differences in the development of anaemia.In Cambodia, Laos, Myanmar, Thailand, there was a relative mean paired
transient decline of 6.3% (95%CI 5.7–7.3) in
haematocrit from admission to Day 7 in DP groups. No difference was detected
compared to the MAS3 group. By contrast, in Rwanda, between Day 0 and Day
14, the relative mean paired haematocrit difference was significantly higher
in the AS+AQ group (+10%, 95%CI
8–11) compared to the DP group (+6%,
95%CI 4–8)(P = 0.021).
In Uganda, patients treated with DP (+20%,
95%CI 16–24) had a higher relative paired mean increase
in haemoglobin levels on Day 42 compared to AL group
(+16%, 95%CI 12–20,
P = 0.049).
vii) Drug vomiting, incidence of adverse events, number of adverse
events, and death
Overall, vomiting on admission and before treatment administration was a risk
factor for vomiting the first dose of DP
(OR = 6.1, 95%CI
3.2–11.7) and for vomitingDP treatment over the three days
(OR = 4.6, 95%CI
2.7–7.7). This was similar in every country. In patients who did
not present with vomiting on admission, the overall incidence of early
vomiting (defined as vomiting the drug within 1 hour after intake) DP was
low; 1.7% (21/1,231) on Day 0. Over the 3 days of treatment, the
overall incidence rate of early vomiting ranged from 3.2 (95%CI
2.1–4.8)% in Thailand to 9.9 (95%CI
6.8–14.4)% in Rwanda (Table 5). In DP groups, drug vomiting was
more frequent in Rwanda than all other countries
(P = 0.001) and was related to age: the
0–4 y age group (OR = 8.2,
95%CI 3.2–21.3), and the 5–14 y age group
(OR = 3.9, 95%CI
1.9–8.1) were at higher risk compared to adults. In Rwanda, the
incidence of overall vomitingDP was not different to that after
AS+AQ (11.5%,
P = 0.565), but the risk was much lower
than with AQ+SP (19.5%,
P = 0.002). No difference in the incidence
of early vomiting after drug treatment was observed between DP and MAS3 on
Day 0 (3.2%, and 2.4%, respectively,
P = 0.400), or overall (3.7%,
and 4.2%, respectively,
P = 0.671).
Table 5
Early vomiting (
Country
Daily incidence
Total incidence
95% confidence interval
N
Day 0
Day 1
Day 2
Myanmar
2.1%
1.2%
0.6%
4.0%
2.3%–6.8%
13/327
Cambodia
4.8%
1.3%
0.0%
5.2%
3.0%–9.1%
12/228
Rwanda
6.7%
2.4%
2.8%
9.9%
6.8%–14.4%
25/252
Thailand
2.6%
0.6%
0.1%
3.2%
2.1%–4.8%
22/686
Total
3.5%
1.1%
0.5%
4.8%
3.7%–5.9%
72/1495
We examined the incidence and prevalence of 24 other different adverse events
(apart from early vomiting) in 1,267 individuals using available records
from DP groups in five countries and 9 different sites. It was not possible
to calculate the adverse events duration in Laos, and Uganda. In the
remaining DP groups, the five most commonly reported adverse events by Day
28 were 23.3% for headache, 17.0% for dizziness,
13.8% for sleep disturbance, 11.6% for anorexia,
10.5% for nausea (table 6). Hypersensitivity reactions including urticaria were
reported in 4 patients in Thailand (0.6%, 4/686, 95%CI
0.2–1.5) [6]. The following adverse events: muscle
pain, hearing disturbances, itching, nightmares, visual disturbances,
dyspnoea, numbness, skin rash, agitation and confusion, were all reported in
less than 5% of cases. The maximum point prevalence rates of the
adverse events all occurred on Day 1. Day 1 and Day 2 captured
54% and the first week captured 70% of the reported
adverse event incidence.
Table 6
Adverse event incidence density and prevalence rates,
dihydroartemisinin-piperaquine groups.
Adverse event
Adverse event cumulative incidence
density over 28 days
Incidence within the first week*
Adverse event maximum
prevalence
Number of patients without the symptom on
admission
%
Lower 95%CI
Upper 95%CI
Day
%
Lower 95%CI
Upper 95%CI
Headache
124
23.3%
15.4%
31.2%
74%
Day 1
9.9%
5.8%
17.0%
Dizziness
457
19.3%
15.3%
23.2%
88%
Day 1
11.6%
8.5%
14.8%
Sleeping problem
811
18.4%
15.0%
21.7%
83%
Day 1
6.3%
4.8%
8.2%
Anorexia
521
16.7%
13.4%
19.9%
85%
Day 1
10.3%
7.7%
13.0%
Fatigue
628
15.0%
12.4%
18.1%
82%
Day 1
7.7%
5.9%
10.1%
Nausea
628
13.6%
10.8%
16.5%
83%
Day 1
8.7%
6.4%
11.0%
Joint pain
451
10.0%
7.6%
13.3%
63%
Day 1
4.7%
3.1%
7.2%
Abdominal pain
1040
9.6%
7.8%
11.4%
76%
Day 1
4.7%
3.4%
6.0%
Diarrhoea
1204
9.2%
7.5%
10.9%
84%
Day 1
4.8%
3.6%
6.1%
Late vomiting
1083
7.1%
5.5%
8.7%
86%
Day 1
4.7%
3.4%
6.0%
Palpitations
753
6.7%
5.1%
8.8%
82%
Day 1
3.2%
2.2%
4.8%
Hearing disturbance
971
6.3%
4.5%
8.1%
68%
Day 1
2.4%
1.3%
3.5%
CI; confidence interval.
The incidence within the first week is the proportion of cases
occurring in the first week divided by the total number of cases
within 28 days for each adverse event.
CI; confidence interval.The incidence within the first week is the proportion of cases
occurring in the first week divided by the total number of cases
within 28 days for each adverse event.In the Asian trials, the only adverse event that was significantly more
frequent in DP treated patients compared to the MAS3 group was diarrhoea in
all age groups (children: 36% 310/852 vs. 17% 108/625,
OR = 2.74, 95%CI
2.13–3.51; adults: 46% 248/543 vs. 21%
83/390, OR = 3.11, 95%CI
2.31–4.18, respectively,
P = 0.001 for both comparisons, figure 5, table
S3). Regarding other gastro-intestinal adverse events, DP was
significantly better tolerated than AS+AQ, AS+SP, or MAS3
(P<0.040 for all comparisons) but was not different compared to AL
(only for late vomiting). In adults the risk of nightmare
(P = 0.028) and sleep disturbances
(P = 0.003) was lower in the DP group than
in the MAS3 group. The risk of dermatological events
(P = 0.002), dizziness, palpitation, and
muscle pain in all ages was also lower than in the MAS3 group
(P<0.010 for all comparisons). The risks of hearing disturbance
(tinnitus, or hearing problems) in adults treated with MAS3 was greater than
in the DP group (P = 0.001).
Figure 5
Note: the forest plot represents the risk of adverse event
appearance after the start of dihydroartemisinin-piperaquine
treatment in children (<15 y) and adults who did not present
this symptom on admission versus comparators in comparative studies.
The size of boxes is proportional to the number of patients included.
95% confidence intervals (CI) are calculated for the odds
ratio (OR).
Note: the forest plot represents the risk of adverse event
appearance after the start of dihydroartemisinin-piperaquine
treatment in children (<15 y) and adults who did not present
this symptom on admission versus comparators in comparative studies.
The size of boxes is proportional to the number of patients included.
95% confidence intervals (CI) are calculated for the odds
ratio (OR).The frequency of patients treated with DP and reporting at least one of the
24 adverse events analyzed was 57.2% (840/1,468, 95%CI
54.7–59.8); among them 38% reported one, and
26% two adverse events (without excluding patients under 5). The
total number of adverse events reported per patient was higher in older
patients (P = 0.001) and in anaemic
patients on admission (P = 0.020 after
correcting for age).The incidence of adverse events was significantly lower in DP recipients
compared to MAS3 recipients (on average by −59%,
95%CI −28 to −90%,
P = 0.001). More patients treated with MAS3
reported two or more AEs (67%, 454/675,
P = 0.034). In Rwanda, the risk of having
any adverse event was higher in the AQ+SP group
(OR = 2.19, 95%CI
1.35–3.57) and in the AS+AQ group
(OR = 1.90, 95%CI
1.15–3.12) compared to the DP group. No differences were detected
in Uganda in the AL group compared to the DP group.A child from Rwanda had a seizure and received a rescue treatment. Overall, 5
deaths occurred in DP groups, all of which were considered to be unrelated
to the treatment, except in Thailand where a 43-year-old woman who died from
severe malaria the day after entering the study, which might have been
related to a lack of efficacy of the drug. In Thailand, there were another 2
deaths: a 13-year-old girl who died on Day 7 from probable bacterial sepsis,
and a 21 year old male who died on Day 28 from gunshot wounds. In Laos, a
two year old child died on Day 37 from cerebral malaria after probable
reinfection. In Myanmar, one 11-year-old child died after developing fever
on Day 20 and had generalized seizures the next morning (Day 21). The
malaria smear was negative. In the comparator groups, one death occurred in
MAS3 groups in Thailand involving a malaria-smear negative 13-year-old boy,
who was clinically well by the third day of treatment. He was reported to
have deteriorated rapidly with worsening abdominal pain and distension,
jaundice, and anuria, and he died within a few hours.
viii) Plasmodium vivax and other species appearing during the follow-up
period
No difference was detected between DP groups and the comparator
(mefloquine-artesunate) in P. vivax recurrence rates
(P>0.05 for all comparisons). In Cambodia, Laos, Myanmar, and
Thailand, 265 patients receiving DP (28.8/100 person-days within 63 days)
had P. vivax parasitaemia detected during the follow-up
(figure 6). The
median (range) time to the P. vivax parasitaemia was 49
(14–63) days compared with 49 (28–63) days, in MAS3
groups. Patients with P. vivax on admission (mixed
infections) were at higher risk of having a second P. vivax
episode during the follow-up (HR = 1.70,
95%CI 1.15–2.51,
P = 0.008). Children were at increased risk
of P. vivax recurrence when compared to adults;
0–4 age group (HR = 2.85,
95%CI 1.81–4.48,
P = 0.001) and the 5–14 age group
(HR = 1.43, 95%CI
1.05–1.94, P = 0.024). In
patients who had mixed infections on admission, the median time to
P. vivax recurrence was 42 days (7–63),
significantly shorter than in patients presenting with a P.
falciparum monoinfection: 49 (16–70) days,
(P = 0.029). In Uganda patients treated
with DP had a lower risk of recurrent parasitaemia due to P.
malariae and P. ovale species compared to
patients treated with AL (5.2% versus 0.9%,
P = 0.001)[10].
Patients receiving DP in Cambodia, Laos, Myanmar, and Thailand who
had P. vivax parasitaemia detected during the
follow-up.
Discussion
Since initial deployment in 1994 of the mefloquine-artesunate (MAS3) combination to
treat P. falciparum malaria along the Thai-Myanmar border, there
has been increasing use of ACTs throughout the malaria affected world.
Dihydroartemisinin-piperaquine (DP) is a relatively new and very promising fixed
dose ACT which has been extensively evaluated in the past few years. This analysis
of 3,547 patients (1,814 of whom received DP) in randomized comparative clinical
trials includes 7 of the 22 published studies (until December 2008), but is broadly
representative as it comprises a wide patient age range and derives from areas of
widely differing intensity of malaria transmission. It is the first individual
patient data set compiled prospectively, based on randomized comparisons in studies
of generally similar overall design. It includes half (49%, 1,814/3,678)
of all the patients treated with DP in published clinical trials with parasite
genotyping corrected results and reports 43% (1,814/4,212) of all
patients included in published studies to date.To present the results of this analysis of individual patient data we have used a
method similar to that used for a meta-analysis of trials (for instance in
Cochrane's review) with graphical representation of risks, recommended for
communicating in medical research [22]. Compared to a “conventional”
meta-analysis from published studies, the analysis of individual patient level data
increases statistical power by facilitating analytical practice, and enables
standardized estimates of drug efficacy across different studies.In the 12 different African and Asian sites with varying levels of background
antimalarial drug resistance, DP was well tolerated and highly efficacious. Like all
ACTs DP produces rapid therapeutic responses with swift resolution of symptoms and
fever and clearance of parasitaemia. Efficacy (PCR corrected) exceeded
96% in all sites except one in Rwanda, where no food was co-administered
with the drug. Treatment with DP was associated with lower risks of overall
recurrence (P = 0.001), recrudescence
(P = 0.001), and new infections
(P = 0.001) compared with the comparator drugs. The
superiority of DP was demonstrated in Rwanda, Uganda and Thailand against the local
current first-line treatments. This excellent efficacy and tolerability profile
suggests that DP could be considered as a potential alternative first-line
antimalarial treatment. This result based on studies of 1,814 adults and children
who received antimalarial treatment with DP, contrasts with the recently reported
finding of a study of 100 young children in Papua New Guinea [23]. DP was not
administered with food in that study, a factor that could contribute to lower oral
piperaquine absorption, and reduce therapeutic efficacy [24]. High levels of
chloroquine resistance were considered a possible explanatory factor, although
levels of chloroquine resistance were also very high in the study sites in this
multi-center analysis. PCR corrected efficacy in adjacent Papua with DP treatment
was over 95%, although this trial enrolled adults and children [25]. The
reasons for lower efficacy in Rukara, Rwanda are unclear but consistent with the
lower efficacy of other ACTs such as amodiaquine-artesunate at this site compared to
other Rwandan sites [26] and could also be related with the fact that DP
was not administered with food. The superior protective effect of DP against
reinfection and suppression of vivax relapses compared with the other drugs
presumably results from the long terminal half-life of piperaquine. Suppression of
reinfection provides longer disease free intervals but at the expense of increased
selection pressure for resistance to piperaquine compared with more rapidly
eliminated partner drugs.DP was less potent than mefloquine–artesunate in suppressing
gametocytaemia. Similar results were also observed in Kenya in comparison with AL
[27],
and in Peru compared to MAS3 [28]. Taken together these results indicate that the
reduction in gametocytaemia, an important pharmacodynamic advantage of ACTs, is less
pronounced with DP than with other ACTs. This could be related to the relatively
lower dose of DHA (2.5 mg/kg/day) compared to the dose of artesunate in the
comparators (4 mg/kg/day). But in our analysis we found no relationship between the
dose of DHA received by the patients in the DP arms and the clearance of
gametocytaemia. Prolonged gametocytemia has been proposed as an early sign of the
emergence of drug resistance [29]. This might be a concern given the poorer
gametocytocidal effects of DP. However the gametocyte carriage rate remained low,
and the gametocyte clearance was fast. A relatively few patients had detectable
gametocytemia during the studies, which reflects the potent gametocytocidal
properties of the artemisinin derivatives.DP was effective in treating non-P. falciparum species
co-infections. Unlike P. falciparum infections, recurrence of
P. vivax (either relapses or failures) cannot be reliably
distinguished from a new infection [30]. Mixed infections are common. Approximately one
third of acute falciparum malaria infections in the South-East Asian region are
followed by a vivax malaria relapse. In trials with 63 days follow-up the recurrent
episode of vivax malaria in patients with mixed infections on admission occurred
slightly earlier (6 weeks) than new vivax appearances in patients with a falciparum
mono-infection (7 weeks). Thus, the first relapse is suppressed by DP, comparable to
the effect of chloroquine on sensitive P. vivax strains [31].The higher risk of treatment failure in children treated with DP compared with adults
is similar to the pattern seen with other antimalarial drugs, and presumably results
both from lower immunity and lower blood piperaquine concentrations. The shorter
time to P. vivax reappearance in children would also support a
pharmacokinetic explanation. The Day 7 piperaquine level is a useful measure of drug
exposure. Young children have lower piperaquine levels on Day 7 and higher treatment
failure rates than older children and adults [4], [25]. In a recently reported
population pharmacokinetic study from Thailand, there were therapeutically relevant
pharmacokinetic differences between different age groups. Children had a smaller
central volume of distribution, a shorter distribution half-life (t1/2,
α), and a more rapid fall in initial PQ plasma concentrations
compared to the population mean profile [4]. Studies indicated
lower plasma piperaquine concentration in children compared to adults in Papua,
Indonesia [25] and higher clearance in children in Vietnam [32]. Taken
together these data argue for higher weight adjusted doses in children compared with
adults. This would also have the advantage of providing a larger dose of
dihydroartemisinin. Further studies in young children to optimize the dose of DP are
needed.The risk of early vomiting of DP was lower than following AQ+SP in Rwanda
(P = 0.001). No differences were observed with the
other comparator treatments. Early vomiting was more frequent in young children,
although it was not a risk factor for treatment failure, presumably because these
children were re-dosed successfully after vomiting the drug.The DP safety profile has been excellent in all published series. The overall safety
analysis showed that the risk of the most common adverse events was significantly
lower following DP treatment than in the comparator arms in both children
(<15 years old) and adults. Adverse events were often related to the disease
itself (particularly neurological and gastro-intestinal AEs), although diarrhea was
approximately twice as common following DP than with MAS3.The use of common protocols for data collection to assess antimalarial drug efficacy
and tolerability allows combination of these data into larger international
databases which can give us more information on the safety and efficacy of these
drugs in different patient groups [33]. While methods for assessing antimalarial drug
efficacy are well standardized there is little uniformity in safety reporting in
antimalarial drug studies, a problem which needs to be addressed.DP is not yet recognized internationally and its use has been limited by its
regulatory status. The formulation used in the trials was donated by Holley and
manufactured according to Chinese SFDA Good Manufacturing Practice (GMP) standards.
Nevertheless, differences in efficacy might be related to the variability in the
composition of the study drug.This antimalarial combination is currently under evaluation by the WHO
pre-qualification process. DP is clearly an important new antimalarial drug. It is
well tolerated, highly effective and safe. The higher rates of gametocytaemia
compared with other ACTs and lower piperaquine levels early in the terminal
elimination phase observed in children suggest that dosage may have to be increased
in this important patient group.(for figure 2):
Recurrences (PCR uncorrected) and recrudescences (PCR corrected) comparing
the risks in the dihydroartemisinin-piperaquine group versus the comparator
arms by drug and country of study. *Overall number of failures does
not add up because two comparators were used in Rwanda. Note: the forest
plot represents the risk of parasite reappearance (PCR corrected; i.e.
recrudescence, and not corrected i.e. recrudescence+novel
infection) of DP versus comparators in comparative studies. Groups size are
equivalent except in Thailand where the DP group was twice as large
(N = 686). Endpoints were assessed on Day
28 in Rwanda, Day 42 in Laos, Myanmar, and Uganda, and Day 63 in Cambodia,
and Thailand. Overall results were stratified by site, and drugs. HR: hazard
ratio(0.07 MB DOC)Click here for additional data file.(for figure 3): Risks of
clearing gametocytaemia by Day 14 in patients with gametocytaemia on
admission, dihydroartemisinin-piperaquine (DP) group versus comparators arms
by drug and country of study. HR; hazard ratio, CI; confidence interval.
(NC): not computable because of the day of clearance not available.(0.05 MB DOC)Click here for additional data file.(for figure 5): Day 28
adverse event risks for ‘treatment’ DP versus controls
(comparators)Note: The risk of adverse event appearance after the start of
dihydroartemisinin-piperaquine treatment in children (<15 y) and
adults who did not present this symptom on admission versus comparators in
comparative studies. 95% confidence intervals (CI) are calculated
for the odds ratio (OR)(0.12 MB DOC)Click here for additional data file.
Authors: Corine Karema; Caterina I Fanello; Chantal van Overmeir; Jean-Pierre van Geertruyden; Walli van Doren; Daniel Ngamije; Umberto D'Alessandro Journal: Trans R Soc Trop Med Hyg Date: 2006-06-12 Impact factor: 2.184
Authors: Trong Chinh Nguyen; Ngoc Quang Nguyen; Xuan Thanh Nguyen; Dai Bui; Thomas Travers; Michael D Edstein Journal: Am J Trop Med Hyg Date: 2008-10 Impact factor: 2.345
Authors: J Tarning; E A Ashley; N Lindegardh; K Stepniewska; L Phaiphun; N P J Day; R McGready; M Ashton; F Nosten; N J White Journal: Antimicrob Agents Chemother Date: 2008-01-07 Impact factor: 5.191
Authors: R N Price; A R Hasugian; A Ratcliff; H Siswantoro; H L E Purba; E Kenangalem; N Lindegardh; P Penttinen; F Laihad; E P Ebsworth; N M Anstey; E Tjitra Journal: Antimicrob Agents Chemother Date: 2007-09-10 Impact factor: 5.191
Authors: Abel Kakuru; Jane Achan; Mary K Muhindo; Gloria Ikilezi; Emmanuel Arinaitwe; Florence Mwangwa; Theodore Ruel; Tamara D Clark; Edwin Charlebois; Philip J Rosenthal; Diane Havlir; Moses R Kamya; Jordan W Tappero; Grant Dorsey Journal: Clin Infect Dis Date: 2014-04-23 Impact factor: 9.079
Authors: Darren J Creek; Victor Bigira; Shelley McCormack; Emmanuel Arinaitwe; Humphrey Wanzira; Abel Kakuru; Jordan W Tappero; Taylor G Sandison; Niklas Lindegardh; Francois Nosten; Francesca T Aweeka; Sunil Parikh Journal: J Infect Dis Date: 2013-02-27 Impact factor: 5.226
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6