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Transcript 
ORIGINAL INVESTIGATION
Cardiac Function in 5-Year Survivors
of Childhood Cancer
A Long-term Follow-up Study
Helena J. van der Pal, MD; Elvira C. van Dalen, MD, PhD; Michael Hauptmann, MSc, PhD; Wouter E. Kok, MD, PhD;
Huib N. Caron, MD, PhD; Cor van den Bos, MD, PhD; Foppe Oldenburger, MD, PhD; Caro C. Koning, MD, PhD;
Flora E. van Leeuwen, MSc, PhD; Leontien C. Kremer, MD, PhD
Background: Childhood cancer survivors (CCSs) have
an increased risk of morbidity and mortality. We evaluated the prevalence and determinants of left ventricular
(LV) dysfunction in a large cohort of long-term CCSs
treated with different potentially cardiotoxic therapies.
Methods: The study cohort consisted of all adult 5-year
CCSs who were treated with potentially cardiotoxic therapies and who visited our late effects outpatient clinic. Echocardiography was performed in patients who had received anthracyclines, cardiac irradiation, high-dose
cyclophosphamide, or high-dose ifosfamide. Detailed
treatment data were registered. Both multivariate linear
and logistic regression analyses were performed.
Results: Of 601 eligible CCSs, 525 (87%) had an echocardiogram performed, of which 514 were evaluable for
assessment of the LV shortening fraction (LVSF). The median overall LVSF in the whole group of CCSs was 33.1%
(range, 13.0%-56.0%). Subclinical cardiac dysfunction
L
Author Affiliations:
Departments of Medical
Oncology (Dr van der Pal),
Pediatric Oncology
(Drs van der Pal, van Dalen,
Caron, van den Bos, and
Kremer), Cardiology (Dr Kok),
and Radiation Oncology
(Drs Oldenburger and Koning),
Emma Children’s
Hospital/Academic Medical
Center, Amsterdam,
the Netherlands; and
Departments of Bioinformatics
and Statistics (Dr Hauptmann)
and Epidemiology
(Dr van Leeuwen), Netherlands
Cancer Institute, Amsterdam.
(LVSF⬍30%) was identified in 139 patients (27%). In a
multivariate linear regression model, LVSF was reduced
with younger age at diagnosis, higher cumulative anthracycline dose, and radiation to the thorax. High-dose cyclophosphamide and ifosfamide were not associated with
a reduction of LVSF. Vincristine sulfate was associated with
a nonsignificant decrease of cardiac function (P=.07). Epirubicin hydrochloride was as cardiotoxic as doxorubicin
when corrected for tumor efficacy, and daunorubicin hydrochloride seemed less cardiotoxic.
Conclusions: A high percentage (27%) of young adult
CCSs have an abnormal cardiac function. The strongest
predictors of subclinical cardiac dysfunction are anthracycline dose, cardiac irradiation, and younger age at diagnosis. There is a suggestion that daunorubicin is less
cardiotoxic than other anthracyclines.
Arch Intern Med. 2010;170(14):1247-1255
ONG-TERM SURVIVAL OF CHILD-
hood cancer has improved
considerably, from 20% in the
1940s,1 to 70% to 80%2-5 at
present, owing to chemotherapy, radiotherapy, supportive therapy,
and combined modality treatment. Unfortunately, improved survival is accompanied by the occurrence of late treatment effects.6-8 Cardiovascular disease (CVD) and
cardiac mortality are among the most serious late effects. Several populationbased studies observed a 6- to 8-fold increased mortality owing to CVD among
childhood cancer survivors (CCSs) compared with the general population.9-11
Anthracycline- and radiation-induced
CVD are recognized as important longterm complications after childhood cancer.7,8 Anthracyclines are among the most
effective antineoplastic drugs for childhood cancer and are still widely used in
about half the patients. The use of radio-
(REPRINTED) ARCH INTERN MED/ VOL 170 (NO. 14), JULY 26, 2010
1247
therapy as part of childhood cancer treatment has decreased over time. Heart damage
can become manifest as either subclinical
or clinical cardiac dysfunction. The frequency of anthracycline-induced cardiac
dysfunction varies across studies, depending on follow-up time, attained age, population studied, and definitions used, ranging from 0% to 57% for subclinical cardiac
dysfunction and from 0% to 16% for clinical CVD.12-17 Reported frequencies of radiation-induced clinical CVD vary by follow-up time and concurrent chemotherapy,
whereas the frequency of subclinical radiation-induced damage is largely unknown.
Most studies focus on radiation-induced
cardiac mortality, which is increased 22to 68-fold compared with the general population.18 Suspected risk factors for treatment-induced CVD are cumulative dose
and type of anthracycline, radiation dose,
age at diagnosis, and female sex.12,14,18 However, results are not univocal across stud-
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ies.19-24 Furthermore, the impact of other potentially cardiotoxic drugs, like high-dose cyclophosphamide or
ifosfamide, has not been examined in large studies.25-27
In this study we evaluated the prevalence of echocardiographic left ventricular (LV) dysfunction and associated risk factors in a large cohort of long-term CCSs treated
with different potentially cardiotoxic therapies.
METHODS
PATIENTS
In 1996, the Outpatient Clinic for Late Effects of Childhood Cancer for adult CCSs was established in the Emma Children’s Hospital/Academic Medical Center (EKZ/AMC), Amsterdam, the
Netherlands. All adult 5-year CCSs were traced using the Childhood Cancer Registry of the EKZ/AMC, which was established
in 1966 and maintains data on diagnosis, treatment, last known
medical status, and follow-up of all patients treated for childhood cancer in the EKZ/AMC. All CCSs surviving 5 years or more
were invited to participate and enrolled into prospective follow-up study protocols tailored to previous diagnosis and treatment. These protocols were developed by health care professionals based on consensus. The CCSs gave informed consent
for data collection. The CCSs who received treatment with anthracyclines, cardiac irradiation (thorax, spine, left or whole upper abdomen, total body irradiation [TBI]), and/or high-dose cyclophosphamide or ifosfamide (ie, total cumulative dose ⬎10 g/m2
or ⱖ1 g/m2 per course) were enrolled in the cardiotoxic effects
screening protocol. Five-year CCSs were eligible for the present
study if they were treated between January 1966 and August 1997,
qualified for the cardiotoxic effects screening protocol, and visited our outpatient clinic for adult CCSs for the first time after
the age of 18 years between January 1996 and April 2004.
DATA COLLECTION
Data were extracted directly from the Childhood Cancer Registry database or collected from the medical records and the digital hospital information system, including: birth date, sex, tumor diagnosis, date of start of cardiotoxic treatment, cumulative
doses of anthracyclines (doxorubicin, daunorubicin hydrochloride, epirubicin hydrochloride), cyclophosphamide, ifosfamide,
cardiac irradiation, date of last follow-up, date and cause of death,
signs and symptoms of heart failure, and echocardiography data.
CARDIAC ASSESSMENT
The cardiotoxic effects screening protocol comprised a full medical assessment and an echocardiography on the same day. All
eligible CCSs underwent a clinical cardiac assessment by the medical oncologist to evaluate signs and symptoms of heart failure.
Clinical heart failure (CHF) was defined as congestive heart failure not attributable to other known causes, like direct medical
effects of the tumor, septic shock, or renal failure. We defined
congestive heart failure as the presence of the following: dyspnea, pulmonary or peripheral edema, and/or exercise intolerance, which were treated with anticongestive therapy (according to the New York Heart Association criteria).28 Patients were
examined by echocardiography at least once. The LV systolic function was assessed by means of standard M-mode echocardiography with a concurrent electrocardiogram. The LV shortening
fraction (LVSF) was calculated using the formula: LVSF (%)=
[(LVDD–LVSD)/LVDD]⫻100%, where LVDD is the LV diastolic diameter measured at the start of the QRS complex and
LVSD is the LV systolic diameter. The LVSF correlates to ejec-
tion fraction (EF) as follows: an LVSF of 30% equals an EF of
50%, an LVSF of 25% equals an EF of 45%.29 The measurements of LVSF were performed by trained specialists from our
department of cardiology, blinded to the patient’s treatment, according to a follow-up protocol specific for CCSs. Measurements of LVSF were performed multiple times, diminishing the
risk of intraobserver variability. For each patient, the first evaluable echocardiogram was used as the outcome measurement for
the LVSF. We chose the first echocardiography as the most unbiased measurement possible, to avoid both selection bias and
confounding by treatment. Survivors with an LVSF of less than
30% received a different additional follow-up schedule and possible treatment of CVD than those with an LVSF within normal
limits. Treatment could even influence the prevalence and course
of cardiac dysfunction (ie, treatment with angiotensin-converting enzyme [ACE] inhibitors could improve cardiac function and slow progression to overt clinical CVD).30
STATISTICAL ANALYSIS
The main outcomes of interest were the mean values of the LVSF
across all available first measurements and the number of patients with an abnormal first LVSF (defined as an LVSF⬍30%)
according to the Common Terminology Criteria for Adverse
Events (CTCAE), version 3.0.29 The following potential determinants of the LVSF were evaluated: sex, age at cancer diagnosis, time since cancer diagnosis, body mass index (BMI) at
the time of the echocardiogram, cumulative doses of doxorubicin, epirubicin, daunorubicin, all anthracyclines combined,
cyclophosphamide, and ifosfamide and total radiation dose to
each of the 4 fields involving the heart.
Using multivariate linear regression models, changes in LVSF
(percentage points) were estimated for categories of each variable compared with a reference category. We generally used
the low-dose category as the reference instead of the zerodose category to avoid confounding because all patients were
exposed to potentially cardiotoxic treatments; hence, patients
not exposed to anthracyclines were always exposed to radiotherapy or high-dose cyclophosphamide or ifosfamide.
We also examined determinants of an abnormal LVSF using
multivariate logistic regression models to estimate the odds ratio (OR). Tests of trend were based on the corresponding continuous variable.
We evaluated whether the relationship between a certain
treatment and LVSF was modified by another factor (eg, calendar year of treatment or time since diagnosis). Heterogeneity of effects across categories of the potential effect modifier was assessed based on goodness-of-model fit. Differences
in radiation- or anthracycline-related risks by calendar year of
treatment could indicate calendar period effects, while differences by time since diagnosis would indicate latency. Because
detailed information on anthracycline and radiation dose was
available and included in the analysis, any residual effect of calendar period of treatment was considered small. We therefore
focused on modification of radiation- or anthracycline-related
risks by time since diagnosis.
To address interaction between anthracyclines and radiotherapy, we evaluated whether the anthracycline dose effect was
homogeneous across groups of patients whose radiotherapy
fields involved different parts of the body. Where we observed
strong evidence of an association (ie, significant trends among
all patients and among exposed patients only), we evaluated
the shape of the dose-response curve parametrically by adding
a quadratic term to the linear regression model, as well as nonparametrically by using relatively narrow categories of dose.
To assess the cardiotoxic potency of the different anthracycline derivates, we analyzed the effect of the cumulative doses
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Table 1. Number of Patients With Echocardiogram by Left Ventricular Shortening Fraction (LVSF) and Patient Characteristics
Characteristic
Number
Sex
Male
Female
Age at diagnosis, y
Median (range)
0-5
⬎5-10
⬎10-15
⬎15
Diagnosis
ALL
ANLL
Hodgkin
Non-Hodgkin
Nephroblastoma
Rhabdomyosarcoma
Ewing sarcoma
Osteosarcoma
CNS tumor
Germ cell tumor
Neuroblastoma
Other
Anthracyclines
Cumulative dose, median (range), mg/m2
1-150
151-300
301-450
⬎450
Dose missing
Anthracycline derivates
Doxorubicin only
Daunorubicin hydrochloride only
Epirubicin hydrochloride only
Doxorubicin ⫹daunorubicin
Doxorubicin ⫹epirubicin
Daunorubicin ⫹ epirubicin
Cyclophosphamide
High-dose, ⬎10 g/m2
Cumulative dose, median (range), g/m2
Dose missing
Patients With LVSF
ⱖ30%, No. (%)
Patients With LVSF
⬍30%, No. (%)
Total No. of Patients
With Echocardiogram (%)
375
139
525 (87.4) a
192 (51.2)
183 (48.8)
81 (58.3)
58 (41.7)
277 (52.8)
248 (47.2)
8.7 (0.1-17.8)
97 (25.9)
118 (31.5)
121 (32.3)
39 (10.4)
9.6 (0.4-17.2)
35 (25.2)
43 (30.9)
50 (36.0)
11 (7.9)
8.9 (0.1-17.8)
135 (25.7)
164 (31.2)
175 (33.3)
51 (9.7)
51 (13.6)
13 (3.5)
39 (10.4)
74 (19.7)
37 (9.9)
47 (12.5)
18 (4.8)
32 (8.5)
34 (9.1)
9 (2.4)
12 (3.2)
9 (2.4)
248 (66.1)
240.0 (4-720)
70 (18.7)
104 (27.8)
52 (13.9)
21 (5.6)
1 (0.3)
16 (11.5)
1 (0.7)
17 (12.2)
35 (25.2)
18 (12.9)
21 (15.1)
8 (5.8)
12 (8.6)
5 (3.6)
1 (0.7)
0
5 (3.6)
107 (77.0)
350.0 (75-720)
8 (5.8)
43 (30.9)
35 (25.2)
19 (13.7)
2 (1.4)
153 (40.8)
30 (8.0)
35 (9.3)
19 (5.1)
9 (2.4)
2 (0.5)
160 (42.7)
37 (23.1) b
5.8 (0.8-26.8)
5 (3.1) b
74 (53.2)
3 (2.2)
19 (13.7)
7 (5.0)
4 (2.9)
0
73 (52.5)
23 (31.5) b
7.2 (0.3-19.5)
4 (5.5) b
69 (13.1)
14 (2.7)
57 (10.9)
109 (20.8)
56 (10.7)
68 (13.0)
29 (5.5)
46 (8.8)
39 (7.4)
11 (2.1)
13 (2.5)
14 (2.7)
361 (68.8)
250.0 (33-720)
79 (15.0)
147 (28.0)
91 (17.3)
41 (7.8)
3 (0.6)
230 (43.8)
34 (6.5)
56 (10.7)
25 (4.8)
14 (2.7)
1 (1.9)
237 (45.1)
61 (25.7) b
7.7 (0.3-26.8)
10 (4.2) b
(continued)
of specific anthracyclines separately from each other. We tested
the heterogeneity of the results for the different derivates. We
corrected the dose of epirubicin compared with doxorubicin
and daunorubicin, because 90 mg/m2 of epirubicin hydrochloride is as effective against cancer as 60 mg/m2 of doxorubicin
or daunorubicin hydrochloride. We evaluated the change in
LVSF (linear model) and the OR for low LVSF (logistic model)
per 60 and per 90 mg/m2 of epirubicin hydrochloride.10,31,32 Statistical analyses were performed using SPSS software for Windows (version 16.0.2; SPSS Inc, Chicago, Illinois), SAS software (version 9.1; SAS Institute Inc, Cary, North Carolina), and
Epicure software (version 1.4; Hirosoft, Seattle, Washington).
RESULTS
Between January 1966 and August 1997, 3310 patients
were treated for childhood cancer in the EKZ/AMC. Of
those, 1535 survived their cancer for more than 5 years,
but 229 were not yet 18 years old during the study pe-
riod and were excluded. Of the remaining 1306 CCSs,
735 patients were treated with anthracyclines, cardiac irradiation, high-dose cyclophosphamide, and/or ifosfamide. Sixty 5-year CCSs died before the start of our outpatient clinic (ie, the start of our study), 1 of CHF. Thus,
675 CCSs were eligible for inclusion, and 601 visited the
outpatient clinic (89%). The other 74 CCSs did not visit
the outpatient clinic for the following reasons: the CCS
moved abroad (n = 9), visited another Dutch hospital
(n = 6), died before the visit (n = 22), was lost to follow-up (n=6), or did not show up at follow-up (n=31).
None of the 22 CCSs who died before they could visit
the outpatient clinic died because of CVD.
Table 1 lists the characteristics of the study population. Of the 601 patients, 525 had an echocardiogram
(87.4%). Seventy-six patients did not have an echocardiogram for various reasons: they had had echocardiography elsewhere (n=20), had planned to have the echo-
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Table 1. Number of Patients With Echocardiogram by Left Ventricular Shortening Fraction (LVSF) and Patient Characteristics
(continued)
Characteristic
Ifosfamide
High dose, ⬎10 g/m2
Cumulative dose, median (range), g/m2
Dose missing
Vincristine sulfate
Radiotherapy
Cumulative dose, median (range), Gy
Dose missing
Localization RTX
Thorax
Abdomen
Spine
TBI
Age at screening, y
Attained age, median (range), y
18-20
⬎20-25
⬎25-30
⬎30-35
⬎35-40
⬎40
Time since diagnosis, y
Median (range)
5-10
⬎10-15
15-20
⬎20-25
⬎25
Calendar year of treatment
1960-1970
1970-1980
1980-1990
After 1990
Patients With LVSF
ⱖ30%, No. (%)
Patients With LVSF
⬍30%, No. (%)
Total No. of Patients
With Echocardiogram (%)
56 (14.9)
45 (80.4) b
18.0 (3.0-84.0)
0
298 (79.8)
134 (35.7)
25.0 (7.5-60.0)
3 (2.2) b
26 (18.7)
22 (84.6) b
30.0 (4.0-132.0)
0
118 (84.9)
44 (31.7)
25.0 (7.5-45.0)
0
83 (15.8)
70 (84.3) b
35.7 (4.0-132.0)
0
416 (79.2)
184 (35.0)
25.0 (8.0-60.0)
3 (1.6) b
42 (31.3) b
34 (25.4) b
47 (35.1) b
11 (8.2) b
22 (50.0) b
13 (29.5) b
7 (15.9) b
2 (4.5) b
67 (36.4) b
49 (26.6) b
55 (29.9) b
13 (7.1) b
23.1 (18.0-47.1)
85 (22.7)
134 (35.7)
70 (18.7)
55 (14.7)
18 (4.8)
13 (3.5)
22.7 (18.0-39.1)
38 (27.3)
57 (41.0)
25 (18.0)
17 (12.2)
2 (1.4)
0
23.1 (18.0-47.1)
125 (23.8)
194 (37.0)
96 (18.3)
74 (14.1)
21 (4.0)
15 (2.9)
15.8 (5.1-40.3)
79 (21.1)
90 (24.0)
105 (28.0)
46 (12.3)
55 (14.7)
14.3 (5.9-31.5)
34 (24.5)
46 (33.1)
33 (23.7)
19 (13.7)
7 (5.0)
15.4 (5.1-40.3)
115 (21.9)
138 (26.3)
140 (26.7)
69 (13.1)
63 (12.0)
9 (2.4)
91 (24.3)
187 (49.9)
23.5 (23.5)
0
29 (20.9)
82 (59.0)
28 (20.1)
11 (2.1)
122 (23.2)
274 (52.2)
118 (22.5)
Abbreviations: ALL, acute lymphoblastic leukemia; ANLL, acute nonlymphoblastic leukemia; CNS, central nervous system; RTX, radiotherapy; TBI, total body
irradiation.
a Only 514 of the 525 echocardiograms were evaluable for assessment of the LVSF, therefore the number of patients with LVSF of 30% or higher and those with
LVSF lower than 30% add up to 514.
b Percentage of subpopulation.
cardiogram but not yet undergone it (n = 39), refused it
(n=15), or had died (n = 2). Patients with and without
an echocardiogram did not differ or did not differ substantially by cumulative anthracycline dose, age at diagnosis, sex, cardiac irradiation, cumulative cyclophosphamide or ifosfamide dose, time since diagnosis, and tumor
diagnoses. Six CCSs died after the first cardiac assessment owing to causes other than CVD.
Of the 525 echocardiograms, 514 were evaluable for
assessment of the LVSF. The median overall LVSF was
33.1% (range, 13.0%-56.0%). An LVSF of less than 30%
was identified in 139 patients (27.0%) at an attained age
of 23 years (Table 2). Two patients (1.4%) had an LVSF
of less than 15% (CTC-AE grade 3), 29 (22.3%) had an
LVSF of 15% to 23% (CTC-AE grade 2), and 108 (77.7%)
had an LVSF of 24% to 29% (CTC-AE grade 1). An abnormal LVSF was most common among patients who received combination therapy: anthracyclines with either
cyclophosphamide or ifosfamide (34.1%), or cardiac irradiation (28.1%) and in the group with cardiac irradiation and either cyclophosphamide or ifosfamide (30.8%).
Seven CCSs (1.3%) were diagnosed as having CHF during cancer treatment. All were treated with anticongestive therapy and fully recovered. At the time of evaluation, none of these patients had symptoms or signs of CHF.
Three patients did not use medication; 4 were treated with
ACE inhibitors, digoxin, or carnitine. These patients were
included in the echocardiographic analyses; all but 1 had
an abnormal LVSF.
Results of the multivariate linear regression model are
shown in Table 3. Age at diagnosis, time since diagnosis, cumulative anthracycline dose, and thoracic radiotherapy were significantly associated with a change in LVSF.
The use of vincristine was not significantly associated with
a decrease in LVSF (P=.07). Adding BMI to the regression model did not substantially improve the goodnessof-fit, nor did it substantially change the regression coefficients for other variables in the model (results not shown).
Using multivariate logistic regression to model the effect
of these potential determinants on subclinical cardiac dysfunction led to largely similar results as the linear regression analyses on continuous LVSF (Table 3).
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Table 2. Echocardiographic Findings and Clinical Assessment
Parameter
No.
LVSF Mean,
(Range)
LVSF⬍ 30%,
No. (%)
CHF Cases,
No. (%)
All evaluable echocardiograms
Treatment
Anthracycline only
RTX only
Ifosfamide only
Cyclophosphamide only
Anthracycline and other chemotherapy a
Anthracycline and RTX and other chemotherapy a
RTX and other chemotherapy a
Cyclophosphamide and ifosfamide
Sex
Male
Female
Age at diagnosis, y
0-5
⬎5-10
⬎10-15
⬎15
Cumulative dose anthracyclines, mg/m2
1-150
151-300
301-450
⬎450
Cumulative cyclophosphamide dose, g/m2
ⱕ10
⬎10
Cumulative ifosfamide dose, g/m2
ⱕ10
⬎10
Vincristine sulfate
Yes
No
Radiotherapy
Thorax
Abdomen
Spine
TBI
Cumulative radiotherapy dose, Gy
ⱕ30
⬎30
Time since diagnosis, y
5-10
⬎10-15
⬎15-20
⬎20-25
⬎25
Calendar year of treatment
1960-1970
1970-1980
1980-1990
1990-1997
514
33.1 (13.0-56.0)
139 (27.0)
7 (1.3)
88
107
28
10
209
58
13
1
34.2 (24.0-54.0)
34.4 (13.0-51.2)
35.6 (23.0-44.9)
35.4 (26.7-47.2)
32.2 (14.0-56.0)
31.4 (20.0-50.0)
29.1 (21.0-38.0)
38.0 (NA)
17 (19.3)
22 (20.6)
5 (17.9)
1 (10.0)
72 (34.1)
18 (28.1)
4 (30.8)
0
0
0
0
0
5 (2.4)
2 (5.3)
0
0
273
241
32.8 (13.0-53.8)
33.5 (20.0-56.0)
81 (29.7)
58 (24.1)
1 (0.4)
6 (2.5)
132
161
171
50
32.8 (14.0-53.8)
32.9 (19.0-56.0)
33.1 (16.0-51.2)
34.8 (13.0-54.0)
35 (26.5)
43 (26.2)
50 (28.6)
11 (21.6)
2 (1.5)
3 (1.8)
2 (1.1)
1 (2.0)
79
147
91
41
34.0 (20.0-56.0)
32.0 (20.7-53.8)
30.2 (16.0-44.0)
30.0 (14.0-42.0)
8 (5.8)
43 (30.9)
35 (25.2)
19 (13.7)
0
3 (1.9)
2 (2.1)
2 (4.3)
164
60
32.8 (14.0-56.0)
30.4 (16.0-50.0)
46 (28.0)
23 (38.3)
1 (0.6)
3 (4.9)
13
69
33.1 (22.9-43.6)
33.1 (18.0-44.9)
2 (15.4)
24 (34.8)
0
2 (2.9)
416
98
32.7 (13.0-56.0)
34.7 (21.0-51.2)
118 (28.4)
21 (21.4)
6 (1.3)
1 (1.0)
64
47
54
13
32.5 (13.0-50.0)
32.8 (16.0-51.2)
34.4 (25.0-47.0)
32.5 (22.9-38.0)
22 (34.4)
13 (27.7)
7 (13.0)
2 (15.4)
1 (1.5)
1 (2.0)
1 (1.8)
0
56
119
35.3 (21.0-51.2)
32.1 (13.0-50.0)
7 (12.5)
37 (31.1)
0
3 (2.4)
113
136
138
66
61
33.1 (20.0-54.0)
32.1 (13.0-56.0)
33.1 (14.0-53.8)
33.1 (16.0-47.2)
35.6 (21.0-51.2)
34 (30.1)
46 (33.8)
33 (23.9)
20 (30.3)
6 (9.8)
1 (0.9)
4 (2.9)
2 (1.4)
0
0
9
120
269
116
40.0 (32.0-51.2)
33.3 (16.0-49.1)
32.8 (13.0-56.0)
33.2 (16.7-54.0)
0
29 (24.2)
82 (30.5)
28 (24.1)
0
0
5 (1.8)
2 (1.7)
Abbreviations: CHF, congestive heart failure; LVSF; left ventricular shortening fraction; NA, not applicable; RTX, radiotherapy; TBI, total body irradiation.
SI conversion factor: To convert gray to rads, multiply by 100.
a Other chemotherapy indicates either cyclophosphamide or ifosfamide or a combination of both.
With regard to specific anthracycline derivates,
doxorubicin and epirubicin, but not daunorubicin,
were significantly associated with a reduced LVSF
(Table 4). Doxorubicin seemed to be the most potent
determinant of LVSF, although the magnitude of effects
did not differ significantly. However, taking into account that epirubicin is usually administered at a 1.5fold higher dose than doxorubicin and daunorubicin,
we observed about a 1.3-fold increased OR for cardiac
dysfunction associated with either doxorubicin, 60 mg/
m2, or epirubicin hydrochloride, 90 mg/m2. The observed association for daunorubicin was weaker with a
significant trend among patients who received daunorubicin but not among all patients. There was no evidence of heterogeneity of the magnitude of effects of
specific anthracycline derivates.
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Table 3. Multivariate Linear Regression Analysis of LVSF and Multivariate Logistic Regression Analysis
of Subclinical Cardiac Dysfunction (LVSF ⬍30%)
LVSF ⬍ 30%
Change in LVSF
␤ (95% CI)
Risk Factor
Sex (male vs female)
Age at diagnosis, y
0-5
⬎5-10
⬎10-15
⬎15
Time since diagnosis, y
5-10
10-15
15-20
20-25
⬎25
Vincristine sulfate (yes vs no)
Cum dose anthracycline, mg/m2
No
1-150
151-300
301-450
⬎450
Cyclophosphamide, g/m2
No
ⱕ10
⬎10
Ifosfamide, g/m2
No
ⱕ10
⬎10
Radiotherapy b
None
Thorax
Abdomen
Spine
TBI
Homogeneity P value c
P Value for
Trend a
0.77 (−0.27 to 1.80)
0.73 (0.47 to 1.13)
−3.55 (−5.80 to −1.30)
−1.95 (−4.03 to 0.12)
−1.32 (−3.21 to 0.58)
0 [Reference]
2.94 (1.08 to 8.02)
1.64 (.67 to 4.01)
1.45 (0.64 to 3.28)
1 [Reference]
.008
0 [Reference]
0.41 (−1.25 to 2.08)
1.71 (−0.07 to 3.50)
2.07 (−0.08 to 4.22)
4.86 (2.28 to 7.43)
−1.30 (−2.88 to 0.27)
0.54 (−2.89 to 3.96)
0 [Reference]
0.66 (−3.06 to 4.39)
0 [Reference]
−3.67 (−5.54 to −1.79)
−3.54 (−5.87 to −1.20)
−0.79 (−2.92 to 1.24)
−0.53 (−4.01 to 2.94)
.048
.01
2.87 (1.09 to 7.59)
1 [Reference]
3.98 (1.58 to 10.01)
7.77 (2.85 to 21.22)
10.58 (3.35 to 33.40)
⬍.001 (⬍.001)
0.38 (−1.13 to 1.90)
0 [Reference]
−0.85 (−2.91 to 1.22)
.049
1 [Reference]
0.80 (0.41 to 1.54)
0.40 (0.18 to 0.86)
0.48 (0.19 to 1.23)
0.11 (0.03 to 0.42)
1.47 (0.71 to 3.05)
⬍.001
−0.65 (−2.64 to 1.33)
0 [Reference]
−1.93 (−3.71 to −0.15)
−4.24 (−6.32 to −2.16)
−5.38 (−7.98 to −2.79)
P Value for Trend a
OR (95% CI)
⬍.001 (⬍.001)
.11 (.14)
1.01 (0.52 to 1.99)
1 [Reference]
1.01 (0.45 to 2.26)
.79 (.54)
.80 (.70)
1.25 (0.23 to 6.67)
1 [Reference]
1.50 (0.26 to 8.82)
.68 (.29)
.006 (.21)
.08 (.07)
.96 (.70)
.98 (.19)
.09 (.42)
1 [Reference]
3.49 (1.60 to 7.61)
2.66 (1.00 to 7.05)
0.64 (0.23 to 1.74)
0.53 (0.10 to 2.87)
.008
.02 (.20)
.20 (.27)
.22 (.79)
.29 (NA d)
.02 (.81)
Abbreviations: CI, confidence interval; cum, cumulative; LVSF, left ventricular shortening fraction; NA, not applicable; OR, odds ratio; TBI, total body irradiation.
a P value for test of trend based on continuous variable among all patients, and among exposed patients only in parentheses.
b For radiotherapy, trend tests are based on continuous grays to the part of the body, adjusted for doses to other areas.
c Test of homogeneity of LVFS changes or trends.
d Not calculated because there were only 2 cases.
Table 4. Multivariate Linear and Logistic Regression Analyses of the Left Ventricular Shortening Fraction (LVSF)
for Different Anthracycline Derivates a
LVSF ⬍ 30%
Change in LVSF
Anthracycline Derivates
2
Doxorubicin, 100 mg/m
Daunorubicin hydrochloride, 100 mg/m2
Epirubicin hydrochloride, 100 mg/m2
Homogeneity P value c
Doxorubicin, 60 mg/m2
Daunorubicin hydrochloride, 60 mg/m2
Epirubicin hydrochloride, 90 mg/m2
Homogeneity P value c
␤ (95% Cl)
−1.18 (−1.65 to −0.72)
−0.88 (−1.97 to 0.20)
−0.87 (−1.38 to −0.35)
−0.71 (−.99 to −0.43)
−0.53 (−1.18 to 0.12)
−0.78 (−1.24 to −0.32)
Trend P
Value b
⬍.001 (⬍.001)
.11 (.21)
.001 (.12)
.44 (.27)
⬍.001 (⬍.001)
.11 (.21)
.001 (.12)
.80 (.71)
OR (95% CI)
Trend P Value b
1.52 (1.25 to 1.85)
1.21 (0.74 to 1.97)
1.35 (1.10 to 1.65)
⬍.001 (⬍.001)
.44 (.01)
.004 (.04)
.36 (.43)
⬍.001 (⬍.001)
.44 (.01)
.004 (.04)
.62 (.61)
1.29 (1.14 to 1.45)
1.12 (0.84 to 1.50)
1.31 (1.09 to 1.57)
Abbreviations: CI, confidence interval; OR, odds ratio.
a Adjusted for sex, age at diagnosis, time since diagnosis, vincristine sulfate, cyclophosphamide, ifosfamide, and radiotherapy (see Table 3).
b P value for test of trend based on continuous variable among all patients, and among exposed patients only in parentheses.
c Test of homogeneity of LVSF changes or trends.
We observed no evidence that the effect of anthracycline dose was different among patients whose radiotherapy field involved a certain body part compared with
others (thorax, P=.92; abdomen, P=.38; spine, P=.40;
TBI, P=.30, based on linear regression; and thorax, P=.36;
abdomen, P =.80; spine, P =.93; TBI, P=.26 based on lo-
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gistic regression). Departure from linearity was mild for
doxorubicin and suggested little decline of LVSF for doses
of less than 100 mg/m2 and a linear decline for higher
doses (Figure).
Abnormal cardiac function, defined as an LVSF of less
than 30%, was observed during long-term follow-up (median duration of follow-up, 15.4 years) in 27% of CCSs.
It was most common in the combined treatment groups.
Important determinants of decreased LVSF were younger
age at diagnosis, higher cumulative anthracycline dose,
and radiotherapy to the thorax. We found some, albeit
weak, evidence that vincristine sulfate could decrease cardiac function. Epirubicin was as cardiotoxic as doxorubicin when corrected for tumor efficacy; daunorubicin
seemed less cardiotoxic. We found no evidence that female sex, high-dose cyclophosphamide, or ifosfamide were
risk factors for cardiac dysfunction.
The overall prevalence of 27% of CCSs with cardiac
dysfunction is alarmingly high in this young population. Although large prospective longitudinal cohort studies with complete follow-up are currently lacking, these
patients are expected to be at greater risk of developing
CHF in the future. Lipshultz et al15 showed that cardiac
abnormalities were persistent and progressive with time
in ALL survivors. Brouwer et al16 also found evidence of
progressive cardiac disease in survivors of malignant bone
tumors, with 1 of 22 patients developing CHF. Because
both studies were relatively small, these results need to
be confirmed in a large cohort with complete follow-up.
Furthermore, subclinical cardiac abnormalities need to
be validated as surrogate markers for clinically important end points, like CHF. In adult patients with asymptomatic cardiac dysfunction from causes other than anthracyclines, the LVSF has been validated as a surrogate
marker for CHF and death from CHF.33,34 However, because the etiology of cardiac damage in these patients was
different, it is important to confirm these findings in patients treated with anthracyclines.
Our results showed higher LVSF measurements in patients with longer time since diagnosis, in contrast to most
other studies.15,16 However, appropriate longitudinal data
are still missing, so it is difficult to interpret these results. Lipshultz et al15,30 described a recovery phase of the
LVSF after treatment, so our findings might reflect this
temporary improvement of the LVSF, owing to a compensatory or remodeling mechanism of the heart. However, the suggestion of an improvement in LVSF over time
should not encourage a wait-and-see policy. The measurement of LVSF has limitations. It is a sum of different pathophysiologic mechanisms of the heart. If we had
examined our cohort with more sensitive and sophisticated markers of the LV function, we might have found
more deterioration of cardiac parameters as described by
Lipshultz et al15 and Brouwer et al.16
To our knowledge, this is the first study in CCSs with
information on the cardiotoxic effect of different anthracycline derivates. The decrease in LVSF per 100 mg/m2 of
doxorubicin in the linear regression analysis showed an
5
0
Change in LVFS
COMMENT
10
–5
– 10
– 15
– 20
Linear-quadratic
Linear
Categorical
– 25
– 30
0
100
200
300
400
500
600
700
800
Doxorubicin Dose, mg/m2
Figure. Shape of dose response for cumulative dose of doxorubicin. LVSF
indicates left ventricular shortening fraction.
apparent but not significant difference with the decrease
per 100 mg/m2 of daunorubicin hydrochloride and epirubicin hydrochloride. When we corrected the epirubicin dose for tumor efficacy, the cardiotoxic effects of doxorubicin and epirubicin were almost identical, and that of
daunorubicin was weaker. Therefore, our data suggest that
epirubicin is as cardiotoxic as doxorubicin at the same tumor efficacy, whereas daunorubicin seemed to be less cardiotoxic.
The present study confirmed that younger age at diagnosis had a clinically significant role in the decrease of LVSF
compared with the highest age group of 15 years or older
at diagnosis.14 Numerous studies indicate that CCSs treated
with higher cumulative anthracycline doses are at higher
risk of developing subclinical and clinical cardiac dysfunction.12-14,35 Our data were consistent with a linear doseresponse relationship with anthracycline dose; that is, there
was a linear decrease of the LVSF with increasing cumulative anthracycline doses. This suggests an influence of
anthracyclines on cardiac function also in the lower dose
ranges. In our analyses we used the lowest dose range (1150 mg/m2), not the zero-dose, as the reference category,
because all patients had received some form of potentially cardiotoxic treatment. On the one hand, consistent
with the findings of Hudson et al,19 we observed significantly decreased LVSF at relatively low doses of anthracyclines (150-300 mg/m2) (P =.03), suggesting that there
may be no safe cumulative anthracycline dose. On the other
hand, some studies observed no deterioration of cardiac
function in CCSs treated with low-dose anthracyclines.20,21,36 However, Rammeloo et al36 evaluated the effect
of low-dose daunorubicin, which may be less cardiotoxic, as observed in our study, and the relatively small
size of their study may have prevented detection of an effect.
To investigate the influence of radiotherapy on cardiac function, the effect of different radiation fields was
evaluated. Radiation equipment and techniques have
changed considerably over the years. Although the regions irradiated were known for every patient, the individual cardiac radiation doses could not be calculated.
Therefore, we used 4 categories of radiation (thorax, TBI,
spine, and left or whole abdomen) and used the tumor dose
as the maximum dose that (part of) the heart could have
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received. Although we observed a strong effect of any vs
no radiotherapy to the thorax, there was no relationship
between radiation dose to the thorax and LVSF among patients who received thoracic radiotherapy. We believe this
does not provide evidence of absence of a dose-response
relation between cardiac irradiation and LVSF but is rather
due to the fact that a dose to the thorax may be inversely
correlated with the irradiated heart volume in our study.
Most patients treated with radiotherapy to the thorax had
lymphomas, nephroblastoma, Ewing sarcoma, or osteosarcoma (89%). Radiotherapy for the latter 3 usually involves prophylactic radiation of the entire lung with a lower
dose, including a different and mostly larger part of the
heart, whereas radiotherapy for lymphomas usually involves smaller and different parts of the heart (eg, mantle
field, mediastinal) but with higher doses. This shows the
need for future studies to include detailed dosimetry with
assessment of the volume of the heart irradiated as well
as the dose to different parts of the heart. Furthermore,
cardiac irradiation might induce more ischemic heart disease, and we did not evaluate that in this study.18,37-39
Our study has important strengths. We were able to
prospectively evaluate a large cohort of CCSs treated for
all types of childhood cancer at one institution with nearly
complete follow-up, limiting the potential for selection
bias. All echocardiographic measurements were performed using the same screening protocol, thus excluding observer bias. Complete treatment data were available. Cardiotoxic treatment was well characterized,
including cumulative anthracycline doses, type of anthracycline derivate, and cumulative cyclophosphamide and ifosfamide doses. For radiotherapy, the administered tumor dose and fields were known. Furthermore,
the cohort represents a heterogeneous group of diagnoses, treatments across a broad spectrum of different
doses of anthracyclines and radiotherapy and a variety
of ages at diagnosis. We were able to analyze the influence of different anthracycline derivates.
Our study has some limitations. The ability of our study
to evaluate more subtle cardiotoxic effects of high-dose
cyclophosphamide, high-dose ifosfamide, or vincristine
compared with the much stronger cardiotoxic effect of anthracyclines and cardiac irradiation, may have been limited owing to the absence of a comparison group not exposed to any potentially cardiotoxic treatment. Second, we
were able to focus only on the LVSF without looking at
other echocardiographic measurements as afterload, wall
thickness, and diastolic dysfunction. The added value of
those more sophisticated measurements of cardiac dysfunction should be evaluated in new research protocols.
However, for LVSF the predictive value for clinically relevant outcomes has been established in adults and children.33,34,40 Unfortunately, in this study we were not able
to investigate the correlation of an abnormal LVSF with
the development of clinical CVD later on. However, this
will be the focus of our next study. Third, measurements
of LVSF were performed multiple times, diminishing the
risk of intraobserver variability, but interobserver variability was not measured. Fourth, we used the results of
the first echocardiographic measurement at the outpatient clinic to avoid selection bias. As a result, patients entered the study cohort at different time points since diag-
nosis. In the multivariate analyses, we adjusted for time
since diagnosis. Fifth, the generalizability of the results
might be influenced by the fact that our study was a singlecenter study. However, the Netherlands is a small country with only 7 hospitals with a children’s oncology unit,
all united in the Dutch Childhood Oncology Group, so
treatment across the Netherlands is quite uniform.
In conclusion, more than 25% of young adult CCSs had
subclinical cardiac dysfunction at their first visit to the outpatient clinic for late effects of childhood cancer. Continued monitoring of all CCSs treated with potentially cardiotoxic therapy with or without subclinical cardiac
dysfunction is necessary to identify CCSs who could possibly benefit from early treatment, which could avoid further deterioration of cardiac function. The most important risk factors for developing subclinical cardiac
dysfunction are the cumulative anthracycline dose, radiotherapy to the thorax and younger age at diagnosis. There
is the suggestion that both abdominal radiotherapy and
vincristine might play a role in developing cardiac dysfunction; this has to be confirmed in a cohort of CCSs including those who did not receive cardiotoxic treatment.
We found no evidence of a higher risk of cardiac dysfunction for female CCSs and high-dose cyclophosphamide and
ifosfamide. Epirubicin was as cardiotoxic as doxorubicin
when corrected for tumor efficacy, and daunorubicin
seemed to be less cardiotoxic.
Accepted for Publication: January 20, 2010.
Correspondence: Helena J. van der Pal, MD, Departments of Medical Oncology and Pediatric Oncology, Room
F4-224, Academic Medical Center, Meibergdreef 9, 1105
AZ Amsterdam, the Netherlands (h.j.vanderpal@amc
.uva.nl).
Author Contributions: Drs van der Pal, van Dalen, Hauptmann, and Kremer had full access to all the data in the
study and take responsibility for the integrity of the data
and the accuracy of the data analysis. Study concept and
design: van der Pal, van Dalen, Caron, van Leeuwen, and
Kremer. Acquisition of data: van der Pal, van Dalen, Kok,
van den Bos, and Oldenburger. Analysis and interpretation of data: van der Pal, van Dalen, Hauptmann, Kok, van
den Bos, Koning, van Leeuwen, and Kremer. Drafting
of the manuscript: van der Pal, Hauptmann, and Kremer.
Critical revision of the manuscript for important intellectual
content: van der Pal, van Dalen, Hauptmann, Kok, Caron,
van den Bos, Oldenburger, Koning, van Leeuwen, and
Kremer. Statistical analysis: Hauptmann and van Leeuwen. Obtained funding: Caron. Administrative, technical, and
material support: van der Pal, van Dalen, and van den Bos.
Study supervision: Caron and Kremer.
Financial Disclosure: None reported.
Funding/Support: This study was supported by the
Foundation of Pediatric Cancer Research, Amsterdam,
the Netherlands.
Role of the Sponsor: The funding organization had no
role in the design and conduct of the study; in the collection, analysis, and interpretation of the data; or in the
preparation, review, or approval of the manuscript.
Additional Contributions: We thank the staff of our
Outpatient Clinic for Late Effects of Childhood Cancer,
EKZ/AMC. We also thank Richard C. Heinen, MSc,
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Department of Pediatric Oncology, EKZ/AMC, for his
uncompensated help in identifying eligible patients. We
are indebted to the patients for giving their permission
to participate in the study.
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