当前位置: 首页 > 期刊 > 《临床肿瘤学》 > 2005年第8期 > 正文
编号:11332416
Blood Pressure and Body Mass Index in Long-Term Survivors of Testicular Cancer
http://www.100md.com 《临床肿瘤学》
     the Department of Oncology, Institute of Clinical Medicine, and Institute of Community Medicine, University of Troms?

    Department of Oncology, University Hospital of Northern Norway, Troms?

    Department of Clinical Cancer Research, The Norwegian Radium Hospital

    Medical Faculty, University of Oslo

    Department of Oncology, Ullev?l University Hospital, Oslo

    Department of Oncology, Haukeland University Hospital, Bergen

    Department of Oncology, St Olav University Hospital, Trondheim, Norway

    ABSTRACT

    PURPOSE: To evaluate blood pressure and body mass index (BMI) in long-term survivors of testicular cancer (TC) treated with different modalities.

    PATIENTS AND METHODS: One thousand eight hundred fourteen patients treated for unilateral TC in Norway (1980 to 1994) were invited to participate in a follow-up study (1998 to 2002), including measurements of systolic blood pressure (SBP), diastolic blood pressure (DBP), and BMI. Of these patients, 1,289 patients (71%) participated in the study. The patients were categorized into four treatment groups: surgery (n = 242), radiotherapy (n = 547), and two chemotherapy groups, cumulative cisplatin dose 850 mg (n = 402) and cumulative cisplatin dose more than 850 mg (n = 98). A control group consisted of healthy males from the Troms? Population Study (n = 2,847).

    RESULTS: At diagnosis, age-adjusted regression analyses showed no differences between the treatment groups for any variables. After a median follow-up time of 11.2 years, age-adjusted SBP and DBP were significantly higher for both chemotherapy groups compared with the surgery group. Chemotherapy-treated patients had increased odds for hypertension at follow-up compared with the surgery group, and the odds were highest for the cisplatin more than 850 mg group (odds ratio = 2.4; 95% CI, 1.4 to 4.0). The cisplatin more than 850 mg group had a significantly higher 10-year BMI increase and a higher prevalence of obesity at follow-up than the surgery group. Compared with healthy controls, chemotherapy-treated patients had, at follow-up, increased SBP, increased DBP, excessive BMI increase, and a higher prevalence of hypertension.

    CONCLUSION: Five to 20 years after therapy, cured TC patients treated with cisplatin-based chemotherapy had significantly higher levels of blood pressure, a higher prevalence of hypertension, and an excessive weight gain compared with patients treated with other modalities and compared with healthy controls.

    INTRODUCTION

    Testicular cancer (TC) is the most common malignancy among young men, and the incidence rate has now exceeded 10 per 100,000 men in Norway.1 The prognosis for metastatic disease has improved considerably after the introduction of cisplatin-based combination chemotherapy,2,3 and today, more than 95% of all patients are cured.1 The combination of increased incidence and improved prognosis has led to an increasing number of TC survivors (TCS). Although there are indications for higher mortality rates among long-term TCS,4 these young men are presumed to have a lifetime almost comparable to age-matched healthy males once they have achieved a durable remission. Thus, the impact of long-term morbidity after treatment becomes increasingly important.

    The major acquired risk factors for cardiovascular disease in the general population are smoking, hypertension, obesity, and an unfavorable lipid profile.5,6 During the last decade, several studies have reported an increased risk of cardiovascular events (angina pectoris and myocardial infarction) in TCS years after treatment with cisplatin-based chemotherapy.7-9 A recent publication by Huddart et al7 reported a higher prevalence of cardiovascular events in TC patients treated with radiotherapy (RT) alone or in combination with chemotherapy compared with patients who were observed with a surveillance program. However, the authors did not identify any corresponding risk factors. Other investigators have suggested that TCS may have an unfavorable lipid profile, hypertension risk, or excessive weight gain as late side effects after cisplatin-based chemotherapy.8-16 However, the majority of these studies have limited power as a result of small series and generally lack control groups.

    Because an increased cardiovascular risk may be life threatening for cured TC patients, it is imperative to further estimate the risk potential and clarify possible mechanisms for the development of cardiovascular morbidity in these individuals. The aim of our study was to evaluate the cardiovascular risk factors of blood pressure, hypertension, body mass index (BMI), and obesity in long-term TCS treated with different modalities (surveillance/surgery, RT, and chemotherapy) through the following research questions: do any of these cardiovascular risk factors differ according to administered treatment, and do TCS differ from healthy controls with respect to any of these cardiovascular risk factors?

    PATIENTS AND METHODS

    Patients

    All Norwegian long-term survivors ( 5 years) of unilateral TC who were between 18 and 75 years of age and treated between 1980 and 1994 were invited to participate in a national multicenter follow-up survey. The follow-up was carried out during 1998 to 2002. Patients with extragonadal germ cell tumor, bilateral orchiectomy for any reason, secondary malignancy, or mental retardation were excluded, leaving 1,814 patients who were eligible and, thus, invited to participate in the study. One thousand four hundred thirty-eight patients (79%) accepted the invitation, signed the informed consent form, and completed a 219-item questionnaire including data on medical history, family status, educational level, and smoking habits. Of these patients, 1,289 patients who underwent a follow-up examination, including a clinical examination and blood tests, at one of five university hospitals form the study population. This group constituted 71% of all eligible patients. The study was recommended by the Ethical Review Board of Region South.

    All patients were orchiectomized at diagnosis. Staging was performed according to the Royal Marsden Staging System.17 For this study, the patients were categorized into the following four groups related to initial treatment after orchiectomy and eventual relapse treatment: surgery only; RT only; chemotherapy with a cumulative dose of cisplatin 850 mg (Cis 850); and chemotherapy with a cumulative dose of cisplatin more than 850 mg (Cis > 850).

    The surgery group comprised patients who did not receive treatment with RT or chemotherapy. This group consisted of 242 patients, of whom 131 (54%) had undergone retroperitoneal surgery only. The remaining patients (n = 111) did not receive any other treatment than orchiectomy and were on a surveillance program without developing chemotherapy-requiring relapses. The RT group comprised 547 patients, of whom the majority received a modified dog-leg (n = 488) or para-aortic (n = 34) RT field for seminoma stage I or IIA. From the early 1980s to mid-1990s, the applied RT dose was gradually reduced from 40 to 27 Gy. Among the remaining 25 patients, two patients had received additional mediastinal irradiation.

    The chemotherapy groups consisted of 500 patients, of whom 98 were in the Cis > 850 group and 402 were in the Cis group. Most patients (n = 477; 95%) received cisplatin-based chemotherapy, which involved primarily the combinations of cisplatin, etoposide, and bleomycin (n = 263) or cisplatin, vinblastine, and bleomycin (n = 152). Sixty-two patients received other cisplatin-based regimens. The remaining 23 patients who received carboplatin-based chemotherapy were included in the Cis 850 group. The median cisplatin doses in the Cis 850 and Cis > 850 group were 723 mg (range, 185 to 850 mg) and 1,143 mg (range, 855 to 2,455 mg), respectively. Of the chemotherapy-treated patients, 321 (64%) underwent retroperitoneal surgery, and 53 (11%) received additional RT (mostly abdominal).

    Measurements

    Resting blood pressure was measured manually or with an automatic device. BMI was calculated as weight in kilograms divided by the square of height in meters (kg/m2). Data for blood pressure, weight, and height at the time of diagnosis (pretreatment data) were obtained from medical records. At follow-up, blood samples were drawn by venipuncture between 8 AM and 12 PM. Levels of total serum testosterone assessments were based on commercial immunoassay technology at each hospital laboratory and were assessed as nanomolar per liter (nmol/L), with similar reference ranges at each hospital. Data on antihypertensive treatment, family status, educational level, and smoking habits were obtained from the questionnaire and were dichotomized for the present analyses.

    Systolic blood pressure (SBP), diastolic blood pressure (DBP), and BMI at time of diagnosis were identified as pre SBP, pre DBP, and pre BMI, respectively, whereas these variables at follow-up were identified as post SBP, post DBP, and post BMI, respectively. Hypertension was defined as SBP 140 mmHg and/or DBP 90 mmHg, according to the WHO guidelines.18 Individuals treated for hypertension were also included in the hypertension group, irrespective of measured blood pressure values. The applied 10-year BMI change was calculated as the difference between post and pre BMI, divided by the observation time in years, multiplied by 10 [(post BMI – pre BMI) x 10/observation time]. In agreement with the WHO guidelines,19 obesity at follow-up was defined as BMI 30 kg/m2.

    Control Group

    The control group was recruited from the Troms? Study, which was a longitudinal population-based epidemiologic study conducted in Troms?, Northern Norway. Troms? covers a relatively large geographical area with both urban and rural population, and the Troms? Study is representative of the Norwegian population with regard to cardiovascular risk factors such as blood pressure and BMI.20-23 This study was initiated in 1974 primarily to identify possible risk factors for cardiovascular disease, and large parts of the population have gone through repeated health examinations. The following five surveys have been performed: Troms? 1 (1974), Troms? 2 (1979/1980), Troms? 3 (1986/1987), Troms? 4 (1994/1995), and Troms? 5 (2001). Methods and attendance rates have been previously published.20 The Troms? 5 Study was carried out during approximately the same time period as our follow-up survey.

    The control group consisted of 2,847 males (born after 1925) who attended the Troms? 5 survey and had participated in at least one earlier survey. Men treated with testosterone substitution were excluded. The median age was 63 years (range, 30 to 76 years). SBP, DBP, and BMI values from Troms? 5 were compared with the patients' values at follow-up. SBP, DBP, and BMI values from Troms? 2, 3, or 4 were compared with the patients' values at diagnosis. We selected one of the surveys before Troms? 5 as reference for pretreatment data. Patients diagnosed during 1980 to 1983 were matched to controls from Troms? 2, patients diagnosed during 1984 to 1989 were matched to Troms? 3, and patients diagnosed during 1990 to 1994 were matched to Troms? 4.

    Statistical Analyses

    Categorical data were analyzed using the 2 test, and continuous data were analyzed using the Student's t test. Multiple linear regression with BMI or blood pressure as the dependent variable was performed to evaluate possible differences between treatment groups and between patients and controls. Dichotomous variables, such as familial status, educational level, smoking, hypertension, and obesity were analyzed using multiple logistic regression. The surgery group was used as reference group when comparing the impact of different treatment modalities. All analyses were adjusted for age. All P values are two tailed, with statistical significance set at P < .05. The regression coefficient ? is used to indicate change in the dependent variable when comparing different treatment groups. The data were analyzed using the Statistical Package for the Social Sciences (SPSS) for Windows version 11.0 (SPSS Inc, Chicago, IL).

    RESULTS

    Patient Characteristics

    Of 1,814 patients eligible for the study, 1,438 accepted the invitation, and 1,289 underwent the follow-up examination (responders; Table 1). The responders were older than nonresponders at time of diagnosis (median age, 32 v 31 years, respectively; P = .02), but age at follow-up was not significantly different between responders and nonresponders (median age, 44 v 43 years, respectively; P = .87). Stage, histology, and treatment were not significantly different between the two groups (Table 1).

    Patient characteristics are listed in Table 2. For the total study population, the median age was 32 years (range, 15 to 64 years) at diagnosis and 44 years (range, 23 to 75 years) at follow-up. The median observation time was 11.2 years (range, 4 to 22 years). The RT group was significantly older than the surgery group at diagnosis (36 v 29 years, respectively; P < .001) and at follow-up (48 v 41 years, respectively; P < .001), whereas the Cis > 850 group was significantly younger than the surgery group at follow-up (37 v 41 years, respectively; P = .005) and had a shorter observation time (9.5 v 11.8 years, respectively; P = .007). The Cis 850 group consisted of more smokers than the surgery group (P = .007). There were no significant differences between the treatment groups with regard to family status or educational level.

    Blood Pressure

    Data on blood pressure, BMI, and total testosterone levels for patients are listed in Table 3, whereas data for control individuals are listed in Table 4. Mean pre SBP and pre DBP were 135 mmHg (standard deviation [SD], 18 mmHg) and 83 mmHg (SD, 11 mmHg), respectively, for all patients, and there were no significant differences between the treatment groups. Overall, the mean post SBP and post DBP were 134 mmHg (SD, 19 mmHg) and 83 mmHg (SD, 12 mmHg), respectively. Univariate analyses revealed age and total testosterone as important predictors for blood pressure (P < .001), hypertension (P < .001), and BMI (P < .001) in both patients and healthy controls. Therefore, further statistical analyses were adjusted for age and total testosterone. Blood pressure analyses were additionally adjusted for BMI.

    Data for age-adjusted SBP, DBP, and BMI at follow-up are listed in Table 5. Compared with the surgery group, the chemotherapy-treated patients had significantly higher blood pressure at follow-up. Age-adjusted post SBP was 4.1 mmHg (P = .005) and 5.0 mmHg (P = .02) higher for the Cis 850 and the Cis > 850 groups, respectively; and post DBP was 1.9 mmHg (P = .04) and 3.4 mmHg (P = .01) higher, respectively. Table 5 further lists age-adjusted post SBP and post DBP according to treatment group after adjusting for serum testosterone and for serum testosterone and BMI. After adjusting for total testosterone, post SBP remained significantly higher in both the Cis 850 and the Cis > 850 groups (P = .008 and P = .04, respectively), and post DBP was higher in the Cis > 850 group (P = .03) compared with the surgery group. When BMI was added to the model, post DBP was significantly higher in both chemotherapy groups (P = .03 for both groups), and post SBP was higher in the Cis 850 group (P = .005).

    When comparing all patients to the healthy controls, SBP and DBP at time of diagnosis were significantly higher among the patients (SBP: ? = 5.0, P < .001; DBP: ? = 4.8, P < .001), whereas there were no differences between all patients and controls at follow-up. Table 6 lists age-adjusted comparisons of post SBP and DBP between controls and patients divided into two treatment groups (surgery/RT or chemotherapy). Chemotherapy-treated patients tended to have a higher post SBP (? = 1.7, P = .08) and post DBP (? = 1.3, P = .06) compared with controls. These differences became significant after adjusting for total testosterone (P = .03 for both SBP and DBP). Adding BMI to the model further increased the average difference in post SBP to 2.3 (P = .02) and in post DBP to 1.8 (P = .007) between chemotherapy-treated patients and controls. Neither post SBP nor post DBP for patients in the surgery/RT group differed from that of the healthy controls.

    Prevalence of Hypertension at Follow-Up

    According to our definition of hypertension at follow-up, the percentage of individuals with hypertension was 39% in the surgery group, 54% in the RT group, 50% in the Cis 850 group, and 53% in the Cis > 850 group (Table 3). The overall age-adjusted association between treatment groups and hypertension was highly significant (P < .001). Table 7 lists the treatment group–specific age-adjusted odds ratios (OR) and 95% CIs of having hypertension. Both chemotherapy groups had significantly higher prevalence of hypertension compared with the surgery group, which was highest in the Cis > 850 group, with an OR of 2.4 (95% CI, 1.4 to 4.0). The significantly elevated ORs were maintained after adjustments for total testosterone and BMI.

    Compared with the healthy controls, the total patient group had increased odds of having hypertension (OR = 1.4; 95% CI, 1.2 to 1.7). Subgroup analysis showed that all treatment groups, except the surgery group, had a significantly higher prevalence of hypertension. The prevalence was highest in the Cis > 850 group (OR = 2.3; 95% CI, 1.5 to 3.7; Fig 1).

    BMI

    Mean BMI for all patients at diagnosis was 24.1 kg/m2 (SD, 3.4 kg/m2; Table 3), and analyses showed no differences between the treatment groups. At follow-up, mean BMI was 26.5 kg/m2 (SD, 3.9 kg/m2). The Cis > 850 group had a slightly, although not significantly, higher post BMI compared with the surgery group (? = 0.6, P = .21; Table 5). Analyses of 10-year BMI change in patients and controls were adjusted for age and observation time in years. Mean 10-year BMI change was 2.2 kg/m2 (SD, 2.4 kg/m2) for all patients. The Cis > 850 group had a higher 10-year BMI increase compared with the surgery group (? = 0.7, P = .02), whereas the other treatment groups did not differ significantly.

    Pre BMI in the patient group was slightly lower but not significantly different from the pre BMI of the healthy controls (? = –0.17, P = .2). However, post BMI was significantly lower for patients than controls (? = –0.5, P < .001). Subgroup analyses showed that the Cis > 850 group did not differ from controls (P = .95), whereas the other patient groups had lower post BMI, with significantly lower values for the RT group (? = –0.6, P = .002) and the Cis 850 group (? = –0.6, P = .007). Adjustments for testosterone did not alter these results significantly. In subgroup analyses, the Cis 850 and Cis > 850 groups had a higher 10-year BMI increase than controls (? = 0.3, P = .009 and ? = 1.0, P < .001, respectively).

    Prevalence of Obesity at Follow-Up

    The percentage of individuals who were obese (BMI 30 kg/m2) at follow-up was 16% and 25% in the Cis 850 and Cis > 850 groups, respectively, and 13% in the surgery and RT groups (Table 3). The overall age-adjusted association between treatment groups and obesity was significant (P = .003). When compared with the surgery group, the chemotherapy groups had increased age-adjusted odds of being obese, with an OR of 1.4 (95% CI, 0.9 to 2.2) for the Cis 850 group and a significantly increased OR of 2.4 (95% CI, 1.3 to 4.4) for the Cis > 850 group. The RT group did not differ significantly from the surgery group, with an OR of 0.9 (95% CI, 0.6 to 1.5). The observed difference between treatment groups was weakened when we adjusted for total testosterone. The OR for the Cis > 850 group was reduced to 1.8 (95% CI, 1.0 to 3.4).

    Compared with healthy controls, the total patient group had a significantly lower prevalence of obesity (OR = 0.8; 95% CI, 0.6 to 1.0). The lower prevalence of obesity was statistically significant for the surgery group and the RT group (Fig 2). The Cis > 850 group had an increased, although not significant, prevalence of obesity (OR = 1.4; 95% CI, 0.9 to 2.3).

    DISCUSSION

    In the present series, TCS treated with cisplatin-based chemotherapy had increased age-adjusted SBP and DBP and a higher prevalence of hypertension at follow-up compared with TCS who underwent surgery or RT only and also compared with healthy controls. These associations remained significant after adjusting for serum testosterone and BMI, and were more pronounced for those patients treated with cumulative cisplatin doses greater than 850 mg. Cisplatin-based treatment was also associated with an excessive weight gain and an increased prevalence of obesity.

    The major strength of this study is the case-control study design, which allows comparisons between the TCS and healthy controls. In addition, blood pressure and BMI assessments in the healthy controls coincided in time with assessments in our patients at diagnosis and follow-up. Another essential strength is the large unselected patient population, allowing comparisons between different treatment groups. However, a limitation is the age difference between the TCS and controls. Although the difference in median age at follow-up between the patient population and the healthy controls (44 v 63 years, respectively) was compensated for by age adjusting all statistical analyses, it may not have completely equalized the impact of age on blood pressure, hypertension, and BMI. If so, a significant age bias would underestimate the observed associations between treatment with cisplatin-based chemotherapy and blood pressure, hypertension, and BMI. Another limitation that may represent a source of bias is the 525 TCS who did not participate in the follow-up examination. However, a systematic bias is unlikely because the nonresponders and responders are equally distributed according to initial stage, histology, treatment group, and age at follow-up.

    In accordance with our results, Meinardi et al8 reported significantly higher SBP and DBP in cisplatin-treated patients compared with patients who were observed with a surveillance program. Several investigators have also suggested that hypertension is a possible complication in TCS after treatment with cisplatin-based chemotherapy.8-15 The reported hypertension rates were between 13% and 39%, whereas we observed even higher rates for the chemotherapy-treated patients. Possible explanations for the higher prevalence of hypertension in our study are the inclusion of patients receiving antihypertensive medication and the applied definition of hypertension, which is according to the latest, more liberal WHO guidelines from 1999.18 Our findings also support the data presented by Bokemeyer et al,9 demonstrating that a cumulative cisplatin dose of more than 400 mg/m2 was associated with a higher hypertension rate than a cumulative cisplatin dose of less than 400 mg/m2 (24% v 10%, respectively).

    In a study of 739 TCS, Huddart et al7 observed a two-fold higher prevalence of antihypertensive treatment among patients treated with both RT and chemotherapy when compared with surveillance (21% v 9%, respectively), whereas the prevalence in patients treated with RT or chemotherapy alone did not differ significantly. They did not detect any differences in blood pressure between the treatment groups. In our study, the patients receiving both chemotherapy and RT (n = 53) did not, when analyzed separately, differ with regard to hypertension risk from TCS treated with chemotherapy alone. Thus, our results do not support the findings in the British study. One possible explanation for the discrepancy between our results and those presented by Huddart et al7 is that the hypertension and blood pressure data in the British study were not age adjusted.

    To our knowledge, this is the first study to compare blood pressure in TCS with blood pressure of healthy controls. Our patients' blood pressure measurements at time of diagnosis were probably biased and temporarily increased because of stress and anxiety related to the initial hospitalization. This may explain the higher pre BP in patients than controls. Chemotherapy-treated patients had higher post SBP, higher post DBP, and increased prevalence of hypertension compared with healthy controls. We did not identify increased blood pressure levels as a late side effect after irradiation, and our RT patients had only a slightly increased OR of having hypertension compared with healthy controls. Theoretically, partial irradiation of the kidneys could lead to RT-induced nephropathy,24 which might cause hypertension by activating the renin-angiotensin system.25 Thus, our data indicate that elevated blood pressure and hypertension are long-term complications after treatment with cisplatin-based chemotherapy, rather than related to the TC itself or late sequelae after orchiectomy or RT.

    Several studies have suggested an inverse relationship between blood pressure and serum testosterone.26,27 The inverse association between hypertension and total testosterone has been reported to be stronger than between hypertension and free testosterone.26 Leydig-cell dysfunction has been proposed as a possible complication after cisplatin treatment,28,29 and subnormal levels of total testosterone may cause increased blood pressure in chemotherapy-treated patients. Obesity may also contribute to elevated blood pressure.21,30 In this study, however, the higher blood pressure and hypertension rate in the chemotherapy-treated patients were maintained after adjusting for testosterone and BMI, indicating that other mechanisms are involved as well. Nephrotoxicity is a well-known side effect of cisplatin-based chemotherapy, particularly after high cumulative doses or in combination with RT.9,31,32 Cisplatin-treated TCS have a high prevalence of microalbuminuria,33 and there are indications that cisplatin-treated patients with microalbuminuria have higher SBP and DBP than patients with a normal albumin excretion,8 suggesting that endothelial damage may contribute to the increased BP. In a study by Hansen et al,11 there was no correlation between increased blood pressure and renal dysfunction after cisplatin-based chemotherapy in TCS. However, the number of patients was limited. Thus, any possible relationship between hypertension and cisplatin-induced renal damage needs to be further investigated.

    Our findings, which indicate no differences in BMI between the different treatment groups at follow-up, are consistent with previous studies.7,8,34 However, several studies have demonstrated that being overweight (BMI 25 kg/m2) may be a chemotherapy-related side effect in TCS, with reported rates at 32%9 and 48%.15 Our results are in line with these findings, with 25% of heavily cisplatin-treated patients (> 850 mg) being obese (BMI 30 kg/m2). The present study demonstrates that heavily cisplatin-treated TCS, compared with the surgery group and healthy controls, have an excessive BMI increase. Thus, our results confirm the findings by Nord et al,16 who examined BMI change in a subset of our patient population. Because our analyses were age adjusted, factors other than age may explain this excessive weight gain. Furthermore, because the total patient population at follow-up had a lower BMI and lower odds of being obese than the healthy controls, we suggest that the unfavorable weight gain in heavily chemotherapy-treated patients is a result of the cisplatin-based therapy, rather than a consequence of the malignant disease or sequelae after orchiectomy.

    It has been demonstrated that moderately obese men have a reduced sex hormone–binding globulin–binding capacity, leading to lower levels of total testosterone, whereas free testosterone levels are unchanged.35 Several reports have shown an inverse association between BMI and total testosterone,36,37 and the results by Giagulli et al35 suggest that low levels of total testosterone may be the consequence and not the cause of obesity. In our study, the Cis > 850 group remained more obese compared with the surgery group, even after adjusting for total testosterone. Because obesity is an important predictor of hypertension21,30 and an independent risk factor for cardiovascular disease,6 one should be aware of the possible clinical implications of the excessive weight gain observed in cisplatin-treated TCS.

    In conclusion, we have identified hypertension and augmented weight gain as potential long-term cardiovascular risk factors in TCS treated with cisplatin-based chemotherapy and particularly in patients treated with cumulative doses of more than 850 mg. Our results demonstrate the importance of establishing good follow-up routines to identify high-risk patients before they develop cardiovascular events. Because cisplatin-treated TCS seem to constitute a risk group for cardiovascular disease, they should have their blood pressure measured regularly. They should also receive general primary prevention information about diet, exercise, obesity, and smoking. Furthermore, these data support the efforts to minimize cumulative chemotherapy doses in good prognosis TC patient groups.

    Authors' Disclosures of Potential Conflicts of Interest

    The authors indicated no potential conflicts of interest.

    Acknowledgment

    We thank project secretary Vigdis Opperud for assistance with the database and Rod Wolstenholme for making the figures.

    NOTES

    Supported in part by grants from the Erna and Olav Aakres Legacy, the Odd Fellow Medical-Scientific Research Fund, and the Norwegian Foundation for Health and Rehabilitation (grant No. 1998/27).

    Authors' disclosures of potential conflicts of interest are found at the end of this article.

    REFERENCES

    Kreftregisteret: Cancer in Norway 2001. http://www.kreftregisteret.no

    Einhorn LH, Donohue J: Cis-diamminedichloroplatinum, vinblastine, and bleomycin combination chemotherapy in disseminated testicular cancer. Ann Intern Med 87:293-298, 1977

    Peckham M: Testicular cancer. Acta Oncol 27:439-453, 1988

    Fossa SD, Aass N, Harvei S, et al: Increased mortality rates in young and middle-aged patients with malignant germ cell tumours. Br J Cancer 90:607-612, 2004

    Kannel WB, Mcgee D, Gordon T: A general cardiovascular risk profile: The Framingham Study. Am J Cardiol 38:46-51, 1976

    Hubert HB, Feinleib M, McNamara PM, et al: Obesity as an independent risk factor for cardiovascular disease: A 26-year follow-up of participants in the Framingham Heart Study. Circulation 67:968-977, 1983

    Huddart RA, Norman A, Shahidi M, et al: Cardiovascular disease as a long-term complication of treatment for testicular cancer. J Clin Oncol 21:1513-1523, 2003

    Meinardi MT, Gietema JA, van der Graaf WT, et al: Cardiovascular morbidity in long-term survivors of metastatic testicular cancer. J Clin Oncol 18:1725-1732, 2000

    Bokemeyer C, Berger CC, Kuczyk MA, et al: Evaluation of long-term toxicity after chemotherapy for testicular cancer. J Clin Oncol 14:2923-2932, 1996

    Gietema JA, Sleijfer DT, Willemse PH, et al: Long-term follow-up of cardiovascular risk factors in patients given chemotherapy for disseminated nonseminomatous testicular cancer. Ann Intern Med 116:709-715, 1992

    Hansen SW, Groth S, Daugaard G, et al: Long-term effects on renal function and blood pressure of treatment with cisplatin, vinblastine, and bleomycin in patients with germ cell cancer. J Clin Oncol 6:1728-1731, 1988

    Bissett D, Kunkeler L, Zwanenburg L, et al: Long-term sequelae of treatment for testicular germ cell tumours. Br J Cancer 62:655-659, 1990

    Boyer M, Raghavan D, Harris PJ, et al: Lack of late toxicity in patients treated with cisplatin-containing combination chemotherapy for metastatic testicular cancer. J Clin Oncol 8:21-26, 1990

    Stoter G, Koopman A, Vendrik CP, et al: Ten-year survival and late sequelae in testicular cancer patients treated with cisplatin, vinblastine, and bleomycin. J Clin Oncol 7:1099-1104, 1989

    Strumberg D, Brugge S, Korn MW, et al: Evaluation of long-term toxicity in patients after cisplatin-based chemotherapy for non-seminomatous testicular cancer. Ann Oncol 13:229-236, 2002

    Nord C, Fossa SD, Egeland T: Excessive annual BMI increase after chemotherapy among young survivors of testicular cancer. Br J Cancer 88:36-41, 2003

    Peckham MJ, McElwain TJ, Barrett A, et al: Combined management of malignant teratoma of the testis. Lancet 2:267-270, 1979

    WHO and International Society of Hypertension: 1999 World Health Organization-International Society of Hypertension Guidelines for the Management of Hypertension: Guidelines Subcommittee. J Hypertens 17:151-183, 1999

    WHO: Obesity: Preventing and Managing the Global Epidemic—Report of a WHO Consultation on Obesity. Geneva, Switzerland, WHO, 1997

    Jacobsen BK, Njolstad I, Thune I, et al: Increase in weight in all birth cohorts in a general population: The Tromso Study, 1974-1994. Arch Intern Med 161:466-472, 2001

    Wilsgaard T, Schirmer H, Arnesen E: Impact of body weight on blood pressure with a focus on sex differences: The Tromso Study, 1986-1995. Arch Intern Med 160:2847-2853, 2000

    Tverdal A: Prevalence of obesity among persons aged 40-42 years in two periods. Tidsskr Nor Laegeforen 121:667-672, 2001

    Tverdal A: Significant decline in blood pressure levels after 1996: Fact or artifact? Tidsskr Nor Laegeforen 121:1821-1825, 2001

    Cassady JR: Clinical radiation nephropathy. Int J Radiat Oncol Biol Phys 31:1249-1256, 1995

    Verheij M, Dewit LG, Valdes Olmos RA, et al: Evidence for a renovascular component in hypertensive patients with late radiation nephropathy. Int J Radiat Oncol Biol Phys 30:677-683, 1994

    Svartberg J, von Muhlen D, Schirmer H, et al: Association of endogenous testosterone with blood pressure and left ventricular mass in men: The Tromso Study. Eur J Endocrinol 150:65-71, 2004

    Khaw KT, Barrett-Connor E: Blood pressure and endogenous testosterone in men: An inverse relationship. J Hypertens 6:329-332, 1988

    Gerl A, Muhlbayer D, Hansmann G, et al: The impact of chemotherapy on Leydig cell function in long term survivors of germ cell tumors. Cancer 91:1297-1303, 2001

    Nord C, Bjoro T, Ellingsen D, et al: Gonadal hormones in long-term survivors 10 years after treatment for unilateral testicular cancer. Eur Urol 44:322-328, 2003

    Sonne-Holm S, Sorensen TI, Jensen G, et al: Independent effects of weight change and attained body weight on prevalence of arterial hypertension in obese and non-obese men. BMJ 299:767-770, 1989

    Aass N, Fossa SD, Aas M, et al: Renal function related to different treatment modalities for malignant germ cell tumours. Br J Cancer 62:842-846, 1990

    Fossa SD, Aass N, Winderen M, et al: Long-term renal function after treatment for malignant germ-cell tumours. Ann Oncol 13:222-228, 2002

    Nuver J, Smit AJ, Sleijfer DT, et al: Microalbuminuria, decreased fibrinolysis, and inflammation as early signs of atherosclerosis in long-term survivors of disseminated testicular cancer. Eur J Cancer 40:701-706, 2004

    Fenton DW, Verma S, Venner P, et al: The lack of long-term effect of cisplatin based combination chemotherapy on serum cholesterol for treatment of testicular cancer. J Urol 168:1971-1974, 2002

    Giagulli VA, Kaufman JM, Vermeulen A: Pathogenesis of the decreased androgen levels in obese men. J Clin Endocrinol Metab 79:997-1000, 1994

    Svartberg J, Midtby M, Bonaa KH, et al: The associations of age, lifestyle factors and chronic disease with testosterone in men: The Tromso Study. Eur J Endocrinol 149:145-152, 2003

    Simon D, Charles MA, Nahoul K, et al: Association between plasma total testosterone and cardiovascular risk factors in healthy adult men: The Telecom Study. J Clin Endocrinol Metab 82:682-685, 1997(H. Sagstuen, N. Aass, S.D)