This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Patel, A. V. Articles by Calle, E. E. Search for Related Content PubMed PubMed Citation Articles by Patel, A. V. Articles by Calle, E. E.

Obesity, Recreational Physical Activity, and Risk of Pancreatic Cancer In a Large U.S. Cohort

¹ Department of Epidemiology and Surveillance Research, American Cancer Society, Atlanta, Georgia and ² Department of Preventive Medicine, University of Southern California School of Medicine, Los Angeles, California

Requests for reprints: Alpa V. Patel, Epidemiology and Surveillance Research, American Cancer Society, National Home Office, 1599 Clifton Road Northeast, Atlanta, GA 30329-4251. Phone: 1-404-329-7726; Fax: 1-404-327-6450. E-mail: apatel{at}cancer.org

	Abstract

Top Abstract Introduction Materials and methods Results Discussion References

 
Background: Obesity and physical activity, in part through their effects on insulin sensitivity, may be modifiable risk factors for pancreatic cancer.

Methods: The authors analyzed data from the American Cancer Society Cancer Prevention Study II Nutrition Cohort to examine the association between measures of adiposity, recreational physical activity, and pancreatic cancer risk. Information on current weight and weight at age 18, location of weight gain, and recreational physical activity were obtained at baseline in 1992 via a self-administered questionnaire for 145,627 men and women who were cancer-free at enrollment. During the 7 years of follow-up, 242 incident pancreatic cancer cases were identified among these participants. Cox proportional hazards modeling was used to compute hazard rate ratios (RR) and to adjust for potential confounding factors including personal history of diabetes and smoking.

Results: We observed an increased risk of pancreatic cancer among obese [body mass index (BMI) 30] men and women compared with men and women of normal BMI [<25; RR, 2.08; 95% confidence interval (95% CI), 1.48-2.93, P_trend = 0.0001]. After adjustment for between BMI, risk of pancreatic cancer was independently increased among men and women who reported a tendency for central weight gain compared with men and women reporting a tendency for peripheral weight gain (RR, 1.45; 95% CI, 1.02-2.07). We observed no difference in pancreatic cancer incidence rates between men and women who were most active (>31.5 metabolic equivalent hours per week) at baseline compared with men and women who reported no recreational physical activity (RR, 1.20; 95% CI, 0.63-2.27).

Conclusion: This study, along with several recent studies, supports the hypothesis that obesity and central adiposity are associated with pancreatic cancer risk.

	Introduction

Top Abstract Introduction Materials and methods Results Discussion References

 
Pancreatic cancer is the fourth leading cancer cause of death among U.S. men and women (1). Over 31,000 new cases and an equal number of deaths due to pancreatic cancer are estimated to occur in 2004 (1). Cigarette smoking and diabetes are the only risk factors that have been consistently associated with pancreatic cancer (2-6). In addition, insulin resistance and abnormal glucose metabolism, without a diagnosis of diabetes, may also be risk factors in pancreatic cancer etiology (7-9). There is a direct relationship between body mass index (BMI) and insulin production, and there is sufficient evidence that obesity, especially intra-abdominal fat, is related to the development of insulin resistance (10). Physical activity may increase insulin sensitivity through reduction of intra-abdominal fat deposits; additionally, physical activity, independent of its effects on weight, has been associated with improved glucose metabolism, increased insulin sensitivity, and decreased plasma insulin levels (10). Therefore, we hypothesized that obesity, through BMI and abdominal weight gain, and physical activity may be modifiable risk factors for pancreatic cancer.

Results of previous observational studies on the association between obesity, physical activity, and pancreatic cancer risk have been inconsistent. Of the 20 studies (12 prospective cohorts, refs. 3, 7, 11-20; and eight case-control studies, refs. 21-28) that have reported on the association between BMI and pancreatic cancer risk, 10 report a positive association (7, 11, 13, 16, 17, 19, 21-24) and 10 report no association (3, 5, 12, 14, 15, 18, 20, 25-28). Most early reports that observed no relationship between increasing BMI and risk of pancreatic cancer had limited power to examine a wide range of BMI (3, 15, 18, 20, 25-27), used proxy respondents for case patients (25-28), or did not adjust for important factors, such as smoking, that may significantly modify the association between obesity and pancreatic cancer risk (3, 18, 25, 27). However, more recent studies (since 1995), including a few large prospective cohorts, suggest that obese (BMI 30) individuals may have a higher risk of developing pancreatic cancer (11, 13, 16, 17, 19, 23, 24). One previous study (15) examined the association between pancreatic cancer risk and adult weight gain and reported a nonstatistically significant positive association. To our knowledge, no previous study has examined the association between location of weight gain and pancreatic cancer risk.

Of the seven studies (five prospective cohorts, refs. 3, 12, 14-16; two case-control studies, refs. 22, 29) that have reported on the association between recreational physical activity and pancreatic cancer, four studies found an inverse association (15, 16, 22, 29) and three found no association (3, 12, 14) between physical activity and pancreatic cancer risk. However, in most positive studies, a lower risk of pancreatic cancer generally was observed only with high levels of moderate to vigorous physical activity (15, 22, 29). Only one previous study (16), analyzing data from the Health Professionals Follow-up Cohort and Nurses' Health Study, observed a significant inverse association with moderate-intensity activities or walking/hiking for men and women; but this study found no association with vigorous activity. Consequently, the frequency, intensity, and type of physical activity necessary to influence pancreatic cancer risk remain unclear.

We examined the association of BMI, weight gain, location of weight gain, recreational physical activity, and risk of pancreatic cancer among men and women in the American Cancer Society Cancer Prevention Study II (CPS-II) Nutrition Cohort, a large prospective study in the United States. It should be noted that 38% of pancreatic cancer cases (49 cases in men and 44 cases in women) in this study were also included in the previous publication by Calle et al. (13) on obesity and cancer mortality using the larger CPS-II Mortality Cohort.

	Materials and methods

Top Abstract Introduction Materials and methods Results Discussion References

 
Study Population
Men and women in this analysis were drawn from the 184,190 participants in the CPS-II Nutrition Cohort, which was established in 1992 by the American Cancer Society as a subgroup of the larger 1982 CPS-II baseline mortality cohort (30). Nearly all participants were ages 50 to 74 years at enrollment in 1992, and they completed a 10-page self-administered questionnaire that included questions on demographic, medical, reproductive, behavioral, environmental, and dietary factors. Beginning in 1997, follow-up questionnaires have been sent to cohort members every 2 years to update exposure information and to ascertain newly diagnosed cancers. Questionnaire response rates among living cohort members have been at least 90%. Cohort members who died are identified by routine linkage of the entire cohort with the National Death Index (31).

This analysis is based on 7 years of follow-up. We excluded participants who were lost to follow-up from 1992 to 1999 (n = 8,223), who reported prevalent cancer (except nonmelanoma skin cancer) at baseline (n = 20,934), who had missing or extreme (lowest and highest 0.1%) values of BMI (n = 4,794), who left the baseline recreational physical activity section blank (n = 2,180), or who had missing information on smoking status (n = 1,575). We also excluded individuals who died from any cause within the first year of follow-up to reduce the possibility of undiagnosed disease at baseline (n = 852) and those with an unverified date of diagnosis of pancreatic cancer (n = 5). After all exclusions, the final analytic cohort consisted of 145,627 men and women with a mean age at study entry of 62.9 years (±6.4 SD).

Case Ascertainment
We identified a total of 242 incident pancreatic cancers that occurred between the date of enrollment and August 31, 1999, among those cohort members eligible for analysis. Seventy-nine percent of incident pancreatic cancers (n = 190) were initially identified through automated linkage of the cohort with the National Death Index where pancreatic cancer was listed as a primary or contributory cause of death (International Classification of Diseases, Ninth Revision codes 157 to 157.9 or International Classification of Diseases, Tenth Revision codes C25-C25.9; refs. 32, 33). Additional information for 141 of these interval deaths was obtained through linkage with state cancer registries. Pancreatic cancer cases (n = 41) were also initially identified by self-report on one of the two follow-up questionnaires (1997 and 1999) and subsequently verified by medical records (n = 26) or linkage with state cancer registries (n = 15). A previous study linking cohort participants with state cancer registries has shown that the Nutrition Cohort participants are highly accurate (93% sensitivity) in reporting any past cancer diagnoses (34). Finally, an additional 11 pancreatic cancer cases were reported by the participant as another cancer but were found to be pancreatic cancer upon examination of medical or registry records.

Measures of Obesity and Physical Activity
BMI (weight in kg/height in m²) at baseline was calculated using self-reported weight and height and categorized as follows: 18.5 to 24.9, 25 to 29.9, and 30. According to the WHO definition for obesity, a BMI <25 is considered "normal weight," 25 to 29.9 is "grade 1 overweight," 30 to 39.9 is "grade 2 overweight," and 40 or more is "grade 3 overweight" (35). In this analysis, we refer to BMI of 25 to 29.9 as "overweight" and BMI of 30 as "obese." We also categorized BMI at age 18 (using recalled weight at age 18 reported in 1992) as <21, 21 to 22.9, and 23. BMI <25 in 1992 and BMI <21 at age 18 were the reference groups in their respective analyses.

We categorized adult weight change in kilograms (kg) between age 18 and weight at baseline and categorized as lost >2.27 kg, lost 2.27 kg to gained 4.54 kg (reference group), gained 4.55 to 9.07 kg, gained 9.08 to 13.61 kg, and gained 13.62 kg. Lastly, we categorized location of weight gain using the question "When you gain weight, where on your body do you mainly add the weight: chest and shoulders, waist, hips and thighs, other part of the body, equally all over, or don't gain weight?." Central weight gain was defined as reported weight gain in chest and shoulders or waist, and peripheral weight gain was defined as reported weight gain in hips and thighs or equally all over. The vast majority of individuals categorized as central weight gainers reported weight gain on the waist only (84.2% of men and 80.3% of women), and a small percent of those included as central weight gainers gained weight on the waist and chest and shoulders (13.7% of men and 17.2% of women). Most men (95%) categorized as peripheral weight gainers reported weight gain equally all over, whereas reported weight gain in hips and thighs or equally all over was approximately equal in women categorized as peripheral weight gainers. Men and women with other responses that could not be clearly categorized into one of these two groups were excluded from analyses examining location of weight gain.

Baseline recreational physical activity information was collected using the question "During the past year, what was the average time per week you spent at the following kinds of activities: walking, jogging/running, lap swimming, tennis or racquetball, bicycling or stationary biking, aerobics/calisthenics, and dancing?." Response to each activity could be "none," "1 to 3 h/wk," "4 to 6 h/wk," or "7+ h/wk." Summary metabolic equivalent (MET) hours per week were calculated for each participant. A MET is the ratio of metabolic rate during a specific activity to resting metabolic rate (36). The summary MET score for each participant was calculated by multiplying the hours spent engaged in each activity (0 for none, 1 for 1-3 h/wk, 4 for 4-6 h/wk, and 7 for 7+ h/wk) times the MET score estimated for each activity according to the Compendium of Physical Activities (36). Due to the older age of this population, MET-hours per week were calculated using the lowest value in a category of hours spent and moderate intensity MET values for each activity to provide conservatively estimated summary measures. The following MET scores were used (36): 3.5 for walking, 7 for jogging/running, 7 for lap swimming, 6 for tennis or racquetball, 4 for bicycling/stationary biking, 4.5 for aerobics/calisthenics, and 3.5 for dancing.

In 1992, we also asked participants to recall recreational physical activity at age 40 based on the question, "At age 40, what was the average time per week you spent at the following kinds of activities: walking, jogging/running, lap swimming, tennis or racquetball, bicycling or stationary biking, aerobics/calisthenics, and dancing?." MET-hours per week at age 40 were then summarized using the same method as baseline recreational activity described above. Recreational physical activity at baseline and age 40 were categorized into MET-hours per week as none, >0 to 7, >7 to 17.5, >17.5 to 31.5, or >31.5. People who reported no recreational physical activity were used as the reference group. Another measure of past physical activity was available using the historical 1982 CPS-II questionnaire data, where participants reported behavior 10 years before baseline. In 1982, participants were asked "How much exercise do you get (work or play): none, slight, moderate, heavy?." Exercise in 1982 was categorized as none/slight, moderate, or heavy; people who responded "none" and "slight" were combined due to small numbers and were used as the reference group. Physical activity at age 40 (as recalled in 1992) and exercise reported in 1982 were combined with baseline 1992 exposure information to assess whether risk of pancreatic cancer was reduced among participants who consistently reported being physically active.

Statistical Analysis
We calculated age-standardized pancreatic cancer incidence rates for measures of obesity (BMI at baseline and age 18, adult weight gain, location of weight gain) and recreational physical activity (MET-hours in 1992 and age 40, exercise level in 1982) standardized to the sex-specific age distribution of CPS-II Nutrition Cohort participants. We used Cox proportional hazards modeling (37) to calculate hazards rate ratios (RR) and corresponding 95% confidence intervals (CI) to examine the relationship between measures of obesity, recreational physical activity, and pancreatic cancer. For each BMI and physical activity exposure variable, we assessed risk in two models, one adjusted only for age and the other adjusted for age and potential confounding factors. All Cox models were stratified on exact year of age at enrollment. Potential confounders included in the multivariate models smoking status (never, current, former) and time since quitting for former smokers (<10, 10-19, and >20 years), height (quintiles), alcohol intake (never,<1 drink per day, 1 drink per day, >1 drink per day, missing), education (high school graduate, some college, college graduate and above, missing), first-degree family history of pancreatic cancer (yes, no), personal history of gallbladder disease (yes, no), personal history of diabetes at baseline (yes, no), total caloric intake (quartiles), fruit and vegetable intake (quartiles), and gender (male, female). Furthermore, all multivariate models were mutually adjusted for BMI and physical activity.

Trend tests for BMI, adult weight gain, and physical activity were conducted by assigning the mean BMI, weight change (in lb) or MET value, respectively, within each category to that category. To test whether any of the above-described potential confounders significantly modified the association between measures of obesity or recreational physical activity and pancreatic cancer risk, we constructed multiplicative interaction terms between each main exposure variable and all covariates. We also constructed interaction terms between measures of obesity and recreational physical activity to test for effect modification between these factors. Due to small numbers in some strata, categories of potential effect modifiers were collapsed. To test for any violation of the Cox proportional hazard assumption, we created interaction terms between measures of obesity and recreational physical activity with time. Statistical interaction and the Cox proportional hazard assumption were assessed in multivariate models using the likelihood ratio test and P < 0.05 was considered statistically significant (38).

	Results

Top Abstract Introduction Materials and methods Results Discussion References

 
The mean baseline BMI in this study population was 26.4 (±3.5 SD) among men and 25.6 (±4.4 SD) among women. Thirty-five percent (n = 34,734) of men and 32% (n =24,582) of women were overweight (BMI 25-29.9) and 14% (n = 9,915) of men and 15% (n = 11,740) of women were obese (BMI 30). Approximately 12% (n = 8,345) of men and 9% (n = 6,908) of women reported no recreational physical activity at baseline (Table 1). Among participants who reported any recreational physical activity at baseline, the median MET expenditure was 14 MET-h/wk for men and 9.5 MET-h/wk for women, which corresponds to 4 and 3 hours, respectively, of moderately paced walking per week. Active participants at all levels of MET expenditure engaged primarily in activities judged to be of low intensity (walking biking, aerobics/calisthenics, or dancing) rather than activities judged to be of moderate/high intensity (jogging/running, swimming, or tennis/racquetball). As expected, physical activity and body mass were inversely correlated, with physically active participants more likely to be leaner. Leaner and more physically active participants also were more likely to report being nonsmokers, not having gained weight since age 18 years, drink alcohol, have no history of diabetes, and have higher educational attainment.

We observed no association between baseline recreational physical activity and risk of pancreatic cancer in this study. Men and women in the highest category of MET-hours per week (>31.5 MET-h/wk) had a relative risk of pancreatic cancer of 1.20 (95% CI, 0.63-2.27) compared with men and women who reported no physical activity at baseline (Table 3). Tests for trend including participants who reported no recreational physical activity (P_trend = 0.97) and excluding participants who reported no recreational physical activity (P_trend = 0.82) were not statistically significant. The lack of association also did not differ when we restricted the analysis to participants engaging in at least some moderate/heavy physical activity compared with those who reported no physical activity or only low-intensity physical activity (data not shown). We also examined the association between pancreatic cancer risk and recreational physical activity at age 40 (reported retrospectively at baseline). Physical activity at age 40 was not associated with risk of pancreatic cancer.

We examined risk of pancreatic cancer in a stratified analysis by smoking status because residual confounding due to smoking has the potential to impact the relationship between BMI and pancreatic cancer risk (13). Risk of pancreatic cancer risk among men and women with BMI 30 compared with <25 was similar when restricting the analysis to never smokers (RR, 1.70; 95% CI, 0.95-3.06). Residual confounding by smoking in relation to BMI and pancreatic cancer risk in this cohort was minimal because there were few smokers. Only nine percent of cohort members reported smoking at baseline and former smokers had a median of 22 years since quitting. There also was no statistical interaction between measures of obesity or baseline recreational physical activity and any of the other potential risk factors examined in this analysis (data not shown).

	Discussion

Top Abstract Introduction Materials and methods Results Discussion References

 
Results from this prospective study support the hypothesis that obesity is associated with approximately a doubling of risk of pancreatic cancer. Higher risk of pancreatic cancer was observed among men and women with higher BMI at baseline and at age 18. The present findings also are consistent in direction and magnitude with six (7, 11, 13, 16, 17, 19) of twelve (3, 7, 11-20) prospective cohort studies, including results included in the large CPS-II Mortality Study (13), and four (21-24) of eight (21-28) case-control studies that found a positive association between BMI and pancreatic cancer risk. There are several possible explanations for the inconsistent findings of obesity and pancreatic cancer risk across previous studies. First, studies that observed a positive association generally examined higher levels of BMI (30) and had larger sample sizes (at least 10 cases in the highest BMI category). Seven (11, 13, 16, 17, 19, 23, 24) of eight (11, 13, 15-17) previous studies that examined an association with BMI of 30 found an increased risk of pancreatic cancer ranging from 20% to 180% (Fig. 1). The one previous study (15) that reported no association with BMI of 30 and pancreatic cancer risk had limited power with only four cases of pancreatic cancer classified as obese.

View larger version (23K): [in this window] [in a new window]   Figure 1. Previous studies (includes only studies with 10 cases in obese category) of obesity (BMI 30 or medical diagnosis) and pancreatic cancer risk.

Our results also support a role of central adiposity, independent of BMI, on pancreatic cancer carcinogenesis, an association that previously has not been examined in observational studies. There is a direct linear relationship between intra-abdominal fat deposits, insulin production, and the development of insulin resistance (reviewed in ref. 10). In vitro studies have shown that insulin binds to the insulin-like growth factor-I receptor and has growth-promoting effects in the pancreas (39). A hyperinsulinemic state also allows increased levels of insulin to pass through pancreatic exocrine cells, bind to the insulin receptor, and trigger mitotic activity (7, 9, 40). Increased insulin also can down-regulate insulin-like growth factor binding protein-I, leaving more bioavailable insulin-like growth factor-I that has been shown to in vitro stimulate cell proliferation (41, 42). As many women tend to gain weight more peripherally, the lack of or weaker magnitude of association observed in some studies in women compared with men (7, 17) may be explained by the role of central adiposity in pancreatic carcinogenesis.

In contrast with several previous studies, we did not observe a relationship between recreational physical activity at baseline and pancreatic cancer risk. The low prevalence of high-intensity activities reported by participants in this cohort may account for the lack of an observed association. In this cohort, we could not examine the more vigorous physical activities that have been associated with reduced risk of pancreatic cancer in previous studies (15, 22, 29). The low-intensity physical activity reported by study participants may be insufficient to improve insulin sensitivity. It is also plausible that the lack of association in our study is due to the timing of the physical activity measure. Pancreatic cancer is generally diagnosed at advanced stages (1), and as a result of the relatively short follow-up period (7 years), pancreatic carcinogenesis may have been initiated before exposure assessment. We evaluated the association after excluding the first 2 years of follow-up and found no differences in risk estimates. Additionally, we evaluated pancreatic cancer risk according to physical activity in 1982 (10 years before baseline) due to the potential for change in physical activity in 1992 due to preclinical disease. We observed a 26% decrease in pancreatic cancer incidence among men and women engaging in moderate physical activity in 1982 compared with men and women engaging in no/slight physical activity in 1982. This finding is consistent with another large prospective cohort study that reported an association with moderate, but not vigorous, physical activity and pancreatic cancer risk (16). Thus, moderate physical activity may be inversely associated with pancreatic cancer risk.

There are a few limitations of our study that should be mentioned. In addition to the limited range of recreational physical activities commonly done by our participants, the lack of individual information on intensity of activities may increase the potential for misclassification of true energy expenditure. Another limitation is that obesity and physical activity measures are self-reported. Furthermore, our physical activity questions have not been validated but physical activity has been previously associated with breast (43) and colon cancer (44) in this cohort. Another limitation is the limited statistical power to examine detailed effect modification between BMI, central weight gain, recreational physical activity, and other covariates, such as smoking or personal history of diabetes. There are many strengths of this study that should also be noted. The prospective design eliminates differential reporting of past exposure information. We were able to control for potential confounding by most known or hypothesized pancreatic cancer risk factors. We had the ability to examine the association between adiposity and pancreatic cancer across a wide range of BMI.

In summary, we observed independent associations between both obesity and the tendency for central weight gain and pancreatic cancer risk. However, we did not observe an association between recreational physical activity and risk of pancreatic cancer in our population of elderly adults. Sufficient biological plausibility exists to warrant additional research to better understand the potential role of physical activity in pancreatic carcinogenesis and the amount, frequency, and intensity of physical activity needed to impact insulin response and other hormonal changes in relation to pancreatic cancer risk. Although evidence recognizing pancreatic cancer as an obesity-related cancer previously has been considered insufficient (10), findings from this study, along with other recent studies, strongly support the role of obesity in pancreatic cancer development.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 8/ 3/04; revised 9/17/04; accepted 9/28/04.

	References

Top Abstract Introduction Materials and methods Results Discussion References

 

1. American Cancer Society. Cancer facts and figures. Atlanta (GA): American Cancer Society; 2004.
2. Coughlin S-S, Calle E-E, Patel A-V, Thun M-J. Predictors of pancreatic cancer mortality among a large cohort of United States adults. Cancer Causes Control 2000;11:915–23.[CrossRef][Medline]
3. Lund-Nilsen T-I, Vateen L-J. A prospective study of lifestyle factors and the risk of pancreatic cancer in Nord-Trondelag, Norway. Cancer Causes Control 2000;11:645–52.[CrossRef][Medline]
4. Villeneuve P-J, Johnson K-C, Hanley A-J-G, Mao Y. Canadian Cancer Registries Epidemiology Research Group. Alcohol, tobacco, and coffee consumption and the risk of pancreatic cancer: results from the Canadian Enhanced Surveillance System case-control project. Eur J Cancer Prev 2000;9:49.[CrossRef][Medline]
5. Everhart J, Wright D. Diabetes mellitus as a risk factor for pancreatic cancer. JAMA 1995;273:1605–9.[Abstract]
6. Calle E-E, Murphy T-K, Rodriguez C, Thun M-J, Heath C-W Jr. Diabetes mellitus and pancreatic cancer mortality in a prospective cohort of United States adults. Cancer Causes Control 1998;9:403–10.[CrossRef][Medline]
7. Gapstur S-M, Gann P-H, Lowe W, Liu K, Colangelo L, Dyer A. Abnormal glucose metabolism and pancreatic cancer mortality. JAMA 2000;283:2552–8.[Abstract/Free Full Text]
8. McCarty M-F. Insulin secretion as a determinant of pancreatic cancer risk. Med Hypotheses 2001;57:146–50.[CrossRef][Medline]
9. Fisher W-E, Boros L-G, Schirmir W-J. Insulin promotes pancreatic cancer: evidence for endocrine influence on exocrine pancreatic tumors. J Surg Res 1996;63:310–3.[CrossRef][Medline]
10. IARC. IARC handbooks on cancer prevention: Weight control and physical activity. Lyon (France): IARC Press; 2002.
11. Samanic C, Gridley G, Chow W, Lubin J, Hoover R-N, Fraumeni J-F. Obesity and cancer risk among white and black United States veterans. Cancer Causes and Control 2004;15:35–43.[CrossRef][Medline]
12. Lee I-M, Sesso H-D, Oguma Y, Paffenbarger R-S. Physical activity, body weight, and pancreatic cancer mortality. Br J Cancer 2003;88:679–83.[CrossRef][Medline]
13. Calle E-E, Rodriguez C, Walker-Thurmond K, Thun M-J. Overweight, obesity, and mortality from cancer in a prospectively studied cohort of U.S. adults. N Engl J Med 2003;348:1625–38.[Abstract/Free Full Text]
14. Stolzenberg-Solomon R-Z, Pietinen P, Taylor P-R, Virtamo J, Albanes D. A prospective study of medical conditions, anthropometry, physical activity, and pancreatic cancer in male smokers (Finland). Cancer Causes Control 2002;13:417–26.[CrossRef][Medline]
15. Isaksson B, Jonsson F, Pedersen N-L, Larsson J, Feychting M, Permert J. Lifestyle factors and pancreatic cancer risk: a cohort study from the Swedish Twin Registry. Int J Cancer 2002;98:480–2.[CrossRef][Medline]
16. Michaud D-S, Giovannucci E, Willett W-C, Colditz G-A, Stampfer M-J, Fuchs C-S. Physical activity, obesity, height, and the risk of pancreatic cancer. JAMA 2001;286:921–9.[Abstract/Free Full Text]
17. Wolk A, Gridley G, Svensson M, Nyren O, McLaughlin J-K. A prospective study of obesity and cancer risk (Sweden). Cancer Causes Control 2001;12:13–21.[CrossRef][Medline]
18. Shibata A, Mack T-M, Paganini-Hill A, Ross R-K, Henderson B-E. A prospective study of pancreatic cancer in the elderly. Int J Cancer 1994;58:46–9.[Medline]
19. Moller H, Mellemgaard A, Lindvig K, Olsen J-H. Obesity and cancer risk: a Danish record-linkage study. Eur J Cancer 1994;30A:344–50.
20. Friedman G-D, Van Den Eeden S-K. Risk factors for pancreatic cancer: an exploratory study. Int J Epidemiol 1993;22:30–7.[Abstract/Free Full Text]
21. Ji B-T, Hatch M-C, Chow W-H, et al. Anthropometric and reproductive factors and the risk of pancreatic cancer: a case-control study in Shanghai, China. Int J Cancer 1996;66:432–7.[CrossRef][Medline]
22. Hanley A-J-G, Johnson K-C, Villeneuve P-J, Mao Y. Canadian Cancer Registries Epidemiology Research Group. Physical activity, anthropometric factors and risk of pancreatic cancer: results from the Canadian Enhanced Cancer Surveillance Program. Int J Cancer 2001;94:140–7.[CrossRef][Medline]
23. Pan S-Y, Johnson K-C, Ugnat A, Wen S-W, Mao Y. The Canadian Cancer Registries Epidemiology Research Group. Association of obesity and cancer risk in Canada. Am J Epidemiol 2004;159:259–68.[Abstract/Free Full Text]
24. Silverman D-T, Swanson C-A, Gridley G, et al. Dietary and nutritional factors and pancreatic cancer: a case-control study based on direct interviews. J Natl Cancer Inst 1998;90:1710–9.[Abstract/Free Full Text]
25. Zatonski W, Przewozniak K, Howe G-R, Maissoneuve P, Walker A-M, Boyle P. Nutritional factors and pancreatic cancer: a case-control study from south-west Poland. Int J Cancer 1991;48:390–4.[Medline]
26. Ghadirian P, Simard A, Baillargeon J, Maisonneuve P, Boyle P. Nutritional factors and pancreatic cancer in the Francophone community in Montreal, Canada. Int J Cancer 1991;47:1–6.[Medline]
27. Howe G-R, Jain M, Miller A-B. Dietary factors and risk of pancreatic cancer: results of a Canadian population-based case-control study. Int J Cancer 1990;45:604–8.[Medline]
28. Bueno De Mesquita H-B, Moerman C-J, Runia S, Maisonneuve P. Are energy and energy-providing nutrients related to exocrine carcinoma of the pancreas? Int J Cancer 1990;46:435–44.[Medline]
29. Inoue M, Tajima K, Takezaki T, et al. Epidemiology of pancreatic cancer in Japan: a nested case-control study from the Hospital-based Epidemiologic Research Program at Aichi Cancer Center (HERPACC). Int J Epidemiol 2003;32:257–62.[Abstract/Free Full Text]
30. Calle E-E, Rodriguez C, Jacobs E-J, et al. The American Cancer Society Cancer Prevention Study II Nutrition Cohort—rational, study design, and baseline characteristics. Cancer 2002;94:500–11.[CrossRef][Medline]
31. Calle E-E, Terrell D-D. Utility of the National Death Index for ascertainment of mortality among Cancer Prevention Study II participants. Am J Epidemiol 1993;137:235–41.[Abstract/Free Full Text]
32. WHO. International classification of diseases ninth revision. Manual of the international statistical classification of disease, injuries, and causes of death. 1. Geneva: WHO; 1977.
33. WHO. International statistical classification of diseases and related health problems tenth revision. 1. Geneva: WHO; 1992.
34. Bergmann M, Calle E, Mervis C, Miracle-McMahill H, Thun M, Heath C Jr. Validity of self-reported cancers in a prospective cohort study in comparison to data from state cancer registries. Am J Epidemiol 1998;147:556–62.[Abstract/Free Full Text]
35. WHO. Physical status: the use and interpretation of anthropometry: report of a WHO Expert Committee 1995;854: 1–452.
36. Ainsworth B-E, Haskell W-L, Leon A-S, et al. Compendium of physical activities: classification of energy costs of human physical activities. Med Sci Sports Exerc 1993;25:71–80.[Medline]
37. Cox D. Regression models and life tables. J R Stat Soc 1972;34:187–220.
38. Kleinbaum G, Kupper L, Morgenstern H. Epidemiologic research: principles and quantitative methods. New York: Van Nostrand Reinhold Co.; 1982.
39. LeRoith D. Seminars in medicine of the Beth Israel Deaconess Medical Center: insulin-like growth factors. N Engl J Med 1997;336:633–40.[Free Full Text]
40. Williams J-A, Goldfine I-D. The insulin-pancreatic acinar axis. Diabetes 1985;34:980–6.[Abstract]
41. McCarty M-F. Up-regulation of IGF binding protein-1 as an anticarcinogenic strategy: relevance to caloric restriction, exercise, and insulin resistance. Med Hypotheses 1997;48:297–308.[CrossRef][Medline]
42. Conover C-A, Lee P-D-K, Kanaley J-A, Clarkson J-T, Jensen M-D. Insulin regulation of insulin-like growth factor binding protein-1 in obese and nonobese humans. J Clin Endocrinol Metab 1992;74:1355–60.[Abstract]
43. Patel A-V, Calle E-E, Bernstein L, Wu A-H, Thun M-J. Recreational physical activity and risk of postmenopausal breast cancer in a large cohort of US women. Cancer Causes Control 2003;14:519–29.[CrossRef][Medline]
44. Chao A, Connell C-J, Jacobs E-J, et al. Amount, intensity, and timing of recreational physical activity in relation to colon and rectal cancer in older adults—The Cancer Prevention Study II Nutrition Cohort. Cancer Epidemiol Biomarkers Prev 2004;13(12):2187–95.[Abstract/Free Full Text]

This article has been cited by other articles:

				Y. Bao and D. S. Michaud Physical Activity and Pancreatic Cancer Risk: A Systematic Review Cancer Epidemiol. Biomarkers Prev., October 1, 2008; 17(10): 2671 - 2682. [Abstract] [Full Text] [PDF]

				C. de Martel, A. E. Llosa, G. D. Friedmana, J. H. Vogelman, N. Orentreich, R. Z. Stolzenberg-Solomon, and J. Parsonnet Helicobacter pylori Infection and Development of Pancreatic Cancer Cancer Epidemiol. Biomarkers Prev., May 1, 2008; 17(5): 1188 - 1194. [Abstract] [Full Text] [PDF]

				R. Z. Stolzenberg-Solomon, K. Adams, M. Leitzmann, C. Schairer, D. S. Michaud, A. Hollenbeck, A. Schatzkin, and D. T. Silverman Adiposity, Physical Activity, and Pancreatic Cancer in the National Institutes of Health-AARP Diet and Health Cohort Am. J. Epidemiol., March 1, 2008; 167(5): 586 - 597. [Abstract] [Full Text] [PDF]

				A. Berrington de Gonzalez, J. E. Yun, S.-Y. Lee, A. P. Klein, and S. H. Jee Pancreatic Cancer and Factors Associated with the Insulin Resistance Syndrome in the Korean Cancer Prevention Study Cancer Epidemiol. Biomarkers Prev., February 1, 2008; 17(2): 359 - 364. [Abstract] [Full Text] [PDF]

				M. L. McCullough, A. V. Patel, R. Patel, C. Rodriguez, H. S. Feigelson, E. V. Bandera, T. Gansler, M. J. Thun, and E. E. Calle Body Mass and Endometrial Cancer Risk by Hormone Replacement Therapy and Cancer Subtype Cancer Epidemiol. Biomarkers Prev., January 1, 2008; 17(1): 73 - 79. [Abstract] [Full Text] [PDF]

				G. K Reeves, K. Pirie, V. Beral, J. Green, E. Spencer, D. Bull, and Million Women Study Collaboration Cancer incidence and mortality in relation to body mass index in the Million Women Study: cohort study BMJ, December 1, 2007; 335(7630): 1134 - 1134. [Abstract] [Full Text] [PDF]

				E. E Calle Obesity and cancer BMJ, December 1, 2007; 335(7630): 1107 - 1108. [Full Text] [PDF]

				D. S. Michaud, B. Wolpin, E. Giovannucci, S. Liu, B. Cochrane, J. E. Manson, M. N. Pollak, J. Ma, and C. S. Fuchs Prediagnostic Plasma C-Peptide and Pancreatic Cancer Risk in Men and Women Cancer Epidemiol. Biomarkers Prev., October 1, 2007; 16(10): 2101 - 2109. [Abstract] [Full Text] [PDF]

				B. M. Wolpin, D. S. Michaud, E. L. Giovannucci, E. S. Schernhammer, M. J. Stampfer, J. E. Manson, B. B. Cochrane, T. E. Rohan, J. Ma, M. N. Pollak, et al. Circulating Insulin-Like Growth Factor Binding Protein-1 and the Risk of Pancreatic Cancer Cancer Res., August 15, 2007; 67(16): 7923 - 7928. [Abstract] [Full Text] [PDF]

				E. Schernhammer, B. Wolpin, N. Rifai, B. Cochrane, J. A. Manson, J. Ma, E. Giovannucci, C. Thomson, M. J. Stampfer, and C. Fuchs Plasma Folate, Vitamin B6, Vitamin B12, and Homocysteine and Pancreatic Cancer Risk in Four Large Cohorts Cancer Res., June 1, 2007; 67(11): 5553 - 5560. [Abstract] [Full Text] [PDF]

				A. L. Jurj, W. Wen, Y.-B. Xiang, C. E. Matthews, D. Liu, W. Zheng, and X.-O. Shu Reproducibility and Validity of the Shanghai Men's Health Study Physical Activity Questionnaire Am. J. Epidemiol., May 15, 2007; 165(10): 1124 - 1133. [Abstract] [Full Text] [PDF]

				C. Rodriguez, S. J. Freedland, A. Deka, E. J. Jacobs, M. L. McCullough, A. V. Patel, M. J. Thun, and E. E. Calle Body Mass Index, Weight Change, and Risk of Prostate Cancer in the Cancer Prevention Study II Nutrition Cohort Cancer Epidemiol. Biomarkers Prev., January 1, 2007; 16(1): 63 - 69. [Abstract] [Full Text] [PDF]

				A. Ansary-Moghaddam, R. Huxley, F. Barzi, C. Lawes, T. Ohkubo, X. Fang, S. H. Jee, M. Woodward, and Asia Pacific Cohort Studies Collaboration The Effect of Modifiable Risk Factors on Pancreatic Cancer Mortality in Populations of the Asia-Pacific Region Cancer Epidemiol. Biomarkers Prev., December 1, 2006; 15(12): 2435 - 2440. [Abstract] [Full Text] [PDF]

				L. H. Kushi, T. Byers, C. Doyle, E. V. Bandera, M. McCullough, T. Gansler, K. S. Andrews, M. J. Thun, and The American Cancer Society 2006 Nutrition and Phy American Cancer Society Guidelines on Nutrition and Physical Activity for Cancer Prevention: Reducing the Risk of Cancer With Healthy Food Choices and Physical Activity CA Cancer J Clin, September 1, 2006; 56(5): 254 - 281. [Abstract] [Full Text] [PDF]

				A. Berrington de Gonzalez, E. A. Spencer, H. B. Bueno-de-Mesquita, A. Roddam, R. Stolzenberg-Solomon, J. Halkjaer, A. Tjonneland, K. Overvad, F. Clavel-Chapelon, M.-C. Boutron-Ruault, et al. Anthropometry, Physical Activity, and the Risk of Pancreatic Cancer in the European Prospective Investigation into Cancer and Nutrition. Cancer Epidemiol. Biomarkers Prev., May 1, 2006; 15(5): 879 - 885. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Patel, A. V. Articles by Calle, E. E. Search for Related Content PubMed PubMed Citation Articles by Patel, A. V. Articles by Calle, E. E.