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Pituitary Adenomas in Sweden between 1958 and 1991: Incidence, Survival, and Mortality¹

Department of Cancer Epidemiology, Karolinska University Hospital (B.N., E.G.-K.), SE-17176 Stockholm; Research Center for Endocrinology and Metabolism, Sahlgrenska University Hospital (B.-Å.B.), SE-41345 Goteborg; and Department of Women and Child Health, St. Goran’s Hospital, Karolinska Institute (B.J.), SE-17177 Stockholm, Sweden

Address all correspondence and requests for reprints to: Prof. Bengt-Åke Bengtsson, Research Center for Endocrinology and Metabolism, Sahlgrenska University Hospital, SE-41345 Goteborg, Sweden.

	Abstract

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The objective of the present study was to determine the incidence of pituitary adenomas (PAs) and the associated rates and causes of mortality in a large population. The study population comprised 2279 patients (1010 women and 1269 men) of all individuals (n = 3321) with pituitary tumors included in the Swedish Cancer Registry between 1958 and 1991. The mean age (±SD) at diagnosis was 52.3 ± 15.7 yr. The age-standardized incidence of PA increased significantly from approximately 6 cases/million inhabitants in 1958 to 11 cases/million in 1991. The age-specific incidence peaked between 60–70 yr of age in both sexes. Excess mortality was found in the study population. The total number of deaths was 842. The standardized mortality ratio (SMR) for the study population was 2.0. The SMR for women (2.3) was significantly (P < 0.01) higher than that for men (1.9). Cardiovascular diseases were the most common cause of mortality among patients, accounting for 346 deaths (SMR, 1.6). The difference between the sexes was significant (men, 1.4; women, 1.8; P < 0.05). Cerebrovascular death occurred in 97 patients (SMR, 2.4), with no significant difference between men (SMR, 2.5) and women (SMR, 2.2). Excess mortality was also observed for tumors, endocrine diseases, and gastrointestinal diseases. These findings suggest that the annual incidence of PA is increasing. Possible explanations are improved diagnostic skill and/or increased awareness of pituitary diseases among physicians. However, a real increase in the incidence of PA cannot be ruled out.

	Introduction

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LITTLE IS KNOWN of the long term prognosis of patients with nonsecreting pituitary adenomas (PAs). Hypopituitarism acquired in adult life is often caused by pituitary or peripituitary tumors and their treatment and is generally severe (1). Patients with acquired hypopituitarism require hormone substitution to maintain the function of the adrenal, thyroid, and somatotropic axes. In a previous study, Swedish patients with verified hypopituitarism were found to have an increased overall mortality rate, due mainly to cardiovascular disease (2). Similar results were reported from a second Swedish study of patients with hypopituitarism who had undergone an operation for PA (3). A study conducted in the United Kingdom also revealed an increased mortality rate in patients with hypopituitarism, but did not support the findings of the Swedish studies that the excess deaths were due in part to cardiovascular disease (4). These studies included patients with different causes of hypopituitarism, such as pituitary adenoma, craniopharyngioma, and meningioma.

The main weakness of the previous Swedish and United Kingdom studies (2, 3, 4) was the limited size of the cohorts. The objective of this study, therefore, was to analyze the incidence of PA and the mortality rates and causes of death of affected individuals in the whole of Sweden, which has a population of approximately 8.5 million.

	Subjects and Methods

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Sweden has a nationwide cancer registry that was established in 1958. Notification of malignant and certain benign tumors is compulsory for the clinician responsible for a case and also for any pathologist/cytologist involved in the diagnostic procedure. Each new primary tumor in an individual is recorded as a separate case allocated to the same individual by an identification number (year, month, and date of birth and a four-digit serial number). The registry follows the guidelines issued by the WHO. Coding of diagnoses is according to the International Classification of Diseases, Injuries, and Causes of Death, seventh revision (ICD 7) (5).

Since the 1970s, the primary processing of cancer notifications has taken place at six regional cancer registries situated in Umea, Uppsala, Stockholm, Linkoping, Goteborg, and Lund. Each regional cancer registry supplies processed data to the Swedish Cancer Registry, which is responsible for coordination of the material. Notification forms for patients diagnosed between 1958 and 1984 are stored at the Swedish Cancer Registry, managed by the National Board of Health and Welfare. Since 1985, the original cancer notification forms have been filed and stored at the regional registries (oncology centers). According to the Swedish National Board of Health and Welfare (6), 98% of all diagnosed cases of tumor are calculated to be have been reported to the Cancer Registry.

Patients with pituitary tumors (code 195.3, ICD 7) diagnosed between 1958 and 1991 constituted the population studied. The original cancer notification forms for these patients were checked to determine whether they contained information on acromegaly or Cushing’s disease.

The Swedish Cancer Registry provided data for all individuals (n = 3321) with pituitary tumors. After exclusion of individuals with pituitary malignancies (n = 87), those who had died less than 1 month after diagnosis (n = 497), those with acromegaly (n = 352) or Cushing’s disease (n = 33), and those for whom the original notification form was missing (n = 73), 2279 individuals with PA remained for analysis (1010 women and 1269 men).

The diagnosis of PA was based on histological examination in 79.8% of cases, radiological examination in 11.7%, clinical examination in 2.3%, postmortem histological examination in 5.4%, and surgery without histological examination in 0.7%. The age-standardized incidence of PA per calendar year between 1958 and 1991 and the age-specific incidence of PA were calculated for men and women separately.

The expected numbers of deaths due to various diseases were calculated from annually published data from the Swedish National Central Bureau of Statistics. These data (for example, see Ref. 6) are specific for the cause of death, gender, calendar year, and age. The standardized mortality ratio (SMR) is defined as the ratio of the observed to the expected number of deaths.

Causes of death for the study population were obtained from the Swedish Cancer Registry. The primary cause of death was coded according to ICD 6–9. Vascular diseases were defined according to ICD9 codes 390–459. Codes 430–438 constitute deaths due to cerebrovascular diseases. Tumors were coded according to ICD7.

Statistical methods

The 95% confidence interval (CI) for disease-specific SMRs was calculated by treating the observed number as a Poisson variable and the expected number as fixed. The 95% CIs are given in parentheses after the SMR. Simple linear regression was performed on the incidence of PA in Sweden, standardized for age to the Swedish population in 1975.

Five-year excess mortality rates (EMRs) were calculated. The EMR in year 5 is defined as 1 minus the cumulative relative survival rate (CRSR) in year 5: EMR₅ = 1 - CRSR₅. For years 10 and 15 the EMR₁₀ = (CRSR₅ - CRSR₁₀)/CRSR₅, and the EMR₁₅ = (CRSR₁₀ - CRSR₁₅)/CRSR₁₀.

Multivariate survival analysis (Cox regression) (7), using the background factors age, calendar year, geographical region, and gender, was also carried out. The log-rank test was used to test survival differences between men and women. The standard statistical computer program SPSS (version 7.5, SPSS, Inc., Chicago, IL) was used for analyses.

	Results

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Population characteristics

The mean age (±SD) at diagnosis was 52.3 ± 15.7 yr; mean ages for men and women were 53.8 ± 14.7 and 50.3 ± 16.6 yr, respectively. Women constituted 44.3% of the patients.

The mean follow-up time from diagnosis to death or until December 1991 was 10.6 ± 8.5 yr (men, 9.9 ± 8.2 yr; women, 11.6 ± 8.8 yr). The mean follow-up time for survivors was 11.9 ± 8.6 yr, and that for patients diseased before 1992 was 8.5 ± 7.9 yr.

Incidence

The mean age-standardized incidence for the diagnosis of PA increased significantly during the study period, from approximately 6 cases/million inhabitants in 1958 to 11/million in 1991. This increase was seen in both men and women (Fig. 1). The age-specific incidence peaked between 60–70 yr of age for both sexes (Fig. 2). Between 1958–1979, the average age and sex standardized annual reported incidence per yr in Sweden of PAs was 7.13/million inhabitants; after 1980, it was 9.76 (P < 0.001).

View larger version (14K): [in this window] [in a new window]   Figure 1. Age- and sex-standardized incidence of pituitary adenomas in Sweden per calendar year between 1958 and 1991. The slopes are significantly positive (P < 0.007).

View larger version (14K): [in this window] [in a new window]   Figure 2. Age- and sex-specific incidence of pituitary adenomas in Sweden between 1958 and 1991.

The median survival time was 18.2 yr for men and 24.8 yr for women (P < 0.001). The estimated 10-yr survival was 68.9% for men and 76.4% for women (Fig. 3).

View larger version (12K): [in this window] [in a new window]   Figure 3. Sex-specific cumulative survival of patients suffering from pituitary adenomas in Sweden between 1958 and 1991. The difference in survival between males and females is significant (P < 0.001).

Mortality

In total, 842 (37%) of the original cohort had died by the time of follow-up (325 women and 517 men). The overall SMR was 2.0 (CI, 1.9–2.2; Fig. 4a); the SMRs for men and women were 1.9 (CI, 1.7–2.1) and 2.3 (CI, 2.1–2.5), respectively.

View larger version (12K): [in this window] [in a new window]   Figure 4. Number of deaths due to all causes (a), cardiovascular diseases (b), and cerebrovascular diseases (c) in patients suffering from pituitary adenomas in Sweden between 1958 and 1991.

The cause of death was known in 832 of the 842 deaths; the causes of death of the patients are detailed in Table 2. Cardiovascular disease was the cause of death in 346 patients. The mean age at death was 72.3 ± 9.0 yr. The overall SMR was 1.6 (CI, 1.4–1.7); the SMRs for men and women were 1.4 (CI, 1.3–1.7) and 1.8 (CI, 1.5–2.1), respectively. In patients between 40–69 yr of age, the overall SMR for cardiovascular deaths was 3.6 (CI, 3.2–4.1; Fig. 4b); the SMRs for men and women were 3.1 (CI, 2.6–3.5) and 5.5 (CI, 4.3–6.6), respectively (P < 0.001).

Excess mortality was also observed for tumors; the primary cause of death was given as tumor in 244 patients, and the overall SMR was 2.4 (CI, 2.1–2.7). After exclusion of patients in whom pituitary tumor was the primary cause of death (n = 95), the SMR decreased to 1.4 (CI, 1.21–1.7). No significant difference between the sexes was observed. The SMR for malign neoplasms was 1.5 (CI, 1.2–1.7). This decreased to a statistically insignificant level when the 38 cases of "other endocrine glands," that is pituitary-related diseases, were subtracted from the observed number (n = 148). However, 18 patients died from malignant tumors of the brain, with a SMR of 7.1 (CI, 4.2–11.3).

Endocrine diseases were the cause of death in 116 patients, with a SMR of 16.1 (CI, 13.2–19.0). In these 116 subjects, the cause of death was pituitary related in 106 patients; diabetes insipidus was the cause of death in 23 patients. Seven patients died as a result of diabetes mellitus, and 3 patients died as a result of adrenal insufficiency. Twenty-eight patients died from gastrointestinal diseases, with a SMR of 2.0 (CI, 1.3–2.9).

	Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

 
The annual age- and sex-standardized incidence of PA increased during the 33-yr study period from approximately 6 to 11/million inhabitants. To our knowledge, this is the first report suggesting that the annual incidence of PA is increasing. Furthermore, patients that were diagnosed more recently lived longer than those diagnosed earlier. Possible explanations are improved diagnostic skill, improved surgical techniques, and/or increased awareness of pituitary diseases among physicians. However, a real increase in the incidence of PA cannot be ruled out.

In contrast to usual observations in tumor epidemiology, the EMR increased after diagnosis for both men and women. During the first 10 yr after diagnosis, the EMR was approximately 15%; however, between 10–15 yr after diagnosis, the EMR increased to approximately 20%. Patients who were diagnosed more recently lived longer than those who were diagnosed earlier. These observations suggest that the causes of excess mortality were not linked to the PA per se, as most of them were probably removed by surgery, but were associated with other factors caused by the PA or its treatment, such as the development of hypopituitarism and the adequacy of its subsequent treatment.

The main finding from this retrospective registry study of 2279 patients with PA was a significant increase in overall mortality, mainly as a result of cardiovascular disease. The increased risk was significant for both cardiac and cerebrovascular deaths.

Changes in death rates in the general Swedish population during the 33-yr study period have been considered in the calculations. Expected mortality was obtained from cause-, sex-, calendar year-, and 5-yr age group-specific death rates for Sweden. Furthermore, we have no reason to believe that the patients differed from the general population with respect to variables such as consumption of alcohol, smoking habits, and ethnic or socio-economic background. If anything, there is a suspicion that hypopituitary patients smoke less than the general population (8).

Information obtained from the Swedish Cause of Death register has proved to be accurate for cardiovascular diseases (9). In the present study, however, it is conceivable that cardiovascular deaths have been underestimated, as there were 116 patients reported to have died from an endocrine disorder and 96 reported to have died from a benign or unspecified tumor. Such a suspicion is supported by the observations of Rosén and Bengtsson (2) and Bulow et al. (3), who reported that 4 of 19 and 15 of 17 patients, respectively, were classified as having died as a result of pituitary tumors when, in fact, they had died from cardiovascular causes.

Consistent with the results reported by Rosén and Bengtsson (2) and Bulow et al. (3), there was an increased risk of death from cardiovascular disease in the present study. The increase in cardiovascular deaths was most prominent in the 40- to 69-yr-old group. In contrast to the results presented by Bulow et al. (3), the increase in deaths from cerebrovascular causes did not differ significantly between the sexes, but, as shown previously (3), the increased cerebrovascular mortality was pronounced even in the younger patients.

Replacement therapy with cortisone acetate, thyroid hormones, and sex hormones has been used for more than 40 yr in the treatment of hypopituitarism. GH is usually the first hormone to decrease in the development of hypopituitarism. During the last 10 yr, the consequences of untreated growth hormone deficiency in adults have been delineated (10), and a number of cardiovascular risk factors, such as visceral obesity, high/low density lipoprotein cholesterol ratio, and blood pressure, have been found to improve after GH replacement therapy (11, 12). In addition cardiac function has been reported to improve after GH treatment (13, 14). Imperfect conventional replacement therapy and untreated GH deficiency might therefore explain the increased mortality due to cardiovascular disorders found in the present study.

The increased incidence of deaths resulting from malignant brain tumors is in contrast to that in previous studies (2, 3). In addition, there was a nonsignificant increase in leukemia. It is conceivable that several patients were treated with pituitary irradiation after surgery, which could explain the increase in these types of tumors (15).

The increased SMR for gastrointestinal diseases is surprising. Hypothetically, patients with acute gastrointestinal disorders in need of acute surgical care might not have been properly treated with corticosteroids in the event of concomitant ACTH deficiency.

In the present study we have not analyzed the incidence of pituitary failure for practical reasons. However, we can assume that most patients suffered from macroadenomas, which are associated with a high incidence of concomitant pituitary failure (16). In addition, 80% of the patients were operated upon, which suggests that most of the tumors were macroadenomas.

In conclusion, in this large cohort of subjects with pituitary adenoma reported to the Swedish Cancer Registry between 1958 and 1991, the incidence of pituitary adenomas was found to increase. In addition, excess mortality was found in the study population, mainly due to increased cardiovascular mortality.

	Footnotes

 
¹ This work was supported by Pharmacia & Upjohn, Inc. and the Swedish Medical Research Council (Grant 244115707).

Received March 16, 1999.

Revised November 23, 1999.

Accepted December 15, 1999.

	References

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4. Bates AS, Van’t Hoff W, Jones PJ, Clayton RN. 1996 The effect of hypopituitarism on life expectancy. J Clin Endocrinol Metab. 81:1169–1172.[Abstract]
5. WHO. 1955 International classification of diseases: manual of the international statistical classification of diseases, injuries, and causes of death based on the recommendations of the seventh revision conference, 1955, and adopted by the ninth World Health Assembly under the WHO Nomenclature Regulations. Geneva: WHO
6. National Board of Health and Welfare. The Cancer Registry. 1996 Cancer incidence in Sweden 1993. Stockholm: Center for Epidemiology; 10.
7. Cox DR. 1972 Regression models and life tables. J R Stat Soc. B34:187.
8. Rosén T, Edén S, Larson G, Wilhelmsen L, Bengtsson B-Å. 1993 Cardiovascular risk factors in adult patients with growth hormone deficiency. Acta Endocrinol (Copenh). 129:195–200.[Medline]
9. De Faire U, Friberg L, Lorich U, Lundman T. 1976 A validation of cause-of-death certification in 1156 deaths. Acta Med Scand. 200:223–228.[Medline]
10. Cuneo RC, Salomon F, McGauley GA, Sonksen PH. 1992 The growth hormone deficiency syndrome in adults. Clin Endocrinol (Oxf). 37:387–397.[Medline]
11. Bengtsson B-Å. 1993 The consequences of growth hormone deficiency in adults. Acta Endocrinol (Copenh). 128(Suppl 2):2–5.
12. Carroll P, Christ ER, Bengtsson B-Å, et al. 1998 Growth hormone deficiency in adulthood and the effects of growth hormone replacement: a review. J Clin Endocrinol Metab. 83:382–395.[Abstract/Free Full Text]
13. Merola B, Citadini A, Colao A, et al. 1993 Cardiac structural and functional abnormalities in adult patients with growth hormone deficiency. J Clin Endocrinol Metab. 77:1658–1661.[Abstract]
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