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Introduction
Excess of body weight (overweight and obesity) is currently acknowledged as one of the most important challenges worldwide in public health. This is due to its magnitude, the rapid increase and negative repercussions on the affected population's health. Mexico is a country with a rising trend in diseases associated with poor nutrition and their comorbidities1.
Benign prostatic hyperplasia (BPH) is a urologic disease with a high prevalence in males older than 60 years old2. The prevalence is greater in white and Afro-American males; however, it tends to be more severe and progressive in Afro-Americans, possibly due to higher testosterone levels, > 5-alpha reductase activity, androgen receptor expression, and growth factor activity in this population3. Although multiple inflammatory, hormonal, and environmental factors and lifestyle can predispose to this condition, they have yet to be completely defined4.
Furthermore, there is enough evidence that suggests obesity as stimulating factor of BPH5. Different studies reveal that the increase of adipocytes, determined by anthropometric measurements, is positively associated with prostatic volume5. The greater quantity of adipose tissue, the more prostatic volume. Therefore, obesity is directly associated with prostatic enlargement. A recent analysis of more than 16,000 specimens of radical prostatectomy has validated these findings and reveals the association that for each kg/m2, there is an increase of 0.45 g in the total of prostatic weight5.
In Mexico, it is poorly known the association between BPH and obesity. Recently, it has been suggested that an individual with obesity can be risk factor for BPH and lower urinary tract symptoms. Despite the existence of multiple studies international wise, research has not been done at national level about the correlation between body mass index (BMI) and prostatic volume with the severity of lower urinary tract symptoms. The aim of this study was to define the relation between the lower urinary tract symptoms and prostatic anatomic characteristics in patients with obesity and severe obesity.
Materials and methods
A comparative, cross-sectional study was conducted from October 2018 to November 2018. The population included was male patients between 60 and 80 years old with lower urinary tract symptoms and prostatic volume > 30 g, measured by suprapubic ultrasound, that were willing to participate and signed informed consent. Exclusion criteria were prostatic specific antigen (PSA) equal or > 4 ng/dl. The anthropometric evaluation was performed to measure weight and height. Weight balance and telescopic height measuring rod were used and measures were expressed in centimeters and grams. The WHO criteria were employed to determine overweight and obesity.
Patients included in this study were divided into two groups according to the BMI (obesity and severe obesity), Group 1 had a BMI ≤ 34.9 and Group 2 had a BMI of 35-39.9.
To evaluate these symptoms, the International Prostatic Symptoms Score (IPSS) was used. A score of 0-7 indicates mild symptoms, 8-19 indicates moderate symptoms, and 20-35 indicates severe symptoms.
The variables were age, weight, and size, BMI, prostatic volume measured by ultrasound, PSA, IPSS, and finasteride treatment. Descriptive statistic on IBM program SPSS v25 for Mac was used, as well as frequency, percentages, central tendency measures, and dispersion, Fisher's exact test, and Chi-square.
The sampling was deterministic, given by the total of patients that fulfilled inclusion criteria in the time frame of the study.
The research protocol was duly authorized by the local ethics and research committee of the participating medical unit under the registration R-2018-2101-062. Confidentiality of the patients was maintained at all times.
Results
Five hundred and thirty-seven patients were surveyed, only 100 patients fulfilled inclusion criteria, which delivers a sample prevalence of 1.862. Mean values were age 68.73, standard deviation (SD) 5.44 years; weight 84.98, SD 7.11 kg; size 1.61, SD 0.05 m; and BMI 32.62, SD 2.17 and 36 (36%) were on finasteride treatment on therapeutic doses. Mean ultrasonographic prostatic size was 69.09, SD 33.93 cm3 and quantification of PSA 1.94, SD 1.07 ng/dl.
Cronbach's alpha for internal consistency of IPSS delivered 0.272 for urine storage, 0.601 for urine voiding, and a total punctuation of 0.748 (Table 1).
Table 1 Internal consistency of IPSS applied to patients
| Symptom | Chronbach's alpha | |
|---|---|---|
| Urine storage | Incomplete emptying Intermittency Urgency | 0.272 |
| Voiding | Straining Nocturia Weak stream Frequency | 0.601 |
| Total score 0.748 |
IPSS: International Prostate Symptom Score.
Regarding the relation between the grade of prostatic enlargement and medical treatment, 36 patients were administered finasteride and 64 were not; no significant statistical differences were found (p = 0.17), details are shown in table 2. In addition, differences between BMI and ultrasonographic prostatic measurements in both groups delivered a value of p = 0.92 (Table 3).
Table 2 Prostatic enlargement grading and finasteride treatment
| Finasteride treatment | χ2 | p | CI 95 | % | |||
|---|---|---|---|---|---|---|---|
| With finasteride | No finasteride | Total | |||||
| Prostatic enlargement grading | 3.75 | 0.17 | 0.96 | 0.24 | |||
| II | 9 | 28 | 37 | ||||
| III | 16 | 19 | 35 | ||||
| IV | 11 | 17 | 28 | ||||
| Total | 36 | 64 | 100 | ||||
CI: confidence interval, p: probability. χ2: Chi-square; %: percentage.
Table 3 Differences between prostatic measurement by ultrasound in both groups of patients
| Prostatic measurement by ultrasound | ||||
|---|---|---|---|---|
| Mean | ± | U | p | |
| Group 1 | 69.31 | 35.05 | ||
| Group 2 | 68.95 | 30.05 | 695.5 | 0.92 |
p: probability; U: U-statistic. ±: standard deviation.
Mean values for Group 1 and Group 2 were as follows: age 68.1 and 71.6 years old, weight 83.8 and 91.5, and BMI 31.9 and 36.3, ultrasound prostatic volume (cm3) measured by ultrasound 69.3 and 68.95, PSA 1.88 and 2.2, IPSS 4.588 and 5.63.
There were 22 patients with mild IPSS, from these 20 had obesity and 2 severe obesity; 72 with moderate IPSS, from these 60 had obesity and 12 severe obesity; and 6 with severe IPSS, from these 3 had obesity and 3 severe obesity. There were significant statistical differences between the groups (p = 0.05).
On the other side, from the 83 patients with obesity, 31 had prostatic hyperplasia Grade II, 29 Grade III, and 23 Grade IV; from the 17 patients with severe obesity, 6 had prostatic hyperplasia Grade II, 6 Grade III, and 5 Grade IV. The association between these two grades of obesity and the grade of BPH measured by ultrasound did not report statistically significant differences, p = 0.985.
Discussion
The global epidemic of obesity and its strong relation with multiple urologic diseases have turned it into a critical issue.
In this study, where 537 patients were surveyed, 100 fulfilled inclusion criteria, which deliver a sample prevalence of 1.862 in the studied time frame. Mean age and mean BMI of all surveyed patients were 68.73 and 32.65, respectively. These data are similar to the reported by other authors regarding the patient's age. Gacci et al. reported 69.7 years6, De Nuzio et al. 68.8 years2, and Antunez et al. 66 years7. Nevertheless, it is not equivalent to the BMI of other studies such as Bhindi et al. trial with a mean of 27.18, Jung et al. 25.679, Yin et al. 27.310, and Fowke et al. 28.511. As for the use of previous medication to the study, only 36% were on finasteride treatment; 38% of them had Grade II prostatic enlargement, 36% Grade III, 26% Grade IV, and a mean PSA level of 1.94 ng/dl.
In respect of this study, among the patients with finasteride treatment, 25% had Grade II enlargement, 44.4% Grade III, and 30.55% Grade IV. In contrast, there was a greater percentage of patients in the different prostatic enlargement grades in patients with no medical treatment. This is controversial since in medical literature, it is described a total improvement of prostatic enlargement with finasteride. We considered that this could be due to the lack of inquiry about adherence to treatment. Nevertheless, significant statistical difference was not established between both groups (p = 0.17). Bhindi et al. mentioned that there is no relation between BMI and IPSS with finasteride treatment8.
In addition, the ultrasonographic characteristics of prostate provided a mean prostatic volume of 69.31 g in patients with Class I obesity and 69.95 g in patients with Class II. There were not significant statistical differences between both groups, p ≥ 0.05. In comparison, Bhindi et al.8 reported a mean prostatic volume of 52 g, Fowke et al.11 48 g, and Antunez et al. 36.8 g7. In Mexico, there have been no studies that establish a correlation between obesity and prostatic enlargement, therefore, there is no point of reference12.
Regarding PSA values of this study (1.94 ng/dl), this concurs with the reported values by Gacci et al.6 that mentioned a mean value of 2.6 ng/dl. However, other authors report greater mean PSA values, for example, Bhindi et al. reported PSA of 5.02 ng/dl, Jung et al. 3.19 ng/dl, De Nunzio et al. 3.2 ng/dl, and Fowke et al. 4.5 ng/dl8,9,2,11. Differences between mean PSA values in this study and the previous mentioned lie in the exclusion of patients with PSA levels > 4 ng/dl due to the increased risk of prostate cancer.
The internal consistency of the IPSS was low for both storage and voiding symptoms with a Cronbach's alpha of 0.272 and 0.601, respectively. However, the internal consistency of the total value of IPSS (7 categories) was 0.748, which is considered acceptable. De Nunzio et al., in 2014, with a population of 431 patients, found an obesity prevalence of 26%, this is greater than the one in our study (18%) with similar findings regarding IPSS values and prostatic volume2.
The findings in IPSS in this study were as follows: 21% of patients with mild symptoms, 73% with moderate symptoms, and 6% severe. Gacci et al.6 had 14.3% of patients with mild IPSS, 55.7% moderate, and 30% severe. These results differ due to the percentage of patients included in the group with Grade III prostatic enlargement which presents more symptoms than Group II.
The patients with Class II obesity had a greater symptomatology of the lower urinary tract than patients with Class I obesity, 11.10 and 13.41, respectively. There is a significant statistical association, p = 0.05. This also coincides with global medical literature, where it is reported that the greater the BMI is, the greater lower urinary tract symptoms is13.
Vignozzi et al. in 2016 reported multiple prospective studies with the objective to determine a positive association between BMI and lower urinary tract symptoms. However, despite the positive result for this association (the greater the BMI, the greater lower urinary tract symptoms) in the prostate center prevention trial; in osteoporotic fractures in Men Study and Southern Community Cohort Study, there are two prospective studies that deny said association14.
Finally, there was no significant statistical association between BMI and prostatic measurement by ultrasound, p = 0.985.
Although some studies conclude that moderate to vigorous physical activity is associated to BPH and lower urinary tract symptoms, this study did not consider physical activity as a variable, therefore, it was not possible to establish an association to physical activity15.
A limitation of this study is the size of the sample. A larger N is needed to demonstrate the hypothesis.
We propose to carry out a greater follow-up of the patients to determine the changes found in these results.
