Journal List > J Korean Med Sci > v.23(2) > 1020624

Kim, Noh, Lee, Choi, Chung, Min, Lee, Lee, and Kim: The Associations of Total and Differential White Blood Cell Counts with Obesity, Hypertension, Dyslipidemia and Glucose Intolerance in a Korean Population

Abstract

Although many studies have reported an association between total white blood cell count and metabolic syndrome, relatively few reports are available on the association between differential white blood cell counts and metabolic syndrome. The medical records of 15,654 subjects (age, median 46, range 14-90 yr; 8,380 men and 7,274 women) who visited the Center for Health Promotion were investigated. It was found that as total white blood cell (WBC) and differential WBC counts increased the frequencies of diabetes, hypertension, obesity, dyslipidemia, and metabolic syndrome also increased. Moreover, these significant relationships persisted after adjusting for age, gender, smoking, alcohol intake, educational background, and household income. The odds ratios (95% CI) for metabolic syndrome was 2.64 (2.30-3.04) in the highest quartile of total WBC count, with corresponding figures of 2.14 (1.88-2.44) for neutrophils, 2.32 (2.03-2.64) for lymphocytes, 1.56 (1.37-1.78) for monocytes, 1.36 (1.20-1.54) for basophils, and 1.82 (1.59-2.08) for eosinophils versus the lowest quartiles of the appropriate total and differential counts, respectively, after adjusting for the variables mentioned above. These independent associations were also observed by subgroup analyses according to the smoking status. Our data suggest that even within normal ranges, total WBC count and the differential WBC counts are associated with the presence of metabolic syndrome.

INTRODUCTION

Many people with metabolic syndrome have a low-grade inflammation that may place them at risk for the development of cardiovascular disease. In view of its emerging epidemic nature and impact, the early identification of those at high risk of developing metabolic syndrome would help prevent associated cardiovascular complications. Several epidemiological studies have already noted a relationship between some components of metabolic syndrome and leukocytes (1-4). Moreover, leukocyte count has been positively associated with elevated cardiovascular mortality, mainly due to coronary heart disease and ischemic stroke (5-9), and it has been considered to be a marker of inflammation associated with the initiation and development of atherosclerosis. If the leukocyte count is an independent risk factor of metabolic syndrome, then it is important to consider the role of the constituent cell types involved. However, few systemic evaluations have investigated the relation between metabolic syndrome and differential leukocyte counts (10-13).
In this study, we investigated the relationship between total and differential leukocyte counts and the frequencies of diabetes, hypertension, dyslipidemia, obesity, and metabolic syndrome, after adjusting for clinical and biochemical factors.

MATERIALS AND METHODS

Subjects

The medical records of the 15,654 subjects (age, median 46, range 14-90 yr; 8,380 men and 7,274 women) who visited our Center for Health Promotion for a medical check up between January 2002 and December 2003 were investigated. Since routine medical checks are not covered by the Korean medical insurance system, we suspect that most of our study subjects were members of the upper-middle economic class. Subjects meeting any of the following criteria were excluded; a positive test for hepatitis C virus antibody, a positive test for hepatitis B virus surface antigen, a history of current antidiabetic/antihypertensive/antilipid medication, or an abnormal white blood cell (WBC) count (<3,800 or >10,000/µL). Subjects were classified into tertiles with respect to total and differential leukocyte counts. Diabetes was defined as a fasting plasma glucose ≥7.0 mM/L; hypertension as a systolic blood pressure ≥140 mmHg and/or a diastolic blood pressure ≥90 mmHg; dyslipidemia as a serum LDL-cholesterol low density lipoprotein-cholesterol-C (LDL-C) ≥4.2 mM/L and/or triglyceride ≥2.46 mM/L and/or HDL-cholesterol high density lipoprotein-cholesterol-C (HDL-C) <1.16 mM/L; obesity as a body mass index ≥25 kg/m2 (14, 15). The presence of metabolic syndrome was determined using the definition provided by the Third Report of the National Cholesterol Education Program Expert Panel on the Detection Evaluation, and Treatment of High Blood Cholesterol in Adults (16), as:- three or more of the following abnormalities: body mass index (BMI) ≥25 kg/m2; triglyceride ≥1.7 mM/L; HDL-C <1.04 mM/L; fasting plasma glucose (FPG) ≥6.1 mM/L; systolic blood pressure (SBP) ≥130 mmHg, and diastolic blood pressure (DBP) ≥85 mmHg. However, obesity according to the Expert Panel guidelines was not used as a criterion; instead, BMI was used, because waist circumference measurement was not available. The inclusion of BMI as a criterion is in line with the definition of metabolic syndrome recommended by the Japan Society for the Study of Obesity (17). This study was approved by the Internal Review Board (IRB) of the Samsung Medical Center.

Assay methods

Height and weight were measured with subjects wearing light clothing but no shoes in the morning; blood pressure was measured using a mercury sphygmomanometer on the right arm with subjects in a sitting position after a 5-min rest. BMI was calculated as weight in kilograms divided by height in meters squared. Information on lifestyle factors including alcohol consumption, cigarette smoking, household income, and educational background were obtained by trained nurses. Questions about alcohol intake included items about alcohol consumption frequency per week, and the type of alcoholic beverage; weekly alcohol intake was calculated and converted to daily alcohol consumption. Subjects were classified as non-drinkers or current drinkers when they consumed on average < 180 or 181 to < 360 g of alcohol/week, respectively. Heavy alcohol drinking was defined as ≥360 g/week of alcohol. Blood samples were obtained in the morning after an overnight fast. Plasma glucose was measured in duplicate by the hexokinase method using an autoanalyzer (Hitachi, Tokyo, Japan), which had an interassay coefficient of variation of 1.6%. Standard liver testing, total cholesterol, HDL-C, LDL-C, triglycerides, and uric acid were measured using an autoanalyzer (Hitachi, Tokyo, Japan), as were WBC counts (Sysmex, Kobe, Japan). Plasma fibrinogen was assessed using Clauss method (reagent kit from Dade Behring, Newark, NJ, U.S.A.). Hepatitis B virus surface antigen (HBsAg) and Hepatitis C virus antibody (anti-HCV) were measured using commercially available immunoradiometric assay kits (both from Riakey, Goyang, Korea).

Statistics

Data are expressed as means±SD. Analysis of variance (ANOVA) or χ2 tests were used to compare variables between tertile groups. Logistic regression analysis was used to obtain the odds ratios for diabetes, impaired fasting glucose, hypertension, dyslipidemia, obesity, and metabolic syndrome after adjusting for age, gender, smoking, alcohol intake, educational background, and household income. Statistical analyses were performed using SPSS/PC+ (SPSS, Inc., Chicago, IL, U.S.A.), and differences were considered statistically significant at a p level of <0.05.

RESULTS

The clinical characteristics of study subjects according to total leukocyte count are presented in Table 1. Univariate analyses showed that the following increased with increasing total leukocyte count; BMI, systolic and diastolic BP, fasting plasma glucose, lipid profile, serum aspartate aminotransferase (AST), serum alanine aminotransferase (ALT), gamma-glutamyl transferase (GGT), fibrinogen, uric acid, and a male gender, heavy alcohol drinking, and current smoking. Age, HDL-C, and household income decreased with increasing total leukocyte counts.
Logistic regression analyses showed that the frequencies of obesity, hypertension, diabetes, and dyslipidemia increased as total leukocyte, neutrophil, and lymphocyte counts increased after adjusting for age, gender, smoking, alcohol intake, educational background, and household income (Table 2). Total and differential leukocyte counts increased with increase in numbers of components of metabolic syndrome (Table 3).
Because smoking was identified as a major determinant of leukocyte count, we performed a subgroup analyses to further examine this feature. It was found that in all three smoking subgroups total and differential leukocyte counts were independently associated with the presence of metabolic syndrome, with the exception of basophil counts in past-smokers and current smokers (Table 4).
Men had higher total leukocyte counts and higher alcohol consumption and smoking frequencies than women. We performed logistic regression analyses to determine the odd ratios of the presence of metabolic syndrome with respect to total and differential leukocyte counts in both genders (Table 5). In both men and women, all differential and total leukocyte counts were significantly associated with the presence of metabolic syndrome after adjusting for the above mentioned variables.
To determine which component of the differential leukocyte count was more strongly related to metabolic syndrome, we performed logistic regression analyses using the individual differential leukocyte counts as covariates. The calculated odds ratios (95% CI) of metabolic syndrome (for highest versus lowest count quartiles) were: 1.76 (1.53-2.02) for neutrophils, 1.96 (1.71-2.25) for lymphocytes, and 1.59 (1.38-1.83) for eosinophils. However, monocyte and basophil showed no significant difference.

DISCUSSION

Our analysis demonstrates that leukocyte count, even within its normal range, is closely related to the presence of the components of metabolic syndrome after adjusting for age, gender, smoking, alcohol consumption, educational background, and income. Our results are consistent with previous findings concerning the significance of the relationship between total leukocyte count and metabolic syndrome (18-20), and with its components, namely, obesity, high blood pressure, and high serum triglyceride (21, 22).
Although several studies previously revealed these associations, these studies have usually involved a relatively small numbers of subjects, and the exclusion criteria adopted were insufficient. Unlike other studies, subjects positive for hepatitis C virus antibody and/or hepatitis B virus surface antigen, which are prevalent in Korea, were excluded, as were subjects with a recent history of antidiabetic, antihypertensive, or antilipid medication because of the possibility that these drugs could have affected leukocyte counts.
The mechanism of the relationship between leukocyte counts and cardiovascular disease has not been clarified. As cytokines are potent inducers of leukocyte differentiation, we speculated that an activated cytokine system might lead to elevated leukocyte levels. Furthermore, activated differentiated leukocytes can produce more cytokines. There is a possibility that hormones such as cortisol or insulin, which are known to be increased in metabolic syndrome, then stimulate leukocyte propagation (23-25). Some data are available on the association between differential leukocyte counts and coronary heart disease. Prentice et al. were the first to analyze differential leukocyte counts, and found that elevated neutrophil and eosinophil counts were both related to the development of coronary heart disease, and further suggested a similar relationship for monocyte count (26), and this relationship between coronary heart disease and monocyte counts was confirmed by Olivares et al. (11). Caerphilly and Speedwell found significant increases of neutrophil and eosinophil count in men who developed ischemic heart disease during follow-up (27), and the Atherosclerosis Risk in Communities study found that those in the highest quartiles for monocyte and granulocyte counts had a higher rate of cardiovascular disease mortality than those in the lowest quartiles (9).
Tanigawa et al. reported that total leukocyte and total lymphocyte counts, and more specifically, memory cell counts are elevated in middle-aged men with clustered features of metabolic syndrome (28). To the best of our knowledge, this is the first report to find significant associations between differential and total leukocyte counts and metabolic syndrome after adjusting for age, gender, smoking, alcohol intake, educational background, and household income. The reason for the differences between our results and those of Tanigawa et al. are uncertain. The first possibility concerns sample size differences, as the larger sample size used in the present study, compared to that of Tanigawa et al. (15,654 vs. 439), would have enabled us to detect smaller differences. The second possibility concerns the compositions of study subjects. Our study included both men and women in the range of age 14-90 yr, whereas Tanigawa et al. included only middle-aged men.
The present study has several limitations. This is a cross-sectional study, thus we only observed the association between leukocyte count and metabolic syndrome and could not determine the causal relationship. Although our study was relatively large in scale, the possibilities of using differential leukocyte counts as risk markers for metabolic syndrome require prospective study. Another limitation of the present study is that insulin resistance, a key component of metabolic syndrome, was not measured, and thus no direct relationship between insulin sensitivity and leukocyte counts was demonstrated. Moreover, we used BMI alone as a parameter of obesity, and waist circumference or some other parameter of obesity that more accurately reflects insulin resistance or atherogenicity would have been more preferable because obesity is a major determinant of leukocyte count. In addition, because this was not a population-based study, our results are limited in terms of their meaningfulness in the Korean population. In view of the fact that subjects with a college or university graduation constituted 52.2% of the study population and 44.2% had a relatively high income (household income ≥40,000 US dollars/yr), it is apparent that our study subjects represented the upper socioeconomic Korean class.
In conclusion, the results of the present study suggest that even within normal ranges, total leukocyte count and all differential leukocyte count examined are independently associated with the presence of metabolic syndrome. Future prospective studies are required to determine which differential leukocyte counts are most associated with metabolic syndrome development.

Figures and Tables

Table 1
Clinical characteristics of study subjects according to total leukocyte counts
jkms-23-193-i001

Data are means±SD or %. *not significant; p<0.05 by the χ2 test. All other significances were at the p<0.01 by the χ2 test or ANOVA. Heavy alcohol drinking was defined as ≥360 grams of alcohol/week. The ranges of the total leukocyte counts tertiles were 3,800-5,290, 5,291-6,460, and 6,461-10,000/µL, respectively.

BP, blood pressure; FPG, fasting plasma glucose; AST, serum aspartate aminotransferase; ALT, serum alanine aminotransferase; GGT, serum gamma glutamyl transferase; BUN, blood urea nitrogen.

Table 2
Odds ratios for obesity, hypertension, diabetes, and dyslipidemia versus total and differential leukocyte counts
jkms-23-193-i002

NS, not significant. *<0.05; <0.01; not significant. All other odds ratios were p<0.001. All odds ratios were adjusted for age, gender, smoking, alcohol intake, educational background, and household income. Definitions; obesity as body mass index ≥25 kg/m2 hypertension as an SBP ≥140 mmHg and/or a DBP ≥90 mmHg; dyslipidemia as an LDL-C ≥4.1 mM/L and/or a triglyceride of ≥2.46 mM/L and/or a HDL-C of <1.16 mM/L. Total leukocyte counts by tertile were the same as shown in Table 1, and were:- 1,070-2,806, 2,807-3,676, and 3,677-8,199 for neutrophils, 146-1,748, 1,749-2,224, and 2,225-5,727 for lymphocytes, 0-315, 316-410, and 411-1,714 for monocytes, 0-22, 23-34, and 35-397 for basophils and 0-88, 89-176, and 177-2,671/µL for eosinophils, respectively.

WBC, white blood cell, SBP, systolic blood pressure; DBP, diastolic blood pressure; LDL-C, low density lipoprotein-cholesterol; HDL-C, high density liprotein-cholesterol.

Table 3
Association of total and differential leukocyte counts with numbers of components of metabolic syndrome controlling after age and gender
jkms-23-193-i003

Data are means±SEM. All p for trend were <0.001 by ANCOVA. Ages were adjusted as 46.43 yr old. WBC, white blood cell.

Table 4
Odds ratios for metabolic syndrome according to total and differential leukocyte counts
jkms-23-193-i004

*<0.05; <0.01; not significant. All other odds ratios were p<0.001. All odds ratios were adjusted for age, gender, smoking, alcohol intake, educational background, and household income. Metabolic syndrome was defined as the presence of 3 or more of the following abnormalities: BMI ≥25 kg/m2; triglyceride ≥1.7 mM/L; HDL-C <1.04 mM/L; FPG ≥6.1 mM/L; and SBP ≥130 mmHg and/or DBP ≥85 mmHg. In all subjects, the ranges of the total and differential leukocyte counts in the tertiles were as shown in Table 2. In never-smokers these were 3,800-5,050, 5,051-6,150, and 6,151-10,000 for total leukocytes, 1,096-2,707, 2,708-3,536, and 3,537-8,199 for neutrophils, 146-1,711, 1,712-2,121, and 2,122-5,057 for lymphocytes, 7-294, 295-379, and 380-1,714 for monocytes, 0-21, 22-32, and 33-397 for basophils, and 0-71, 72-139, and 140-2,268 for eosinophils, respectively. In pastsmokers these were 3,800-5,323, 5,324-6,400, and 6,401-10,000 for total leukocytes, 1,070-2,807, 2,808-3,604, and 3,605-7,571 for neutrophils, 756-1,979,1,798-2,236, and 2,237-5,727 for lymphocytes, 0-22, 23-34, and 35-180 for basophils, and 0-99, 100-190, and 191-2,671 for eosinophils, respectively. In current smokers, these were 3,800-5,900, 5,901-7,200, and 7,201-10,000 for total leukocytes, 1,200-3,079, 3,080-4,063, and 4,064-7,950 for neutrophils, 541-1,971, 1,972-2,445, and 2,446-4,726 for lymphocytes, 0-25, 26-38, and 39-246 for basophils, and 0-129, 130-240, and 241-2,200 for eosinophils, respectively. WBC, white blood cell.

Table 5
Odds ratios for metabolic syndrome according to an increase in the total and differential leukocyte counts in men vs. women
jkms-23-193-i005

*<0.05; <0.01; not significant. All other odds ratios were p<0.001. All odds ratios were adjusted for age, smoking, alcohol intake, educational background, and household income. Metabolic syndrome was defined as in the legend of Table 4. In men, the ranges in each tertile were 3,800-5,580, 5,581-6,800, and 6,801-10,000 for total leukocytes, 1,070-2,922, 2,923-3,810, and 3,811-7,950 for neutrophils, 388-1,864, 1,865-2,330, and 2,331-5,727 for lymphocytes, 0-346, 347-448, and 449-1,376 for monocytes, 0-22, 23-36, and 37-246 for basophils, and 0-112, 113-217, and 218-2,671 for eosinophils, respectively. In women, these were 3,800-5,000, 5,001-6,100, and 6,101-10,000 for total leukocytes, 1,096-2,680, 2,681-3,514, and 3,515-8,199 for neutrophils, 146-1,701, 1,702-2,109, and 2,110-5,057 for lymphocytes, 7-289, 290-369, and 370-1,714 for monocytes, 0-21, 22-32, and 33-397 for basophils, and 0-68, 69-130, and 131-2,132 for eosinophils, respectively. WBC, white blood cell.

References

1. Friedman M, Teskawa I, Grimm RH, Manolio T, Shannon SG, Sidney S. The leukocyte count: correlates and relationship to coronary risk factors: the CARDIA study. Int J Epidemiol. 1990. 19:889–893.
2. Hansen LK, Grimm RH, Neaton JD. The relationship of white cell count to the other cardiovascular risk factors. Int J Epidemiol. 1990. 19:881–888.
3. Nieto FJ, Szaklo M, Folsom AR, Rock R, Mercuri M. Leukocyte count in middle-aged adults: the Atherosclerosis Risk in Communities (ARIC) Study. Am J Epidemiol. 1992. 136:525–537.
4. Wang YY, Lin SY, Liu PH, Cheung BM, Lai WA. Association between hematological parameters and metabolic syndrome components in a Chinese population. J Diabetes Complications. 2004. 18:322–327.
crossref
5. Weijenberg MP, Feskens EJ, Kromhout D. White blood cell count and the risk of coronary heart disease and all-cause morality in elderly men. Arterioscler Thromb Vasc Biol. 1996. 16:499–503.
6. Saito I, Folsom AR, Braneati EL, Duncan BB, Chambless LE, McGovern PG. Non-traditional risk factors for coronary heart disease incidence among persons with diabetes: the Atherosclerosis Risk in Communities (ARIC) Study. Ann Intern Med. 2000. 133:81–91.
crossref
7. Brown DW, Giles WH, Croft JB. White blood cell count: an independent predictor of coronary heart disease mortality among a national cohort. J Clin Epidemiol. 2001. 54:316–322.
8. Noto D, Barbagarllo CM, Cavera G, Cefalu AB, Caimi G, Marino G, Lo Coco L, Caldarella R, Notarbartolo A, Averna MR. Leukocyte count, diabetes mellitus and age are strong predictors of stroke in a rural population in southern Italy: an 8-year follow-up. Atherosclerosis. 2001. 157:225–231.
crossref
9. Lee CD, Folsom AR, Nieto FJ, Chambless LE, Shahar E, Wolfe DA. White blood cell count and incidence of coronary heart disease and ischemic stroke and mortality from cardiovascular disease in African-American and white men and women: Atherosclerosis Risk in Communities Study. Am J Epidemiol. 2001. 154:758–764.
10. Sweetnam PM, Thomas HF, Yarnell JW, Baker IA, Elwood PC. Total and differential leukocyte counts as predictors of ischemic heart disease: the Caerphilly and Speedwell Studies. Am J Epidemiol. 1997. 145:416–421.
crossref
11. Olivares R, Ducimetiere P, Claude JR. Monocyte count: a risk factor for coronary heart disease? Am J Epidemiol. 1993. 137:49–53.
crossref
12. Tanigawa T, Iso H, Yamagishi K, Muraki I, Kawamura N, Nakata A, Sakurai S, Ohira T, Shimamoto T. Association of lymphocyte subpopulations with clustered features of metabolic syndrome in middle-aged Japanese men. Atherosclerosis. 2004. 173:295–300.
crossref
13. Pinto EM, Huppert FA, Morgan K, Brayne C. Neutrophil counts, monocyte counts and cardiovascular disease in the elderly. Exp Gerontol. 2004. 39:615–619.
crossref
14. Oh SW, Shin SA, Yun YH, Yoo T, Huh BY. Cut-off point of BMI and obesity-related comorbidities and mortality in middle-aged Koreans. Obes Res. 2004. 12:2031–2040.
crossref
15. Kim YH, Suh YK, Choi HM. BMI and metabolic disorders in south Korean adults: 1988 Korea National Health and Nutrition Survey. Obes Res. 2004. 12:445–453.
16. Third report of the national cholesterol education program (NCEP) expert panel on detection, evaluation, and treatment of high blood cholesterol in adults (adult treatment panel III) final report. Circulation. 2002. 106:3143–3421.
17. Examination committee of criteria for 'obesity disease' in Japan. Japan society for the study of obesity. New criteria for 'obesity disease' in Japan. Circ J. 2002. 66:987–992.
18. Ble A, Palmieri E, Volpato S, Costantini F, Fellin R, Zuliani G. White blood cell count is associated with some features of metabolic syndrome in a very old population. Nutr Metab Cardiovasc Dis. 2001. 11:221–226.
19. Nakanishi N, Suzuki K, Tatara K. White blood cell count and clustered features of metabolic syndrome in Japanese male office workers. Occup Med (Lond). 2002. 52:213–218.
crossref
20. Ford ES. The metabolic syndrome and C-reactive protein, fibrinogen, and leukocyte count: findings from the Third National Health and Nutritional Examination Survey. Atherosclerosis. 2003. 168:351–358.
21. Nieman DC, Henson DA, Nehlsen-Cannarella SL. Influence of obesity on immune function. J Am Diet Assoc. 1999. 99:294–299.
crossref
22. Gillum RF, Mussolino ME. White blood cell count and hypertension incidence. The NHANES I Epidemiologic Follow-up Study. J Clin Epidemiol. 1994. 47:911–919.
crossref
23. Sims E. Humoral factors. 1993. Oxford: IRL Press;1–373.
24. Athens JW. C.R.ee , editor. Granulocyte-neutrophils. Wintrobe's clinical hematology. 9th ed. Philadelphia: Lea And Ferbinger;247–248.
25. Pederson O, Beck-Nielsen H. A study of insulin receptors in human mononuclear leukocytes. Acta Endocrinology. 1976. 83:556–564.
26. Prentice RL, Szatrowski TP, Fujikara T. Leukocyte counts and coronary heart disease in Japanese cohort. Am J Epidemiol. 1982. 116:496–509.
27. Sweetnam PM, Thomas HF, Yarnell JW, Baker IA, Elwood PC. Total and differential leukocyte counts as predictors of ischemic heart disease: the Caerphilly and Speedwell studies. Am J Epidemiol. 1997. 145:416–421.
crossref
28. Tanigawa T, Iso H, Yamagishi K, Muraki I, Kawamura N, Nakata A, Sakurai S, Ohira T, Shimamoto T. Association of lymphocyte sub-populations with clustered features of metabolic syndrome in meddle-aged Japanese men. Atherosclerosis. 2004. 173:295–300.
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