The Importance of Erythrocyte Parameters in Obese Children
Increasing prevalence of childhood obesity has
increased the interest in early and late indicators of gaining weight.
Cell blood counts may be indicators of pro-inflammatory states. The
aim was to evaluate associations of hematological parameters,
including hematocrit (HTC), hemoglobin, blood cell counts and their
indices with the degree of obesity in pediatric population. A total of
249; -139 morbidly obese (MO), 82 healthy normal weight (NW) and
28 overweight (OW) children were included into the scope of the
study. WHO BMI-for age percentiles were used to form age- and sexmatched
groups. Informed consent forms and the Ethics Committee
approval were obtained. Anthropometric measurements were
performed. Hematological parameters were determined. Statistical
analyses were performed using SPSS. The degree for statistical
significance was p≤0.05. Significant differences (p=0.000) between
waist-to-hip ratios and head-to- neck ratios (hnrs) of MO and NW
children were detected. A significant difference between hnrs of OW
and MO children (p=0.000) was observed. Red cell distribution width
(RDW) was higher in OW children than NW group (p=0.030). Such
finding couldn’t be detected between MO and NW groups. Increased
RDW was prominent in OW children. The decrease in mean
corpuscular hemoglobin concentration (MCHC) values in MO
children was sharper than the values in OW children (p=0.006 vs
p=0.042) compared to those in NW group. Statistically higher HTC
levels were observed between MO-NW (p=0.014), but none between
OW-NW. Though the cause-effect relationship between obesity and
erythrocyte indices still needs further investigation, alterations in
RDW, HTC, MCHC during obesity may be of significance in the
early life.
[1] M. Mansourian, I. Kazemi and R. Kelishadi, “Pediatric metabolic
syndrome and cell blood counts: bivariate Bayesian modeling,” J. Trop.
Pediatr., vol. 60, no. 1, pp. 61-67, Feb. 2014.
[2] J. Vuong, Y. Qiu, M. La, G. Clarke, D. W. Swinkels and G.
Cembrowski, “Reference intervals of complete blood count constituents
are highly correlated to waist circumference: Should obese patients have
their own “normal” values?, Am. J. Hematol., vol. 89, no. 7, pp. 671-
677, July 2014.
[3] C. Aypak, O. Turedi, M. A. Bircan and A. Yuce, “Could mean platelet
volume among complete blood count parameters be a surrogate marker
of metabolic syndrome in pre-pubertal children?,” Platelets, vol. 25, no.
6, pp. 393-398, 2014.
[4] R. Kelishadi, M. Hashemipour, P. Ashtijou, P. Mirmoghtadaee, P.
Poursafa, N. Khavarian and S. Ghatrehsamani, “Association of cell
blood counts and cardiometabolic risk factors among young obese
children,” Saudi Med. J., vol. 31, no. 4, pp. 406-412, Apr. 2010.
[5] J. Zhao, L. Lin, X. Z. Lu and G. Li, “Noninvasive detection
of hematocrit and the mean corpuscular hemoglobin concentration levels
by Vis-NIR spectroscopy,” GuangPuXue Yu GuangPu Fen Xi, vol. 34,
no. 3, pp. 652-655, Mar 2014.
[6] T. Skjelbakken, J. Lappegård, T. S. Ellingsen, E. Barrett-Connor, J.
Brox, M-L. Løchen, I. Njølstad, T. Wilsgaard, E. B. Mathiesen, S. K.
Brækkan and J-B. Hansen, “Red cell distribution width is associated
with incident myocardial infarction in a general population: The Tromsø
Study,” J. Am. Heart Assoc., vol. 3, no. 4, pp. e001109, Aug. 2014.
[7] J. Rodriguez-Carrio, M. Alperi-Lopez, P. Lopez, S. Alonso-Castro, F. J.
Ballina-Garcia and A. Suarez, “Red cell distribution width is associated
with cardiovascular risk and disease parameters in rheumatoid arthritis,”
Rheumatology, to be published.
[8] Z. Z. Li, L. Chena, H. Yuan, T. Zhou and Z. M. Kuang, “Relationship
between red blood cell distribution width and early-stage renal function
damage in patients with essential hypertension,” J. Hypertens., vol. 32,
no. 12, pp. 2450–2456, Dec. 2014.
[9] A. Vayá, R. Alis, A. Hernandez-Mijares, E. Solá, R. Cámara, L. Rivera,
M. Romagnoli and B. Laiz, “Red blood cell distribution width is not
related with inflammatory parameters in morbidly obese patients,” Clin.
Biochem., vol. 47, no. 6, pp. 464–466, Apr. 2014.
[10] A. Vaya, R. Alis, M. Suescun, L. Rivera, J. Murado, M. Romagnoli, E.
Sola, and A. Hernandez-Mijares, “Association of erythrocyte
deformability with red blood cell distribution width in metabolic
diseases and thalassemia trait,” Clin. Hemorheol. Microcirc., to be
published.
[11] H. H. Patel, H. R. Patel and J. M. Higgins, “Modulation of red blood cell
population dynamics is a fundamental homeostatic response to disease,”
Am. J. Hematol., to be published.
[12] Growth reference 5-19 years. BMI-for-age (5-19 years) Available from:
http://www.who.int/growthref/who2007_bmi_for_age/en/
[13] D. R. Matthews, J. P. Hosker, A. S. Rudenski, B. A. Naylor, D. F.
Treacher and R. C. Turner, “Homeostasis model assessment: insulin
resistance and beta-cell function from fasting plasma glucose and insulin
concentrations in man,” Diabetologia, vol. 28, no. 7, pp. 412–419, Jul.
1985.
[14] P. Gunczler and R. Lanes, “Relationship between different fasting-based
insulin sensitivity indices in obese children and adolescents,” J. Pediatr.
Endocrinol. Metab., vol. 19, no. 3, pp. 259-265, Mar. 2006.
[15] C. Su, L. Z. Liao, Y. Song, Z. W. Xu and W. Y. Mei, “The role of red
blood cell distribution width in mortality and cardiovascular risk among
patients with coronary artery diseases: a systematic review and metaanalysis,”
J. Thorac. Dis., vol. 6, no. 10, pp. 1429-1440, Oct. 2014.
[16] Y. Arbel, D. Weitzman, R. Raz, A. Steinvil, D. Zeltser, S. Berliner, G.
Chodick, and V. Shalev, “Red blood cell distribution width and the risk
of cardiovascular morbidity and all-cause mortality. A population-based
study,” Thromb. Haemost.vol. 111, no. 2, pp. 300-307, Feb. 2014.
[17] Y. Borné, J. G. Smith, O. Melander and G. Engström, “Red cell
distribution width in relation to incidence of coronary events and case
fatality rates: a population-based cohort study,” Heart, vol. 100, no. 14,
pp. 1119-1124, Jul. 2014.
[18] Y. L. Huang, Z. D. Hu, S. J. Liu, Y. Sun, Q. Qin, B. D. Qin, W. W.
Zhang, J. R. Zhang, R. Q. Zhong and A. M. Deng, “Prognostic value of
red blood cell distribution width for patients with heart failure: a
systematic review and meta-analysis of cohort studies.” PLoS One, vol.
9, no. 8, pp. e104861, Aug. 2014.
[19] B. Fujita, D. Strodthoff, M. Fritzenwanger, A.Pfeil, M. Ferrari, B.
Goebel, H. R. Figulla, N. Gerdes and C. Jung, “Altered red blood cell
distribution width in overweight adolescents and its association with
markers of inflammation,” Pediatr. Obes. vol. 8, no. 5, pp. 385–391,
Oct. 2013.
[20] F. A. Caporal and S. R. Comar, “Evaluation of RDW-CV, RDW-SD,
and MATH-1SD for the detection of erythrocyte anisocytosis observed
by optical microscopy,” J. Bras. Patol. Med. Lab., vol. 49, no. 5, pp.
324-331, Sept-Oct. 2013.
[21] E. E. Coglianese, M. M. Qureshi, R. S. Vasan, T. J.Wang and L. L.
Moore, “Usefulness of the Blood Hematocrit Level to Predict
Development of Heart Failure in a Community,” Am. J. Cardiol., vol.
109, no. 2, pp. 241–245, Jan. 2012.
[22] E. Sola, A. Vaya, M. Simo, A. Hernandez-Mijares, C. Morillas, F.
Espana, A. Estelles, D. Corella, “Fibrinogen, plasma viscosity and blood
viscosity in obesity. Relationship with insulin resistance,” Clin.
Hemorheol. Microcirc, vol. 37, no. 4, pp. 309-318, 2007.
[23] Y. Z. Jin, D. H. Zheng, Z. Y. Duan, Y. Z. Lin, X. Y. Zhang, J. R. Wang,
S. Han, G. F. Wang and Y. J. Zhang, “Relationship between hematocrit
level and cardiovascular risk factors in a community-based population.,”
J. Clin. Lab. Anal., to be published.
[24] A. J. Hanley, R. Retnakaran, Y. Qi, H. C. Gerstein, B. Perkins, J.
Raboud, S. B. Harris and B. Zinman, “Association of hematological
parameters with insulin resistance and beta-cell dysfunction in
nondiabetic subjects,” J.Clin. Endocrinol. Metab, vol.94, no. 10, pp.
3824-3832, Oct.2009.
[1] M. Mansourian, I. Kazemi and R. Kelishadi, “Pediatric metabolic
syndrome and cell blood counts: bivariate Bayesian modeling,” J. Trop.
Pediatr., vol. 60, no. 1, pp. 61-67, Feb. 2014.
[2] J. Vuong, Y. Qiu, M. La, G. Clarke, D. W. Swinkels and G.
Cembrowski, “Reference intervals of complete blood count constituents
are highly correlated to waist circumference: Should obese patients have
their own “normal” values?, Am. J. Hematol., vol. 89, no. 7, pp. 671-
677, July 2014.
[3] C. Aypak, O. Turedi, M. A. Bircan and A. Yuce, “Could mean platelet
volume among complete blood count parameters be a surrogate marker
of metabolic syndrome in pre-pubertal children?,” Platelets, vol. 25, no.
6, pp. 393-398, 2014.
[4] R. Kelishadi, M. Hashemipour, P. Ashtijou, P. Mirmoghtadaee, P.
Poursafa, N. Khavarian and S. Ghatrehsamani, “Association of cell
blood counts and cardiometabolic risk factors among young obese
children,” Saudi Med. J., vol. 31, no. 4, pp. 406-412, Apr. 2010.
[5] J. Zhao, L. Lin, X. Z. Lu and G. Li, “Noninvasive detection
of hematocrit and the mean corpuscular hemoglobin concentration levels
by Vis-NIR spectroscopy,” GuangPuXue Yu GuangPu Fen Xi, vol. 34,
no. 3, pp. 652-655, Mar 2014.
[6] T. Skjelbakken, J. Lappegård, T. S. Ellingsen, E. Barrett-Connor, J.
Brox, M-L. Løchen, I. Njølstad, T. Wilsgaard, E. B. Mathiesen, S. K.
Brækkan and J-B. Hansen, “Red cell distribution width is associated
with incident myocardial infarction in a general population: The Tromsø
Study,” J. Am. Heart Assoc., vol. 3, no. 4, pp. e001109, Aug. 2014.
[7] J. Rodriguez-Carrio, M. Alperi-Lopez, P. Lopez, S. Alonso-Castro, F. J.
Ballina-Garcia and A. Suarez, “Red cell distribution width is associated
with cardiovascular risk and disease parameters in rheumatoid arthritis,”
Rheumatology, to be published.
[8] Z. Z. Li, L. Chena, H. Yuan, T. Zhou and Z. M. Kuang, “Relationship
between red blood cell distribution width and early-stage renal function
damage in patients with essential hypertension,” J. Hypertens., vol. 32,
no. 12, pp. 2450–2456, Dec. 2014.
[9] A. Vayá, R. Alis, A. Hernandez-Mijares, E. Solá, R. Cámara, L. Rivera,
M. Romagnoli and B. Laiz, “Red blood cell distribution width is not
related with inflammatory parameters in morbidly obese patients,” Clin.
Biochem., vol. 47, no. 6, pp. 464–466, Apr. 2014.
[10] A. Vaya, R. Alis, M. Suescun, L. Rivera, J. Murado, M. Romagnoli, E.
Sola, and A. Hernandez-Mijares, “Association of erythrocyte
deformability with red blood cell distribution width in metabolic
diseases and thalassemia trait,” Clin. Hemorheol. Microcirc., to be
published.
[11] H. H. Patel, H. R. Patel and J. M. Higgins, “Modulation of red blood cell
population dynamics is a fundamental homeostatic response to disease,”
Am. J. Hematol., to be published.
[12] Growth reference 5-19 years. BMI-for-age (5-19 years) Available from:
http://www.who.int/growthref/who2007_bmi_for_age/en/
[13] D. R. Matthews, J. P. Hosker, A. S. Rudenski, B. A. Naylor, D. F.
Treacher and R. C. Turner, “Homeostasis model assessment: insulin
resistance and beta-cell function from fasting plasma glucose and insulin
concentrations in man,” Diabetologia, vol. 28, no. 7, pp. 412–419, Jul.
1985.
[14] P. Gunczler and R. Lanes, “Relationship between different fasting-based
insulin sensitivity indices in obese children and adolescents,” J. Pediatr.
Endocrinol. Metab., vol. 19, no. 3, pp. 259-265, Mar. 2006.
[15] C. Su, L. Z. Liao, Y. Song, Z. W. Xu and W. Y. Mei, “The role of red
blood cell distribution width in mortality and cardiovascular risk among
patients with coronary artery diseases: a systematic review and metaanalysis,”
J. Thorac. Dis., vol. 6, no. 10, pp. 1429-1440, Oct. 2014.
[16] Y. Arbel, D. Weitzman, R. Raz, A. Steinvil, D. Zeltser, S. Berliner, G.
Chodick, and V. Shalev, “Red blood cell distribution width and the risk
of cardiovascular morbidity and all-cause mortality. A population-based
study,” Thromb. Haemost.vol. 111, no. 2, pp. 300-307, Feb. 2014.
[17] Y. Borné, J. G. Smith, O. Melander and G. Engström, “Red cell
distribution width in relation to incidence of coronary events and case
fatality rates: a population-based cohort study,” Heart, vol. 100, no. 14,
pp. 1119-1124, Jul. 2014.
[18] Y. L. Huang, Z. D. Hu, S. J. Liu, Y. Sun, Q. Qin, B. D. Qin, W. W.
Zhang, J. R. Zhang, R. Q. Zhong and A. M. Deng, “Prognostic value of
red blood cell distribution width for patients with heart failure: a
systematic review and meta-analysis of cohort studies.” PLoS One, vol.
9, no. 8, pp. e104861, Aug. 2014.
[19] B. Fujita, D. Strodthoff, M. Fritzenwanger, A.Pfeil, M. Ferrari, B.
Goebel, H. R. Figulla, N. Gerdes and C. Jung, “Altered red blood cell
distribution width in overweight adolescents and its association with
markers of inflammation,” Pediatr. Obes. vol. 8, no. 5, pp. 385–391,
Oct. 2013.
[20] F. A. Caporal and S. R. Comar, “Evaluation of RDW-CV, RDW-SD,
and MATH-1SD for the detection of erythrocyte anisocytosis observed
by optical microscopy,” J. Bras. Patol. Med. Lab., vol. 49, no. 5, pp.
324-331, Sept-Oct. 2013.
[21] E. E. Coglianese, M. M. Qureshi, R. S. Vasan, T. J.Wang and L. L.
Moore, “Usefulness of the Blood Hematocrit Level to Predict
Development of Heart Failure in a Community,” Am. J. Cardiol., vol.
109, no. 2, pp. 241–245, Jan. 2012.
[22] E. Sola, A. Vaya, M. Simo, A. Hernandez-Mijares, C. Morillas, F.
Espana, A. Estelles, D. Corella, “Fibrinogen, plasma viscosity and blood
viscosity in obesity. Relationship with insulin resistance,” Clin.
Hemorheol. Microcirc, vol. 37, no. 4, pp. 309-318, 2007.
[23] Y. Z. Jin, D. H. Zheng, Z. Y. Duan, Y. Z. Lin, X. Y. Zhang, J. R. Wang,
S. Han, G. F. Wang and Y. J. Zhang, “Relationship between hematocrit
level and cardiovascular risk factors in a community-based population.,”
J. Clin. Lab. Anal., to be published.
[24] A. J. Hanley, R. Retnakaran, Y. Qi, H. C. Gerstein, B. Perkins, J.
Raboud, S. B. Harris and B. Zinman, “Association of hematological
parameters with insulin resistance and beta-cell dysfunction in
nondiabetic subjects,” J.Clin. Endocrinol. Metab, vol.94, no. 10, pp.
3824-3832, Oct.2009.
@article{"International Journal of Medical, Medicine and Health Sciences:69725", author = "Orkide Donma and M. Metin Donma and Burcin Nalbantoglu and Birol Topcu and Feti Tulubas and Murat Aydin and Tuba Gokkus and Ahmet Gurel", title = "The Importance of Erythrocyte Parameters in Obese Children", abstract = "Increasing prevalence of childhood obesity has
increased the interest in early and late indicators of gaining weight.
Cell blood counts may be indicators of pro-inflammatory states. The
aim was to evaluate associations of hematological parameters,
including hematocrit (HTC), hemoglobin, blood cell counts and their
indices with the degree of obesity in pediatric population. A total of
249; -139 morbidly obese (MO), 82 healthy normal weight (NW) and
28 overweight (OW) children were included into the scope of the
study. WHO BMI-for age percentiles were used to form age- and sexmatched
groups. Informed consent forms and the Ethics Committee
approval were obtained. Anthropometric measurements were
performed. Hematological parameters were determined. Statistical
analyses were performed using SPSS. The degree for statistical
significance was p≤0.05. Significant differences (p=0.000) between
waist-to-hip ratios and head-to- neck ratios (hnrs) of MO and NW
children were detected. A significant difference between hnrs of OW
and MO children (p=0.000) was observed. Red cell distribution width
(RDW) was higher in OW children than NW group (p=0.030). Such
finding couldn’t be detected between MO and NW groups. Increased
RDW was prominent in OW children. The decrease in mean
corpuscular hemoglobin concentration (MCHC) values in MO
children was sharper than the values in OW children (p=0.006 vs
p=0.042) compared to those in NW group. Statistically higher HTC
levels were observed between MO-NW (p=0.014), but none between
OW-NW. Though the cause-effect relationship between obesity and
erythrocyte indices still needs further investigation, alterations in
RDW, HTC, MCHC during obesity may be of significance in the
early life.
", keywords = "Anthropometry, children, erythrocytes, obesity.", volume = "9", number = "5", pages = "361-4", }
