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Intraocular pressure in subjects with beta-thalassemia minor

Pressão intraocular em indivíduos com talassemia beta minor

Şakir Özgür Keşkek1; Nedime Şahinoğlu Keşkek2; Gizem Ilgın1; Emine Sukgen3

DOI: 10.5935/0004-2749.20190042

ABSTRACT

PURPOSE: Beta-thalassemia minor, a common hereditary blood disorder in Mediterranean countries such as Turkey, is associated with insulin resistance. Insulin resistance, in turn, can be associated with excessively high intraocular pressure and, therefore, intraocular pressure-induced blindness. This study aimed to investigate the intraocular pressure in subjects with beta-thalassemia minor.
METHODS: We conducted a cross-sectional study comprising of 203 subjects divided into two groups: beta-thalassemia minor (103) and healthy (100).Hemoglobin electrophoresis was performed and complete blood count, blood pressures, serum fasting glucose and insulin levels were measured. All subjects underwent ophthalmological examinations including intraocular pressure measurements.
RESULTS: Intraocular pressure in the subjects with beta-thalassemia minor was significantly lower than that in healthy subjects (p=0.007). Additionally, intraocular pressure was inversely correlated with hemoglobin A2 levels (p=0.001, r=-0.320). Serum insulin and systolic blood pressure were significantly higher in subjects with beta-thalassemia minor (p=0.03, p=0.009, respectively).
CONCLUSION: Subjects with beta-thalassemia minor had lower intraocular pressure than healthy controls, suggesting beta-thalassemia minor may actually protect against high intraocular pressure.

Keywords: Beta-Thalassemia; Blood pressure; Glaucoma; Hemoglobin A2; Intraocular pressure

RESUMO

OBJETIVO: Beta-talassemia menor é uma doença hereditária comum no sangue em países mediterrâneos como a Turquia e está associada à resistência à insulina. A resistência à insulina por sua vez, pode estar associada à pressão intraocular excessivamente alta e, portanto à cegueira induzida pela pressão intraocular. Este estudo teve como objetivo investigar a pressão intraocular em indivíduos com beta-talassemia menor.
MÉTODOS: Foi realizado um estudo transversal compreendendo 203 indivíduos divididos em 2 grupos: beta-talassemia menor (103) e saudável (100). Eletroforese de hemoglobina foi realizada e hemograma completo, pressão arterial, glicemia em jejum e níveis de insulina medidos. Todos os indivíduos foram submetidos foram submetidos a exames oftalmológicos, incluindo medidas de pressão intraocular.
RESULTADOS: A pressão intraocular nos indivíduos com beta-talassemia menor foi significativamente menor do que em indivíduos saudáveis (p=0,007). Além disso, a pressão intraocular foi inversamente correlacionada com os níveis de hemoglobina A2 (p=0,001, r=-0,320). Insulina sérica e pressão arterial sistólica foram significativamente maiores em indivíduos com beta-talassemia menor (p=0,03, p=0,009, respectivamente).
CONCLUSÃO: Os indivíduos com beta-talassemia menor tiveram pressão intraocular menor do que os controles saudáveis, sugerindo que a beta-talassemia menor pode, na verdade, proteger contra a alta pressão intraocular.

Descritores: Talassemia beta; Pressão sanguínea; Glaucoma: Hemoglobina A2; Pressão intraocular

INTRODUCTION

Beta-thalassemia syndromes are a group of hereditary blood disorders characterized by reduced or absent globin beta-chain synthesis, resulting in reduced hemoglobin in red blood cells (RBCs), decreased RBC production and anemia. Beta-thalassemia minor (BTM) is a term used to describe reduced or absent production of β-globin resulting from the inheritance of a single heterozygous gene. Patients with BTM are usually clinically asymptomatic but may have mild anemia identifiable only through blood examination. BTM is reported to be most prevalent in the Mediterranean region such as Turkey, Greece, and Italy(1-3).

Intraocular pressure (IOP), the fluid pressure inside the eye, is mainly determined by the coupling of the production and drainage of aqueous humor via the trabecular meshwork located in the anterior chamber angle. Excessive IOP is the most strongest and only treatable risk factor for developing glaucoma(4,5). Additionally, excessive IOP has also been reported to be associated with other conditions such as diabetes, hypertension, obesity and metabolic syndromes(6-9). Metabolic syndromes and its components in turn, further exacerbate these conditions as it is strongly associated with insulin resistance, which plays a vital role in the development of diabetes, hypertension and obesity, and has been demonstrated in patients with BTM(12,13). Hence, studies are required to investigate the various regulatory systems mediating IOP to understand the mechanisms underlying glaucoma. This study aimed to investigate whether insulin resistance in BTM leads to high IOP.

 

METHODS

A cross-sectional study was carried out in the internal medicine outpatient clinics of a tertiary hospital in Turkey from July 30, 2015 to November 30, 2016. The study was approved by the Institutional Review Board. Informed consent was obtained from all participants. All procedures followed the ethical standards of the responsible committee on human experimentation and the Helsinki Declaration.

Power analysis (80%) was performed to determine the optimal sample size for the study. Subjects with a history of glaucoma, ocular inflammation such as uveitis, ocular surgery, use any drugs (steroids, beta-blockers, anti-depressants, bronchodilators, etc.), malignancy, and any other acute or chronic disease were excluded. Additinally, women who were breastfeeding or pregnant were also excluded. A total of 203 subjects at least 18 years of age were enrolled in this study. The participants were divided into two study group: 103 subjects with BTM and the control group 100 healthy subjects. The criteria for the diagnosis of BTM were: hemoglobin A2 (HbA2) ≥3.5%, mean corpuscular volume (MCV) <80 fl and hemoglobin F (HbF)=2%-10%.

Venous blood samples were collected in the morning from each participant after overnight fasting. A complete blood count and hemoglobin electrophoresis was performed for all of the samples. Fluorescence flow cytometry (Sysmex XE 2100i, [manufacturer], Japan) was used for the complete blood counts, and high performance liquid chromatography (Primus Ultra 2, [manufacturer], USA) was used to analyze the electrophoretic data. Serum glucose and lipids were analyzed on a Synchron LX 20 (Beckman Coulter, Massachusetts, USA) using commercially available kits. Insulin levels were measured on an Architect I 2000 SR (Abbott, Illinois, USA). Insulin resistance was measured using the homeostasis model assessment (HOMA-IR). Ferritin, vitamin B12 and folate levels were measured by electrochemiluminescence immunoassay (C-601, Roche, Japan). Trained nurses measured blood pressure using a sphygmomanometer three times per subject at one-minute intervals. Each subject was allowed a 10-min rest prior to measurement and was sitting at the time of measurement.

Ophthalmological examinations were performed between 8:00 am and 11:00 am, and included the best-corrected visual acuity, refraction, IOP measurement by Goldmann applanation tonometry and dilated fundus examination. Two ophthalmologists (NSK and ES) took three consecutive measurements for each eye, and the average IOP of the right eye was used for analysis.

MedCalc 16.8.4 (MedCalc Belgium) was used for statistical analysis. Categorical measurements are reported as number and percentage and were analyzed by Chi-square tests; quantitative measurements are reported as the mean ± standard deviation and were analyzed for normality by Kolmogorov-Smirnov tests. For normally distributed data, t-tests or Mann- Whitney U tests were used for groupwise comparisons of quantitative measurements. Pearson correlation coefficients were derived to analyze the degree of association between two variables (including p-value and 95% confidence interval for r). Log transformation was used for variables that were not normally distributed. Multiple linear regression tests (backward method) were used to analyze the relationship between the dependent variable (HbA2) and one or more independent variables (predictor variables or explanatory variables). A p-value of less than 0.05 was considered to be statistically significant.

 

RESULTS

As seen in table 1, the experimental and control groups were comparable according to age (36.6 ± 11.2 and 38.4 ± 8.8 years, respectively; p=0.197) and sex (68.9% and 62% women, respectively; p=0.635). HbA2 (%) and HbF (%) percentages of subjects with BTM were higher than those in healthy subjects. Mean HbA2 (study, 4.85 ± 0.81%; control, 3.81 ± 1.03%) and HbF (study, 2.06 ± 0.35%; control, 0.26 ± 0.42%) levels were significantly higher in subjects with BTM compared to controls. Mean MCV was significantly lower in subjects with BTM compared to controls (65.3 ± 4.1 fl and 81.5 ± 9.3 fl, respectively; p<0.001). Hemoglobin and hematocrit levels were significantly lower (p<0.001), and RBC levels were significantly higher (p<0.001) in subjects with BTM compared to the control group (Table 1). There were no statistically significant differences between groups in platelets, white blood cells (WBCs), ferritin, vitamin B12, and folate levels of the groups (p >0.05 in all cases). Mean central corneal thickness and refraction were comparable between groups (p=0.371, 0.466, respectively; Table 1).

 

 

Fasting glucose, insulin, and HOMA-IR levels were significantly higher in the study group than the control group (p=0.027, p=0.03, p=0.02, respectively; Table 2). Systolic blood pressure in the BTM group was significantly lower than that in the control group (110.7 ± 11.4 mmHg vs. 115.1 ± 12.5 mmHg; p=0.009), whereas diastolic blood pressure was similar between groups (p=0.708). Triglyceride, LDL, and HDL levels were comparable between groups (p=0.222, p=0.569, p=0.059, respectively; Table 2).

 

 

Mean IOP was significantly lower in the BTM group relative to that in the control group (12.4 ± 2.1 mmHg and 13.2 ± 2.3 mmHg, respectively; p=0.007; Figure 1); IOP in the study group was inversely correlated with HbA2 (p=0.001, r=-0.320; Figure 2) and positively correlated with systolic blood pressure (p=0.001, r=0.308; Figure 3). Multiple regression analyses using IOP as the dependent variable and HbA2 and systolic blood pressure as independent variables demonstrated a significant correlation between IOP and HbA2 (p=0.003), as well as systolic blood pressure (p=0.01; Table 3).

 


Figure 1. The mean intraocular pressures of the BTM and healthy control groups.
BTM= Beta-thalassemia minor.

 

 


Figure 2. Scatter diagram of the correlation between intraocular pressure and hemoglobin A2 (HbA2) in subjects with beta-thalassemia minor

 

 


Figure 3. Scatter diagram of the correlation between intraocular pressure and systolic blood pressure in subjects with beta-thalassemia minor

 

 

 

DISCUSSION

Our results revealed low IOP in subjects with BTM when compared with healthy subjects. Additionally, we found an inverse correlation between IOP and HbA2 and a positive correlation between IOP and systolic blood pressure. Moreover, we also found low systolic blood pressure, but high levels of glucose, insulin, and HOMA-IR, in subjects with BTM.

BTM is associated with various metabolic disturbances(12-14), including insulin resistance(12,13). Research suggests that chronic microcytic erythrocytic hemolysis in BTM patients leads to oxidative stress and liver inflammation, which then lead to insulin resistance(12,14). Gozashti et al. noted BTM is associated with high prevalence of carbohydrate-related metabolic disorders which result liver inflammation and subsequent insulin resistance(15). On the other hand, Gozashti and colleagues ATP-related data indicated that the prevalence of metabolic syndrome in thalassemia patients was below that of the normal population (16.7% vs 36.7%).

Here we identified low systolic blood pressure in subjects with BTM. This is in agreement with other studies that reported low blood pressure in subjects with BTM(13). Hemodynamic variations were seen in anemia such as arterial dilation and decreased blood viscosity may lead to low blood pressure in subjects with BTM(16). Indeed, Vyssoulis et al. reported that hypertensive patients with BTM have better 24-hour blood pressure profiles compared to patients without BTM(17).

IOP in subjects with BTM was low relative to controls, and was positively correlated with systolic blood pressure. High blood pressure is an important risk factor for IOP(6,9) hypertension causes excessive production of aqueous humor, increased episcleral venous and ciliary arterial pressures, and increased sympathetic activity leading to high IOP(18,19). In a Taiwanese population, Lin et al., reported that of all the variables they measured, blood pressure was the strongest predictor of elevated IOP; this finding is supported by a recent epidemiologic study, as well as the correlation between IOP and systolic blood pressure described herein(20-21). Thus, the lower systolic pressure may be a protective factor for glaucoma in patients with BTM.

In this study, we found high levels of RBCs and low levels of hemoglobin in subjects with BTM. BTM leads to microcytic anemia and an associated increase in RBCs that is only minimally impacted by the lower Hb concentration(22).

Our study has some limitations. First, the cross-sectional design of this study limited its ability to establish causality. Intraocular pressure does increase gradually with age, and the subjects included here were relatively young, so longitudinal studies may be more effective regarding the potential associations with glaucoma. Second, 24-hour ambulatory blood pressure monitoring was not performed. Third, genetic analyses to confirm (or define) BTM in the study group would have been beneficial. Lastly, a multicenter study with a larger sample size could be more demonstrative. The study design was also strong in its sample size, which was large enough for power analyses, and in its similarity in age and sex between groups (both characteristics can influence IOP).

The study concludes that low IOP could hypothetically afford some protection against glaucoma or other disorders involving high IOP.

 

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Submitted for publication: January 22, 2018.
Accepted for publication: October 19, 2018.

Approved by the following research ethics committee: Numune Training and Research Hospital (# ÇUTF/13.01.2017/53)

Funding: No specific financial support was available for this study

Disclosure of potential conflicts of interest: None of the authors have any potential conflicts of interest to disclose


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