World Journal of Clinical Medicine Research
Article | Open Access | 10.31586/wjcmr.2023.787

Correlation of Thyroid Gland Functions with Menstrual Patterns amongst Infertile and Fertile Women Attending a Tertiary Care Hospital in North-Central Nigeria

Halima Inya Aliu-Ayo1, Kikelomo Temilola Adesina2, Abiodun Akanbi Gafar Jimoh2, Aloysius Obinna Ikwuka3,*, Francis Chigozie Udeh3, Sikiru Abayomi Biliaminu4 and Olayinka Waheed Ayo5
1
Department of Obstetrics and Gynaecology, R-Jolad Hospital, Lagos, Nigeria
2
Department of Obstetrics and Gynaecology, University of Ilorin & University of Ilorin Teaching Hospital, Ilorin, Nigeria
3
College of Medicine and Health Sciences, American International University West Africa, Banjul, The Gambia
4
Department of Chemical Pathology and Immunology, University of Ilorin & University of Ilorin Teaching Hospital, Ilorin, Nigeria
5
The Bridge Clinic, Lagos, Nigeria

Abstract

A regular menstrual cycle is important to maintain a woman’s fertility. This cycle has been linked to optimal function of the thyroid gland in the production of its hormones. Disturbance of thyroid gland functions could result to female infertility due to changes in menstrual patterns. Aim of this research was to determine the correlation between thyroid gland functions and menstrual patterns amongst infertile and fertile women attending a tertiary care hospital in North-Central Nigeria. This comparative, cross-sectional study recruited 106 women who visited the hospital's Gynecology Clinic and Family Planning Clinic. 53 of the 106 patients were women with a history suggestive of either primary or secondary infertility and the remaining 53 women with no history of infertility served as the control. A well-structured questionnaire was used to obtain data on the patients’ menstrual patterns. Anthropometric data were measured and obtained. Collected blood samples were analyzed using Enzyme-Linked Immunosorbent Assay (ELISA) technique to determine the serum levels of thyroid hormones. All obtained data was analyzed, and the level of significance was set at p<0.05, at a 95% confidence interval. 33 patients had menstrual anomalies (78.8% infertile women; 21.2% fertile women who served as control, p=0.012). The incidence of menstrual anomalies in the infertile women group and control group was 7.5% versus 0.0% for amenorrhea; 20.8% versus 5.7% for menorrhagia; 9.4% versus 7.5% for oligomenorrhea; 7.5% versus 0.0% for hypomenorrhea; nil polymenorrhea for both groups; and 50.9% versus 86.8% for normal menstrual patterns. Ten (9.43%) patients were diagnosed with thyroid dysfunctions (80% in infertile group; 20% in control group, p=0.046). Six (18.2%) out of 33 women with menstrual anomalies were diagnosed with thyroid dysfunction. Five (83.3%) out of these 6 women with both menstrual anomalies and diagnosed thyroid dysfunction were infertile while only one (16.7%) was fertile. Thyroid gland dysfunction correlates strongly with abnormal menstrual patterns, which implies that it is vital to evaluate thyroid hormone levels in blood serum in the course of treating menstrual irregularities and female infertility. Early detection of thyroid dysfunction is important in achieving a positive treatment outcome for female infertility.

1. Introduction

The menstrual cycle is a natural process in females that is responsible for the development and release of secondary oocyte(s), and vaginal bleeding as a result of the shedding of uterine mucosa, under the influence of hormones to make pregnancy possible [59]. The sperm cell must fertilize an ovum in vivo or in vitro in order for conception (pregnancy) to occur [5]. Gametes are ova and sperm cells which are haploid and have one copy of each type of chromosome i.e. 1–22 X or 1–22 Y [32]. The menstrual cycle is divided into uterine and ovarian cycles, occurs monthly and is an important factor in maintaining women’s fertility as it prepares a woman for pregnancy each month [59]. Menstruation is the bleeding phase of the uterine cycle, and as it commences, the follicular phase in the ovary starts for the growth of another follicle [57].

At menarche, a young girl witnesses her first menstruation. This continues all through her reproductive life and terminates at menopause. The event occurs with associating discomfort but the reproductive benefit outweighs these discomforts. However, there are situations where a female’s menstrual cycle experience becomes traumatic, ranging from anovulation to other forms of menstrual disorders [18, 40, 71]. There are instances where these disorders go unnoticed but then, in most cases, they impair a woman’s productivity and cause social embarrassment [13]. As these women seek medical attention, their financial burden heightens, however, it is important to note that many of the women are unaware and lack information about these disorders.

The link between menstrual anomalies and other systemic disorders, notably metabolic syndrome diseases (MSDs) is still being studied. MSDs (Hypertension, Adiposity, Diabetes mellitus and Dyslipidemia) are interrelated diseases with very high morbidity and mortality rates [19, 20, 22, 36] and characterized with high levels of blood pressure, glucose and lipid metabolic disorders, asymptomatic hyperuricemia, activation of systemic immune inflammation, fibrogenesis, and contribute to kidney damage [23, 24, 27, 29, 37, 62, 64, 66]. MSDs require new and effective treatment options. Dapagliflozin which is a Sodium-Glucose Linked Transporter 2 (SGLT-2) inhibitor and Liraglutide which is a Glucagon-like Peptide 1 Receptor Agonist (GLP-1 RA) have been found to increase the effectiveness of treatment and improve the clinical course of type 2 diabetes mellitus and hypertension in patients with such comorbidities [21, 25, 26, 30, 34, 67, 68, 69].

Menstrual disorders have also been linked with increased oxidative stress. Major free radicals that are of physiological significance are superoxide anion, hydroxyl radical, and hydroperoxyl radical, while non-radical is hydrogen peroxide [31]. Tobacco use has been reported as teratogenic, while excessive use of both alcohol and tobacco can be lethal [60, 61]. Oxidative stress can also be caused by the imbalance between Reactive Oxygen Species (ROS) produced by the alcohol consumed in the form of free radicals that contain one or more unpaired electrons and antioxidants [10].

The prevalence of menstrual disorders in an Indian population was recorded to be 10.9% [49], and it has been highlighted that 20% of cases reported in the Obstetrics and Gynecology units are related to menstrual disorders [3]. In a study among female university students in Southwestern Nigeria, 82.8% of the students had regular monthly menstrual flow pattern, while others (17.2%) had one or multiple forms of the following menstrual disorders: menorrhagia, oligomenorrhea, polymenorrhea, and occasional dysmenorrhea that disrupted their school activities by preventing them from going to school [1]. This report explains the 25% infertility cases of all reproductive complaints always handled in this study area. In severe cases, other gruesome consequences of menstrual disorders are infertility and an increased risk of death before 70 years of age [14]. Polymenorrhea described as excessive menstrual bleeding can cause anemia and complicate pregnancy [38, 39]. Infertility is a topic of concern in our society as it has caused several broken homes [5].

Menstruation is regulated by reproductive hormones [57]. However, the thyroid hormones have been identified to have a direct and indirect effect on reproductive physiology [43]. The hormones directly affect various stages of cells in the ovaries, and the indirect function is by elevating prolactin levels, decreasing the binding activity of sex hormone-binding globulin (SHBG), and delaying luteinizing hormone response to gonadotropin-releasing hormone [43, 56]. An optimum secretion of thyroid hormones is the determinant of the efficiency of the thyroid gland, as under- or overproduction of the hormones are termed thyroid gland dysfunctions.

Thyroid gland dysfunctions cause abnormal sexual development and menstrual disorders, and women have been reported to have more cases of thyroid dysfunctions than men [6]. Thyroid gland dysfunctions have been reported by several studies to include subclinical hypothyroidism, overt (clinical) hypothyroidism, subclinical hyperthyroidism, and overt (clinical) hyperthyroidism [17, 43]. These thyroid dysfunctions have been associated with various reproductive anomalies and precisely with menstrual irregularities. As has been documented that thyroid dysfunctions differ from region to region due to the varying iodine intake through salt, other meals and supplements [11], the associating menstrual irregularities are expected to be region-specific. Hence, this study was conducted to correlate thyroid gland dysfunctions with menstrual patterns amongst infertile and fertile women attending a tertiary care hospital in North-Central Nigeria.

2. Materials and Methods

2.1. Study Setting

This comparative, cross-sectional study was conducted at the Gynecology Clinic and Family Planning Clinic of the Department of Obstetrics and Gynecology, University of Ilorin Teaching Hospital (UITH), Ilorin Kwara State, North-Central Nigeria. UITH situated at Oke-Oyi, Old Jebba Road, Kwara State, is a major referral center for Kwara State and other neighboring states and serves as a medical training center for undergraduate and postgraduate students. Approximately 144 female patients visit the clinics weekly.

2.2. Study Population

This study involved women between the ages of 18-45 years visiting the clinics, with a history of infertility (inability to conceive of one year or more duration). This included those with primary infertility and secondary infertility. The control group consisted of fertile women, who had experienced complete gestation within 2 years prior to this study and were new patients at the Family Planning Clinic.

2.3. Sample Size and Sampling Technique

The formula described by Charan & Biswas (2013) [7] for a comparative, cross-sectional study was used.

N= 2Zα/2+ Zβ2 ˟ P1-PP1-P22

N = Sample size

Zα/2  = 1.96 at type 1 error of 5%

Zβ  = 1.28 at 90% power

P1  = Proportion of thyroid disorder in infertile women (47%)

P2  = Proportion of thyroid disorder in fertile women (16%). P1 and P2 were extracted from a previous study by Fatima, et al (2014) [12].

P = Pooled prevalence = [prevalence in one group (P1) + prevalence in another group (P2)]/ 2

P = [(0.47 + 0.16) / 2] = 0.32

N= 21.96+ 1.282 ˟ 0.321-0.320.47-0.162
N= 47.5
N~ 48 patients

For attrition, 10% of the sample size was added, making a total of 53 women in each group (infertile group and fertile group). Thus, a total of 106 women constituted the sample size.

2.4. Inclusion and Exclusion Criteria

Inclusions: For the patients, only women who consented and were within 18-45 years of age with primary or secondary infertility were included. Control group consisted of fertile women within the same age range as the subjects and consented to partake in this study. In addition, the fertile women (control group) were new patients at the Family Planning Clinic with no history of infertility, had been pregnant to term, and with no record of contraceptive use 2 years prior to this study.

Exclusions: Women outside 18-45 years of age, with a history of bleeding disorders, on hormonal or intrauterine contraceptives, with co-existing uterine fibroid, with a history of thyroid disorders, on steroids.

2.5. Data Collection Method

This study was conducted over a period of 6 months. Eligible women were briefed about the study in a simple language that they understood. Socio-demographic data, infertility history, anterior neck swelling history, other symptoms suggestive of thyroid disorder, medical conditions, and past surgical procedures were used.

2.6. Menstrual Pattern Assessment

Accurate measurement of menstrual blood loss may be difficult because of its subjectivity. Therefore, for the purpose of this study, cases were assessed by the number of pads used, passage of clots, and duration of bleeding [73]. The study questionnaire was used to assess this aspect of the study. Other menstrual data obtained include age at menarche, duration of flow, cycle length, and history of dysmenorrhea.

The menstrual patterns considered in this study are: normal menses, polymenorrhea, intermenstrual bleeding/metrorrhagia, menorrhagia, hypomenorrhea, oligomenorrhea, and amenorrhea. All consenting patients participating in this study had a pelvic ultrasound scan, at no additional cost to them. Patients with co-existing uterine fibroid were excluded from the study.

2.7. Sample Collection

A sample of blood (4 ml) was collected from each participant after an overnight fast of 8-10 hours. Patients who had fasted coincidentally at their first visit were recruited, while those who ate before coming on their first visit were recruited at their next visit after being pre-informed.

2.8. Laboratory Procedures

Serum concentrations of TSH, fT3 and fT4 were determined by using Enzyme-linked immunosorbent assay (ELISA) kits manufactured by Monobind Ltd using a Rayto micro-well plate reader, as described by Winter, et al (2012) [72].

2.9. Criteria for Diagnosis of Thyroid Dysfunction

The reference range of values for thyroid hormones that was used for this study is the range of normal values on the kits used: fT3 - 1.4-4.2 pg/mL, fT4 - 0.7-2.0 ng/dL, and TSH - 0.39-6.16 mIU/mL [45, 46, 47]. Thyroid gland dysfunctions can be grouped as subclinical hypothyroidism (normal fT3, fT4, but elevated TSH), hypothyroidism (decreased fT3, fT4, and elevated TSH), subclinical hyperthyroidism (normal fT3, fT4, but low TSH), and hyperthyroidism (elevated fT3, fT4, and decreased TSH) [17].

2.10. Data Analysis

Collected data were cleaned, entered, hardcoded and analyzed using Statistical Package for Social Sciences (SPSS) version 23. Summary statistics was presented using tables. Age and other anthropometric parameters such as weight, height, BMI, pulse rate, systolic blood pressure (SBP) and diastolic blood pressure (DBP) were categorized and summarized with mean and standard deviation. Continuous variables that are normally distributed (e.g. age) were analyzed using the t-test series while discontinuous variables that are not normally distributed (e.g. levels of thyroid hormones) were analyzed using the Mann-Whitney U test. The normality test was done using the Shapiro-Wilk test. The level of significance was set at p< 0.05 and at a confidence interval of 95% for all inferential statistics.

2.11. Ethical Considerations

Approval was obtained from UITH’s Ethical Review Committee. Written consent was obtained from all the participants after proper explanation and the data obtained were treated with confidentiality and used solely for the study. This ethical clearance ensured adequate professional work ethics and confidentiality of all patients’ data. Patients with thyroid abnormalities were referred for further evaluation, treatment, and were co-managed with endocrinologists. This research was also carried out with due observance of the ethical principles of the Declaration of Helsinki (DoH) in 2013 concerning human research.

3. Results

The socio-demographic variables of the respondents are presented in Table 1. The age bracket of 25-28 years had the highest number of respondents (30.2%), while the age group <25 years had the least (13.2%). The mean age was 32.18±6.47 years for the infertile women and 31.4±5.74 years for fertile women (control group). Most of the infertile women (79.2%) and fertile women (81.1%) were employed. Majority of the respondents (69.8%) had tertiary level of education. Due to the location of the study, most (83%) of the women were from the Yoruba tribe. The socio-demographic variables showed no significant differences.

Figure 1 presents the infertility types among the infertile women. Primary infertility accounted for 24.5% while secondary infertility accounted for 75.5%.

Table 2 summarizes the anthropometric parameters and blood pressure values of women with infertility and fertility. The mean BMI of the infertile women (27.05±5.46 kg/m2) was slightly higher than that of the fertile women (25.47±5.97 kg/m2) with no significant difference between the two groups (p=0.156). The pulse rates and blood pressure values were comparable in the two groups with no significant statistical difference.

Figure 2 depicts the patterns of thyroid dysfunctions among infertile and fertile women. Ten (9.43%) out of all the respondents were diagnosed with thyroid dysfunction. Eight infertile women had some form of thyroid dysfunction: four (7.5%) had subclinical hypothyroidism, two (3.8%) had overt (clinical) hypothyroidism, and two (3.8%) had overt (clinical) hyperthyroidism. Two fertile women had thyroid dysfunction: one (1.9%) had subclinical hypothyroidism and one (1.9%) had overt (clinical) hyperthyroidism. The majority of the participants were euthyroid - 45 (84.9%) infertile women versus 51 (96.2%) for the fertile women. No significant difference (p>0.05) was observed between each thyroid dysfunction in the infertile and fertile women, but the overall difference between infertile and fertile women with thyroid dysfunction was significant, p=0.046.

Table 3 shows menstrual patterns and anomalies in women with infertility and the fertile (control) group. Mean age at menarche was similar in the two groups - 14.24±2.26 years in infertile women and 14.43±2.04 years in fertile women (p=0.669). The mean cycle length was also comparable - 28.14±1.93 days (infertile group) versus 28.67±1.67 days (fertile group) (p=0.156). Menorrhagia was the most predominant menstrual anomaly in the respondents, and was present in 11 (20.8%) of infertile women and in 3 (5.7%) of fertile women. Menorrhagia accounted for the highest (56%) of the total incidence of menstrual anomalies. Five (9.4%) of the infertile women had oligomenorrhea versus four (7.5%) of the fertile women. Hypermenorrhea and amenorrhea accounted for 7.5% each, among the infertile women. Intermenstrual bleeding has a prevalence of 3.8% among the infertile women. None of the 106 study participants reported polymenorrhea. Only menorrhagia showed a significant difference (p=0.022) between the infertile and fertile women.

Table 4 shows the prevalence of menstrual anomalies among infertile and fertile women. More infertile women 26 (78.8%) had menstrual anomalies compared with fertile women 7 (21.2%) and this was significantly different (p=0.012). Twenty-seven (50.9%) infertile women had normal menses as against 46 (86.8%) fertile women.

Table 5 compares the pattern of thyroid dysfunction among infertile and fertile women. Four (7.5%) of the infertile women had subclinical hypothyroidism while one (1.9%) of the fertile women had subclinical hypothyroidism, and the difference was not significant (p=0.37). Overt (clinical) hypothyroidism was present in two of the infertile women but was absent in the fertile women. Overt (clinical) hyperthyroidism was present in two of the infertile women while only one fertile woman had it, and the difference was not significant (p=1.000). Majority of the study participants were euthyroid - 45 infertile women (84.9%) versus 51 fertile women (96.2%).

Table 6 shows the association between menstrual anomalies and the forms of thyroid dysfunction among infertile and fertile women. 3 (16.7%) of the infertile women with menstrual anomalies had subclinical hypothyroidism, 1 (5.6%) had overt (clinical) hypothyroidism, 1 (5.6%) had overt (clinical) hyperthyroidism, while the remaining 13 (72.2%) were euthyroid. Thirty-five infertile women without menstrual dysfunction had the following distributions of thyroid dysfunction among them: 1 (2.9%) subclinical hypothyroidism, 1 (2.9%) overt (clinical) hypothyroidism, 1 (2.9%) overt (clinical) hyperthyroidism, and 32 (91.3%) were euthyroid. On the other hand, 7 fertile women with menstrual anomalies showed that 1 (14.3%) had overt (clinical) hyperthyroidism and 6 (85.7%) were euthyroid. In addition, the 46 fertile women without menstrual anomalies showed that 1 (2.2%) had subclinical hypothyroidism and 45 (97.8%) were euthyroid.

4. Discussion

Menstrual anomaly is a topic that has received little attention in society despite its complications and ability to cause infertility in females. Aside from the control of basal metabolic rate and growth functions of the thyroid hormones, the hormones also play a role in maintaining normal menstrual cycle. This therefore means that thyroid gland dysfunction can alter the menstrual cycle and could be associated with infertility [41].

The thyroid hormones are involved in almost all phases of reproduction, from folliculogenesis to placentation [8]. In combination with follicle-stimulating hormone, triiodothyronine (T3) enhances granulosa cell proliferation and inhibits granulosa cell apoptosis by the phosphatidyl inositol 3-kinase/Akt (also known as protein kinase B) pathway [74]. Leukemia inhibitory factor (LIF) is involved in embryo implantation and expressed in the mid-secretory endometrium. Thyroid-stimulating hormone (TSH) significantly upregulates LIF expression in endometrial cell cultures, suggesting a potential role of TSH in the implantation process [2].

This study evaluated the anthropometric parameters of the infertile and fertile women. The mean weight of the infertile women was slightly higher, but the two groups had almost the same mean height. Both groups of women had a mean BMI of 25-29.9 making them mostly categorized as overweight. The mean blood pressure for the groups was within the normal range. However, the control group had a slightly higher mean pulse rate. Abnormal BMI and blood pressure levels have adverse effects on the clinical course of MSDs which can be observed on vital body organs such as the heart and kidneys [28, 33, 35, 63, 65, Twentieth Danilevsky readings. 2021; p. 86-87.">70].

The menstrual anomalies in this study were significantly more in infertile women than in fertile women. Thirty-three (33) of the study participants had menstrual anomalies, of which infertile and fertile women accounted for 78.8% and 21.2% respectively. The intragroup percentages for women with menstrual anomalies were 49.1% for infertile women and 13.2% for fertile women. This finding is less when compared to the findings that reported menstrual irregularities in 50% of the patients [52], and another finding that reported menstrual anomalies in 61.2% of infertile women [16]. Another study presented a lower incidence of 19.6% menstrual irregularities in the cases examined [48]. Moreover, menstrual anomalies in this study had more occurrence than thyroid dysfunction among the study respondents which supports the fact that the latter precedes the former [58].

This study showed that the most common form of menstrual anomaly was menorrhagia (56%). This finding is similar to the results of other studies in which menorrhagia was also the most common anomaly: 50% [53, 54], and 46.42% [42]. Oligomenorrhea in this present study was the second most prevalent menstrual anomaly (36%). This figure is higher than results reported in other studies: 17.86% [42] and 20% [58]. However, both studies agreed that oligomenorrhea was the second most prevalent anomaly. The fertile women in the present study had no incidence of intermenstrual bleeding, hypomenorrhea or amenorrhea.

Six (18.2%) out of the 33 women with menstrual anomalies were diagnosed with thyroid dysfunction while the remaining were euthyroid. Five (83.3%) of these 6 women with both menstrual anomaly and thyroid dysfuction were infertile while only one (16.7%) was fertile. The incidence of subclinical hypothyroidism was the highest (50%) among the women with menstrual anomalies, while overt (clinical) hyperthyroidism and overt (clinical) hypothyroidism were 33.3% and 16.7% respectively. This result is close to the results of Kumari, et al (43.48%) [42]; Sangita, et al (45.45%) [58]; Gandi, et al (45.45%) [13]; and George, et al (55.9%) [15] for the incidence of subclinical hypothyroidism in women with menstrual anomalies, but much lower than the result of Maria, et al (66.4%) [44]. Unlike this current study without diagnosis of subclinical hyperthyroidism, subclinical hyperthyroidism was diagnosed with an incidence of 13% [42] and 4.5% [58] among women with both menstrual anomaly and thyroid dysfunction.

The incidence of infertility in this study was 24.5% (primary infertility) and 75.5% (secondary infertility). This shares similarities with the results of another study which found 32.8% (primary infertility) and 67.2% (secondary infertility) [55]. The dominance of secondary infertility in this study agrees with some other African studies [4, 9, 50, 51], but disagrees with results of studies in some Western societies with 63.1 - 80.0% (primary infertility) dominance [17, 48].

Since thyroid dysfunctions have been associated with female infertility, it is important to evaluate thyroid gland function by estimating the serum levels of thyroid hormones rapidly and reliably using modern hormonal assay techniques. This procedure should be incorporated into the diagnostic routines in evaluating women with menstrual irregularities and infertility. It is also very important to note that an early detection of thyroid dysfunction can save patients from treatment costs of overt (clinical) thyroid dysfunction which may include surgery and/or radiotherapy.

Nevertheless, one limitation of this study should be clearly pointed out. The menstrual cycle consists of ovarian cycle and uterine cycle. These cycles are regulated by different hormones including prolactin, estrogen, progesterone, follicle stimulating hormone (FSH), luteinizing hormone (LH), etc. Therefore, these other hormones might have also contributed to the abnormal and normal menstrual patterns observed in this study, apart from thyroid hormones which this study concentrated on.

5. Conclusion

Thyroid gland dysfunctions strongly correlate with abnormal menstrual patterns. Early detection of thyroid gland dysfunction is vital in achieving a positive treatment outcome. Therefore, it is essential to evaluate serum levels of thyroid hormones during treatment of women with menstrual anomalies and infertility.

Acknowledgment: Special thanks to all the infertile and fertile women who voluntarily participated in this research after making an informed decision, for their cooperation and support in carrying out this research.

Authors’ Contribution: All authors contributed in different aspects of the research.

Conflict of Interest: The authors guarantee responsibility for everything published in this manuscript, as well as the absence of a conflict of interest and the absence of their financial interest in performing this research and writing this manuscript. This manuscript was written from an original research work.

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  31. Ikwuka AO. Dr. Aloy's Core Essential Series (DACES) Immunology. 1st Edition. Science and Education Publishing, USA. 2023; p. 30. ISBN: 978-978-795-866-7.
  32. Ikwuka AO. Dr. Aloy's Core Essential Series (DACES) Medical Genetics. 1st Edition. Science and Education Publishing, USA. 2023; p. 9. ISBN: 978-1-958293-02-7.
  33. Ikwuka AO, Virstyuk NG. Pattern of cardiac remodelling of the left ventricle in patients with essential hypertensive disease and concomitant type 2 diabetes mellitus. Clinical Medicine. 2019; 19(3): s92. DOI: 10.7861/clinmedicine.19-3-s92.[CrossRef] [PubMed]
  34. Ikwuka AO, Virstyuk NG. Influence of SGLT2 inhibitor and A2RB (AT1) on fibrogenesis and heart failure in patients with essential hypertensive disease combined with diabetes mellitus type 2. E-Poster No. 143 of the 44th & 45th Annual General and Scientific Meeting of the West African College of Physicians (WACP), 1 - 3 November, 2021. 2021; DOI: 10.13140/RG.2.2.26912.87047.
  35. Ikwuka AO, Virstyuk N. Prognostic markers of nephropathy in patients with dual metabolic syndrome diseases (essential hypertensive disease and concomitant type 2 diabetes mellitus). Endocrine Practice. 2022; 28(5): S65-S66. DOI: 10.1016/j.eprac.2022.03.164.[CrossRef]
  36. Ikwuka AO, Virstyuk N. Patterns and Influence of Cardio-Metabolic Insufficiency in Patients with Essential Hypertensive Disease and Concomitant Type 2 Diabetes Mellitus. Endocrine Practice. 2023; 29(5): S32-S33. DOI: 10.1016/j.eprac.2023.03.076.[CrossRef]
  37. Ikwuka AO, Virstyuk NG, Luchko OR, Kobitovych I. Heterogeneity Of Renal Pathogenicity On The Background Of Asymptomatic Hyperuricemia In Patients With Dual Metabolic Syndrome Diseases (Essential Hypertensive Disease and Type 2 Diabetes Mellitus). British Journal of Medical and Health Research. 2023; 10(2): 1-9. DOI: 10.5281/zenodo.7690636.
  38. Inya AU, Achara AP, Ikwuka AO, Udeh FC, Chi-kadibia U, Onazi O. Patterns, Peculiarities and Associated Risk Factors of Anemia in Pregnancy: A Case Study of Pregnant Women Attending Antenatal Clinic in North-Central Nigeria. European Journal of Preventive Medicine. 2023; 11(2): 21-31. DOI: 10.11648/j.ejpm.20231102.12.[CrossRef]
  39. Inya AU, Achara AP, Ikwuka AO, Udeh FC, Chi-kadibia U, Onazi O. Clinical Dynamics of Anemia in Pregnancy: A 16-week Cross-sectional Study of Pregnant Women Who Attended Antenatal Clinic of Federal Medical Center, Keffi, Nasarawa State, Nigeria. American Journal of Clinical Medicine Research. 2023; 11(1): 1-9. DOI: 10.12691/ajcmr-11-1-1.[CrossRef]
  40. Karout N, Hawai SM, Altuwaijri S. Prevalence and pattern of menstrual disorders among Lebanese nursing students. East Mediterranean Health Journal. 2012; 18(4): 346-352.[CrossRef] [PubMed]
  41. Krassas GE, Pontikides N, Kaltsas T, Papadopoulou P, Paunkovic J, Paunkovic N. Disturbances of menstruation in hypothyroidism. Clinical Endocrinology. 1999; 50(5): 655–659.[CrossRef] [PubMed]
  42. Kumari A, Rohatgi R, Singh A. Evaluation of thyroid dysfunction in patients with menstrual disorders of reproductive age group: A prospective cross-sectional study. International Journal of Reproduction, Contraception, Obstetrics and Gynaecology. 2021; 10(20): 642-646.[CrossRef]
  43. Lee Y, Kim C, Kwack J, Ahn J, Kim S, Chae H, Kang B. Subclinical hypothyroidism diagnosed by thyrotropin-releasing hormone stimulation test in infertile women with basal thyroid-stimulating hormone levels of 2.5 to 5.0 mIU /L. Obstetrics and Gynaecology Sciences. 2014; 57(6): 507–512.[CrossRef] [PubMed]
  44. Maria JD, Jayakumari S, Sundaram PS. A prospective study on hypothyroidism in premenopausal women. International Journal of Pharmaceutical Science Review and Research. 2016; 39(1): 183-7.
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  48. Nasir S, Khan MM, Ahmed S, Alam S, Ziaullah S. Role of thyroid dysfunction in infertile women with menstrual disturbances. Gomal Journal of Medical Sciences. 2016; 14(1): 20–24.
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  51. Okonofua FE. Infertility in Sub-Saharan Africa. In: F.E. Okonofua & K. Odunsi (Eds.), Contemporary Obstetrics and Gynaecology for Developing Countries. Women’s Health and Action Research Center. 2003; p. 128-156.
  52. Orazulike N, Odum E. Evaluation of thyroid function in infertile female patients in Port-Harcourt, Nigeria. Tropical Journal of Obstetrics and Gynaecology. 2018; 35(1): 38-42.[CrossRef]
  53. Padmaleela K, Thomas V, Lavanya KM. Thyroid disorders in dysfunctional uterine bleeding (DUB) among reproductive age group women - a cross-sectional study in a tertiary care hospital in Andhra Pradesh, India. International Journal of Medicine and Pharmaceutical Sciences. 2013; 4(1): 41-46.
  54. Pahwa S, Shailja G, Jasmine K. Thyroid dysfunction in dysfunctional uterine bleeding. Journal of Advanced Researches in Biological Sciences. 2013; 5(1): 78-83.
  55. Panti A, Sununu Y. The profile of infertility in a teaching hospital in North West Nigeria. Sahel Medical Journal. 2014; 17(1): 7–11.[CrossRef]
  56. Poppe K, Glinoer D. Thyroid autoimmunity and hypothyroidism before and during pregnancy. Human Reproduction Update. 2003; 9(2): 149-61.[CrossRef] [PubMed]
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  58. Sangita AN, Sarbhai V, Yadav N, Paul M, Ahmad A, Ajmani AK. Role of thyroid dysfunction in patients with menstrual disorders in tertiary care centre of walled city of Delhi. Journal of Obstetrics and Gynecology India. 2016; 66(2): 115-119.[CrossRef] [PubMed]
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  60. Udeh FC, Ikwuka AO, Epete MA, Igwe EC. Effects of local tobacco snuff ingestion during pregnancy on renal functions and histology architecture of female Wistar rats and on the birth weight of their pups. American Journal of Medical Sciences and Medicine. 2023; 11(1): 1-5. DOI: 10.12691/ajmsm-11-1-1.[CrossRef]
  61. Udeh FC, Ikwuka AO, Epete MA, Igwe EC. Effects of oral consumption of Nicotiana tabacum during pregnancy on the liver and prolactin levels of adult female Wistar rats. European Journal of Veterinary Medicine. 2023; 3(2): 1-5. DOI: 10.24018/ejvetmed.2023.3.2.93.[CrossRef]
  62. Virstyuk NG, Ikwuka AO, Haman IO, Adebomi MS. Diabetes mellitus type 2, arterial hypertension and dyslipidemia. Materials of 2nd International Scientific and Practical Conference "Therapeutic readings: modern aspects of diagnosis and treatment of diseases of internal organs". 2016; p. 46-47.
  63. Virstyuk NG, Ikwuka AO. Diagnostic and prognostic markers of the diabetes mellitus type 2 course in connection with essential arterial hypertension taking into account the kidney function. Precarpathian Journal Pulse (ISSN: 2304-7437). 2017; 8(44): 53-62.
  64. Virstyuk NG, Ikwuka AO. Features of asymptomatic hyperuricemia in patients with diabetes mellitus type 2 and concomitant essential arterial hypertension. Clinical and Experimental Pathology. 2018; 1(63): 22-26. DOI: 10.24061/1727-4338.XVII.1.63.2018.5.[CrossRef]
  65. Virstyuk NG, Ikwuka AO. Nephropathic characteristics in patients with diabetes mellitus type 2 and essential hypertensive disease. Art of Medicine. 2019; 1(5): 44-47. DOI: 10.21802/artm.2019.1.9.44.[CrossRef]
  66. Virstyuk NG, Ikwuka AO. Asymptomatic hyperuricemia and functional state of the kidneys in patients with essential arterial hypertension and concomitant diabetes mellitus type 2. European Journal of Clinical Medicine. 2021; 2(3): 100-104. DOI: 10.24018/clinicmed.2021.2.3.65.[CrossRef]
  67. Virstyuk NG, Ikwuka AO, Didushko OM. Effect of dapagliflozin on the level of uric acid during asymptomatic hyperuricemia in patients with diabetes mellitus type 2 and concomitant arterial hypertension. Art of Medicine. 2018; 1(5): 21-26. Available online: https://art-of-medicine.ifnmu.edu.ua/index.php/aom/article/view/179/150[CrossRef]
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  70. Virstyuk NH, Ikwuka AO, Luchko OR, Kocherzhat OI. Peculiarities of renal insufficiency in patients with diabetes mellitus type 2 and arterial hypertension. Materials of scientific-practical conference with international participation "Achievements and prospects of experimental and clinical endocrinology" Twentieth Danilevsky readings. 2021; p. 86-87.
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Aliu-Ayo, H. I., Adesina, K. T., Jimoh, A. A. G., Ikwuka, A. O., Udeh, F. C., Biliaminu, S. A., & Ayo, O. W. (2023). Correlation of Thyroid Gland Functions with Menstrual Patterns amongst Infertile and Fertile Women Attending a Tertiary Care Hospital in North-Central Nigeria. World Journal of Clinical Medicine Research, 3(1), 13–26. Retrieved from https://www.scipublications.com/journal/index.php/wjcmr/article/view/787
  1. Adebimpe WO, Farinloye EO, Adeleke NA. Menstrual pattern and disorders and impact on quality of life among university students in South-Western Nigeria. Journal of Basic and Clinical Reproductive Sciences. 2016; 5(1): 27-32.[CrossRef]
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  3. Albers JR, Hull SK, Wesley RM. Abnormal uterine bleeding. American Family Physician. 2004; 69(8): 1915–1934.
  4. Bala M, Alfred A, Mohammed B. Clinical presentation of infertility in Gombe, North-Eastern Nigeria. Tropical Journal of Obstetrics and Gynaecology. 2003; 20(2): 93–96.[CrossRef]
  5. Baysah PV, Ikwuka AO, Udeh FC, Bleh DP, Viloria T. Pathophysiological Effects of Alcohol and Tobacco Consumption on Semen Parameters of Men Attending a Fertility Clinic in West Africa. American Journal of Biomedical and Life Sciences. 2023; 11(4): 73-81. DOI: 10.11648/j.ajbls.20231104.13.[CrossRef]
  6. Cappola AR, Ladenson PW. Hypothyroidism and Atherosclerosis. Journal of Clinical Endocrinology and Metabolism. 2003; 88(6): 2438–44.[CrossRef] [PubMed]
  7. Charan J, Biswas T. How to calculate sample size for different study designs in medical research. Indian Journal of Psychological Medicine. 2013; 35(2): 121–126.[CrossRef] [PubMed]
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  9. Ekanem I, Ekanem A. Endometrial pathology associated with infertility among Nigerian women. Nigerian Postgraduate Medical Journal. 2006; 13(4): 344–347.[CrossRef]
  10. Ekechi HO, Ikwuka AO, Udeh FC, Abraham JC. Effects of ethanol extract of Rauwolfia vomitoria leaf on lipid profile and cerebellar histology in cisplatin-induced oxidative stress. British Journal of Medical and Health Research. 2023; 10(5): 16-39. DOI: 10.5281/zenodo.8042521.
  11. Elahi S, Tasneem A, Nazir I, Nagra S, Hyder S. Thyroid dysfunction in infertile women. Journal of the College of Physicians and Surgeons of Pakistan. 2007; 17(4): 191–194.
  12. Fatima A, Hooja N, Mital P, Singh N, Gothwal S. Correlation of menstrual pattern with thyroid hormone level in infertile women. International Journal of Sciences & Applied Research. 2014; 1(2): 10–12.
  13. Gandi SR, Vishwekar P, Yadav RS, Chauhan N. Study of thyroid dysfunction in women with menstrual disorders: A prospective study. International Journal of Gynaecology. 2019; 9(3): 89-93.[CrossRef]
  14. Geddes L. Irregular periods linked to increased risk of death before the age of 70, says BMJ. The Guardian. 2020; Available online: https://www.theguardian.com/society/2020/oct/01/irregular-periods-linked-to-increased-risk-of-death-before-the-age-of-70-says-bmj
  15. George L, Jacob KJ, Shankar SB. The role of thyroid hormone status in abnormal uterine bleeding. Journal of Evolution Medical and Dental Sciences. 2017; 6(76): 5448-5451.[CrossRef]
  16. Goswami B, Patel S, Chatterjee M, Koner B, Saxena A. Correlation of prolactin and thyroid hormone concentration with menstrual patterns in infertile women. Journal of Reproduction and Infertility. 2009; 10(3): 207–212.
  17. Habbu PP, Shaikh AK. Study of thyroid dysfunction in association with infertility. International Journal of Biochemistry Research Review. 2016; 11(2): 1–6.[CrossRef] [PubMed]
  18. Harlow SD, Campbell OM. Menstrual dysfunction: A missed opportunity for improving reproductive health in developing countries. Reproductive Health Matters. 2000; 8(15): 142-147.[CrossRef] [PubMed]
  19. Ikwuka AO. Risk factors for the pathogenesis of diabetes mellitus type 2. Materials of 84th Scientific and Practical Conference of Students and Young Scientists with International Participation “Innovations in medicine”. 2015; p. 19. Available online: http://www.ifnmu.edu.ua/images/snt/files/konferenciya/Tezu_2015.pdf
  20. Ikwuka AO. Dyslipidemia risk severity in patients with diabetes mellitus type 2 and essential hypertension. Journal of the 21st International Medical Congress of Students and Young Scientists. 2017; p. 59.
  21. Ikwuka AO. Effectiveness of dapagliflozin in patients with diabetes mellitus type 2 and essential hypertension. Book of abstracts of the 7th International Students’ Scientific Conference of Young Medical Researchers. 2017; p. 102. Available online: http://www.stn.umed.wroc.pl/files/lm/Accepted_papers.16113.pdf
  22. Ikwuka AO. Influence of dyslipidemia in patients with diabetes mellitus type 2 and essential hypertension. The Pharma Innovation Journal. 2017; 6(3): 101-103. Available online: http://www.thepharmajournal.com/archives/?year=2017&vol=6&issue=3&part=B
  23. Ikwuka AO, Haman IO. Features of kidney damage in patients with diabetes mellitus type 2 and essential hypertension. Journal of 86th Scientific and Practical Conference of Students and Young Scientists with International Participation “Innovations in medicine”. 2017; p. 144. Available online: http://www.ifnmu.edu.ua/images/snt/86-konf-tezi%20(1).pdf
  24. Ikwuka AO, Virstyuk NG, Luchko OR. Features of the functional state of kidneys in patients with diabetes mellitus type 2 and essential arterial hypertension. Materials of scientific-practical conference with international participation “Babenkivski reading”. 2017; p. 48.
  25. Ikwuka AO. Clinical dynamics in patients with diabetes mellitus type 2 and concomitant essential hypertensive disease treated with dapagliflozin. Journal of the 22nd International Medical Congress of Students and Young Scientists. 2018; p. 32.
  26. Ikwuka AO. Clinical effectiveness of SGLT-2 inhibitors in patients with diabetes mellitus type 2 and essential hypertensive disease. Endocrine Practice. 2018; 24(1): 74. DOI: 10.1016/S1530-891X(20)47129-0.[CrossRef]
  27. Ikwuka AO. Features of kidney damage in patients with arterial hypertension and type 2 diabetes mellitus and optimization of treatment. Specialized Academic Council IFNMU. 2018; Available online: http://www.ifnmu.edu.ua/images/zagalna_informacia/spec_vcheni_radi/2017-2019/%D0%9420.601.01/Ikvuka/Avtoreferat.pdf
  28. Ikwuka AO, Paliy Yu. Structural changes of the left ventricular myocardium in patients with essential arterial hypertension and diabetes mellitus type 2. Abstracts of the 87th Scientific Conference of Students and Young Scientists with International Participation “Innovations in medicine”. 2018; p. 25-26. Available online: https://www.ifnmu.edu.ua/images/snt/zaproshennia_eng.pdf
  29. Ikwuka AO. Clinical dynamics of nephropathy in patients with diabetes mellitus type 2 and concomitant essential hypertensive disease. Clinical Medicine. 2019; 19(2): s39. DOI: 10.7861/clinmedicine.19-2-s39.[CrossRef] [PubMed]
  30. Ikwuka AO. Clinical effectiveness of GLP-1 RAs in patients with metabolic syndrome diseases. Endocrine Practice. 2019; 25(1): 104-105. DOI: 10.1016/S1530-891X(20)46611-X.[CrossRef]
  31. Ikwuka AO. Dr. Aloy's Core Essential Series (DACES) Immunology. 1st Edition. Science and Education Publishing, USA. 2023; p. 30. ISBN: 978-978-795-866-7.
  32. Ikwuka AO. Dr. Aloy's Core Essential Series (DACES) Medical Genetics. 1st Edition. Science and Education Publishing, USA. 2023; p. 9. ISBN: 978-1-958293-02-7.
  33. Ikwuka AO, Virstyuk NG. Pattern of cardiac remodelling of the left ventricle in patients with essential hypertensive disease and concomitant type 2 diabetes mellitus. Clinical Medicine. 2019; 19(3): s92. DOI: 10.7861/clinmedicine.19-3-s92.[CrossRef] [PubMed]
  34. Ikwuka AO, Virstyuk NG. Influence of SGLT2 inhibitor and A2RB (AT1) on fibrogenesis and heart failure in patients with essential hypertensive disease combined with diabetes mellitus type 2. E-Poster No. 143 of the 44th & 45th Annual General and Scientific Meeting of the West African College of Physicians (WACP), 1 - 3 November, 2021. 2021; DOI: 10.13140/RG.2.2.26912.87047.
  35. Ikwuka AO, Virstyuk N. Prognostic markers of nephropathy in patients with dual metabolic syndrome diseases (essential hypertensive disease and concomitant type 2 diabetes mellitus). Endocrine Practice. 2022; 28(5): S65-S66. DOI: 10.1016/j.eprac.2022.03.164.[CrossRef]
  36. Ikwuka AO, Virstyuk N. Patterns and Influence of Cardio-Metabolic Insufficiency in Patients with Essential Hypertensive Disease and Concomitant Type 2 Diabetes Mellitus. Endocrine Practice. 2023; 29(5): S32-S33. DOI: 10.1016/j.eprac.2023.03.076.[CrossRef]
  37. Ikwuka AO, Virstyuk NG, Luchko OR, Kobitovych I. Heterogeneity Of Renal Pathogenicity On The Background Of Asymptomatic Hyperuricemia In Patients With Dual Metabolic Syndrome Diseases (Essential Hypertensive Disease and Type 2 Diabetes Mellitus). British Journal of Medical and Health Research. 2023; 10(2): 1-9. DOI: 10.5281/zenodo.7690636.
  38. Inya AU, Achara AP, Ikwuka AO, Udeh FC, Chi-kadibia U, Onazi O. Patterns, Peculiarities and Associated Risk Factors of Anemia in Pregnancy: A Case Study of Pregnant Women Attending Antenatal Clinic in North-Central Nigeria. European Journal of Preventive Medicine. 2023; 11(2): 21-31. DOI: 10.11648/j.ejpm.20231102.12.[CrossRef]
  39. Inya AU, Achara AP, Ikwuka AO, Udeh FC, Chi-kadibia U, Onazi O. Clinical Dynamics of Anemia in Pregnancy: A 16-week Cross-sectional Study of Pregnant Women Who Attended Antenatal Clinic of Federal Medical Center, Keffi, Nasarawa State, Nigeria. American Journal of Clinical Medicine Research. 2023; 11(1): 1-9. DOI: 10.12691/ajcmr-11-1-1.[CrossRef]
  40. Karout N, Hawai SM, Altuwaijri S. Prevalence and pattern of menstrual disorders among Lebanese nursing students. East Mediterranean Health Journal. 2012; 18(4): 346-352.[CrossRef] [PubMed]
  41. Krassas GE, Pontikides N, Kaltsas T, Papadopoulou P, Paunkovic J, Paunkovic N. Disturbances of menstruation in hypothyroidism. Clinical Endocrinology. 1999; 50(5): 655–659.[CrossRef] [PubMed]
  42. Kumari A, Rohatgi R, Singh A. Evaluation of thyroid dysfunction in patients with menstrual disorders of reproductive age group: A prospective cross-sectional study. International Journal of Reproduction, Contraception, Obstetrics and Gynaecology. 2021; 10(20): 642-646.[CrossRef]
  43. Lee Y, Kim C, Kwack J, Ahn J, Kim S, Chae H, Kang B. Subclinical hypothyroidism diagnosed by thyrotropin-releasing hormone stimulation test in infertile women with basal thyroid-stimulating hormone levels of 2.5 to 5.0 mIU /L. Obstetrics and Gynaecology Sciences. 2014; 57(6): 507–512.[CrossRef] [PubMed]
  44. Maria JD, Jayakumari S, Sundaram PS. A prospective study on hypothyroidism in premenopausal women. International Journal of Pharmaceutical Science Review and Research. 2016; 39(1): 183-7.
  45. Monobindinc. Thyrotropin (TSH) Test System. Product code: 325-300. Lake Forest. 2012.
  46. Monobindinc. Free Triiodothyronine (fT3) Test System. Product code: 1325-300. Lake Forest. 2012.
  47. Monobindinc. Free Thyroxine (fT4) Test System. Product code: 1225-300. Lake Forest. 2012.
  48. Nasir S, Khan MM, Ahmed S, Alam S, Ziaullah S. Role of thyroid dysfunction in infertile women with menstrual disturbances. Gomal Journal of Medical Sciences. 2016; 14(1): 20–24.
  49. Nitika LP. Prevalence and determinants of menstrual disorders and napkin usage among women in India using DLHS-4 data. Journal of Family Medicine and Primary Care. 2019; 8(6): 2106-2111.[CrossRef] [PubMed]
  50. Obuna J, Ndukwe E, Ugboma H, Ejikeme B, Ugboma E. Clinical presentation of infertility in an outpatient clinic of a resource poor setting, South-East Nigeria. International Journal of Tropical Diseases and Health. 2012; 2(2): 123–131.[CrossRef] [PubMed]
  51. Okonofua FE. Infertility in Sub-Saharan Africa. In: F.E. Okonofua & K. Odunsi (Eds.), Contemporary Obstetrics and Gynaecology for Developing Countries. Women’s Health and Action Research Center. 2003; p. 128-156.
  52. Orazulike N, Odum E. Evaluation of thyroid function in infertile female patients in Port-Harcourt, Nigeria. Tropical Journal of Obstetrics and Gynaecology. 2018; 35(1): 38-42.[CrossRef]
  53. Padmaleela K, Thomas V, Lavanya KM. Thyroid disorders in dysfunctional uterine bleeding (DUB) among reproductive age group women - a cross-sectional study in a tertiary care hospital in Andhra Pradesh, India. International Journal of Medicine and Pharmaceutical Sciences. 2013; 4(1): 41-46.
  54. Pahwa S, Shailja G, Jasmine K. Thyroid dysfunction in dysfunctional uterine bleeding. Journal of Advanced Researches in Biological Sciences. 2013; 5(1): 78-83.
  55. Panti A, Sununu Y. The profile of infertility in a teaching hospital in North West Nigeria. Sahel Medical Journal. 2014; 17(1): 7–11.[CrossRef]
  56. Poppe K, Glinoer D. Thyroid autoimmunity and hypothyroidism before and during pregnancy. Human Reproduction Update. 2003; 9(2): 149-61.[CrossRef] [PubMed]
  57. Saladin KS, McFarland RK, Gan CA, Cushman HN. Essentials of Anatomy and Physiology. 2nd ed. McGraw Hill. 2014; p. 657.
  58. Sangita AN, Sarbhai V, Yadav N, Paul M, Ahmad A, Ajmani AK. Role of thyroid dysfunction in patients with menstrual disorders in tertiary care centre of walled city of Delhi. Journal of Obstetrics and Gynecology India. 2016; 66(2): 115-119.[CrossRef] [PubMed]
  59. Thiyagarajan DK, Basit H, Jeanmonod R. Physiology, menstrual cycle. StatPearls Publishing. 2022.
  60. Udeh FC, Ikwuka AO, Epete MA, Igwe EC. Effects of local tobacco snuff ingestion during pregnancy on renal functions and histology architecture of female Wistar rats and on the birth weight of their pups. American Journal of Medical Sciences and Medicine. 2023; 11(1): 1-5. DOI: 10.12691/ajmsm-11-1-1.[CrossRef]
  61. Udeh FC, Ikwuka AO, Epete MA, Igwe EC. Effects of oral consumption of Nicotiana tabacum during pregnancy on the liver and prolactin levels of adult female Wistar rats. European Journal of Veterinary Medicine. 2023; 3(2): 1-5. DOI: 10.24018/ejvetmed.2023.3.2.93.[CrossRef]
  62. Virstyuk NG, Ikwuka AO, Haman IO, Adebomi MS. Diabetes mellitus type 2, arterial hypertension and dyslipidemia. Materials of 2nd International Scientific and Practical Conference "Therapeutic readings: modern aspects of diagnosis and treatment of diseases of internal organs". 2016; p. 46-47.
  63. Virstyuk NG, Ikwuka AO. Diagnostic and prognostic markers of the diabetes mellitus type 2 course in connection with essential arterial hypertension taking into account the kidney function. Precarpathian Journal Pulse (ISSN: 2304-7437). 2017; 8(44): 53-62.
  64. Virstyuk NG, Ikwuka AO. Features of asymptomatic hyperuricemia in patients with diabetes mellitus type 2 and concomitant essential arterial hypertension. Clinical and Experimental Pathology. 2018; 1(63): 22-26. DOI: 10.24061/1727-4338.XVII.1.63.2018.5.[CrossRef]
  65. Virstyuk NG, Ikwuka AO. Nephropathic characteristics in patients with diabetes mellitus type 2 and essential hypertensive disease. Art of Medicine. 2019; 1(5): 44-47. DOI: 10.21802/artm.2019.1.9.44.[CrossRef]
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  67. Virstyuk NG, Ikwuka AO, Didushko OM. Effect of dapagliflozin on the level of uric acid during asymptomatic hyperuricemia in patients with diabetes mellitus type 2 and concomitant arterial hypertension. Art of Medicine. 2018; 1(5): 21-26. Available online: https://art-of-medicine.ifnmu.edu.ua/index.php/aom/article/view/179/150[CrossRef]
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