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Volume 15, Issue 9 (9-2017)
IJRM 2017, 15(9): 583-588 |
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Asgharnia M, Mirblouk F, Kazemi S, Pourmarzi D, Mahdipour Keivani M, Dalil Heirati S F. Maternal serum uric acid level and maternal and neonatal complications in preeclamptic women: A cross-sectional study. IJRM 2017; 15 (9) :583-588
URL: http://ijrm.ir/article-1-862-en.html
URL: http://ijrm.ir/article-1-862-en.html
Maryam Asgharnia1 
, Fariba Mirblouk1 , Soudabeh Kazemi * 2, Davood Pourmarzi1 , Mina Mahdipour Keivani3 , Seyedeh Fatemeh Dalil Heirati1
, Fariba Mirblouk1 , Soudabeh Kazemi * 2, Davood Pourmarzi1 , Mina Mahdipour Keivani3 , Seyedeh Fatemeh Dalil Heirati1
1- Reproductive Health Research Center, Guilan University of Medical Sciences, Rasht, Iran
2- Reproductive Health Research Center, Guilan University of Medical Sciences, Rasht, Iran , drsodabehkazemi@gmail.com
3- Guilan University of Medical Sciences, Rasht, Iran.
2- Reproductive Health Research Center, Guilan University of Medical Sciences, Rasht, Iran , drsodabehkazemi@gmail.com
3- Guilan University of Medical Sciences, Rasht, Iran.
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Introduction
Preeclampsia with the prevalence of 10.5% is a blood pressure disorder. It is a multi-systemic disease with unknown etiology. It is indicated by >140/90 mm Hg blood pressure with or without proteinuria after 20 wk of gestation. Hypertension during pregnancy is associated with maternal and neonatal complications (1, 2). In developed countries, 16% of maternal deaths are caused by high blood pressure which is higher than other factors such as bleeding (13%), abortion (8%) and sepsis (2%) (3). In Iran, the prevalence of hypertensive disorders during pregnancy is reported as 8.1% (4, 5). Up to now, there is no reliable, valid, and cost-effective screening test for the early detection of preeclampsia. It seems that measuring the blood level of uric acid is one of the available and cheap screening tests that have already been taken into account. Uric acid is the final product of purine metabolism oxidation which is mainly excreted in the urine. Since increased uric acid is the first and earliest laboratory presentation of preeclampsia as a result of reduced clearance of uric acid due to decreased glomerular filtration clearance, increased tubular reabsorption, and reduced secretion, some investigators use serum uric acid as a criterion for preeclampsia (3).It has been indicated that uric acid might not only have a predictive role in preeclampsia but also play a significant role in the maternal and fetal pathogenesis and presentations (3). However, previous studies mentioned inconsistent results (6, 7). Some previous investigations mentioned a higher level of uric acid in patients with preeclampsia compared to healthy subjects (8, 9). However, other studies mentioned that changes in uric acid levels in preeclampsia might be as a result of associated diseases. They noted no important predictive value for uric acid (10, 11). Also, epidemiological studies on non-pregnant individuals showed that hyperuremia could be associated with hypertension, metabolic syndrome, coronary artery disease, cardiovascular disease and chronic kidney disease (12, 13).
Given the importance of preeclampsia in maternal and neonatal complications, in this study, we aimed to investigate the relationship between the level of uric acid with maternal and neonatal complications in women with preeclampsia. Knowing the effect of uric acid on the severity of preeclampsia and maternal and neonatal complications can help early diagnosis, control, and treatment. Results can be used for clinical decision-making and prevent from maternal and neonatal complications.
Materials and methods
In this cross-sectional study, 160 preeclamptic women (severe and nonsevere) at more than 28 weeks gestational age admitted to Al-Zahra Hospital in Rasht, Iran during 2014-2015 were included. Diagnostic criteria were having hypertension to the extent of 140/90 mmgHg or more after 20 wk of pregnancy in women with or without proteinuria in previously normotensive. Also, hypertension in pregnant women with a history of preeclampsia was noted by >30 mm Hg increase in systolic blood pressure or >15 mmHg increase in diastolic blood pressure. Severe preeclampsia was diagnosed when systolic pressure ≥160 mmHg, diastolic pressure ≥110 mmHg with or without proteinuria, headache, visual changes, upper abdominal pain, oliguria, increased serum creatinine and liver transaminases and thrombocytopenia (<100,000).
Measurement of blood pressure was performed by a single resident of obstetrics and gynecology. All pregnant women with smoking, diabetes or gestational diabetes, hemoglobinopathies, nephropathy, acute and chronic renal failure, glomerulopathy, urinary tract infection, hepatic dysfunction, gout, hypothyroidism or hyperthyroidism, fetal and placental malformations, and multiple pregnancies were excluded.
Of all women who met the inclusion criteria, 5 ml of blood from an anterior Cubital vein was taken and hemoglobin, hematocrit, platelet count, and liver and uric acid tests were assessed. For all women, 24-hr urine protein, creatinine, urine dipstick tests, and random urine samples were also performed. Uric acid was assessed using Pars test kit and by BT2000 (Italy) auto-analyzer system. All laboratory tests were conducted in Al-Zahra hospital.
Data including age, gravidity, parity, gestational age, and history of hypertension before pregnancy were collected through interviews. Weight and height were measured and body mass index (BMI) was calculated. Maternal complications included severity of preeclampsia, placental abruption, preterm labor (PTL), thrombocytopenia, elevated alanine aminotransferase (ALT) and aspartate aminotransferase (AST), HELLP syndrome (Hemolysis, Elevated Liver enzymes, and Low Platelet count), eclampsia and required hospitalization in the ICU were assessed. Neonatal complications including small for gestational age (SGA), intrauterine fetal death, hospitalization in the neonatal intensive care unit, and Apgar score <7 at five minutes were investigated.
Ethical consideration
This study was approved by the Ethics Committee of Guilan University of Medical Sciences (1930596730). Written informed consents were obtained from all participants before enrollment.
Statistical analysis
Data were analyzed using Statistical Package for the Social Sciences (version 21.0, SPSS Inc, Chicago, and Illinios, USA). Independent samples t-test was used to compare means between groups. Also, univariate logistic regression analysis using forward: LR method was used to assess the relationship between levels of uric acid and the incidence of maternal and neonatal complications. In the regression analysis, the effect of uric acid levels, age, gestational age, gravidity, parity, the platelet count, albuminuria, hemoglobin, hematocrit, creatinine, body mass index, and effect of hypertension before pregnancy on maternal and neonatal complications were examined. The p<0.05 indicated statistical significance and 95% confidence interval was noted.
Results
In this study, 160 preeclamptic women participated, which 38 of them were severe preeclampsia (23.8%) and 122 of them were none severe (76.3%). The mean age of participants was 31.18±5.41 yr. 14.4% (n=23) had a history of hypertension before pregnancy and 71.3% (114) had albuminuria. Demographic characteristics and laboratory results have been reported in table I. Mean level of uric acid in women with severe pre- eclampsia (5.66±1.46) was significantly higher than non-severe preeclampsia (5.12±1.29) (p=0.031). In univariate analysis, the mean level of uric acid in women with hepatic dysfunction was significantly higher than the non hepatic dysfunction group (p=0.009). Also, women with preterm delivery had higher uric acid levels than women with normal term pregnancy (p=0.0001). Uric acid levels in women with neonates hospitalized in Neonate invasive care unit (NICU) were significantly higher than other women (p=0.016). In the case of maternal and neonatal complications, there was no significant difference between groups regarding the level of uric acid (Table II).
Based on the logistic regression analysis, 1 mg/dl increase in blood uric acid level induced 1.74 fold increase in the risk of hepatic dysfunction (OR: 1.74, 95% CI: 1.12-2.72). Also, with 1% increase in hematocrit, the chance of hepatic dysfunction will be about 1.3 times higher. Other variables had no effect on increasing or decreasing the risk of hepatic dysfunction in pregnant women with preeclampsia. In the present study by 1 mg/dl, increase in serum uric acid, 1.54 fold increase in the risk of PTL was noted (OR: 1.54, 95% CI: 1.15-2 ). Furthermore, by 1 mg/dl increase in serum hemoglobin and creatinin, 1.6 and 1.06 fold increase in the risk of PTL was noted, respectively. While other variables did not increase or decrease the chance of PTL in pregnant women with preeclampsia.
Based on regression analysis, results showed that the level of uric acid had no effect on hospitalization of infants in the NICU. Also, the level of uric acid had no effect on neonatal hospitalization in NICU. However, by 1 mg/dl increase in hemoglobin and AST in pregnant women with preeclampsia, 1.6 and 1.022 fold increase in the risk of hospitalization in NICU was noted, respectively. The positive history of hypertension before pregnancy indicated 3.8 fold increase in hospitalization in NICU. (Table III).
Table I. Demographic characteristics and laboratory results of the study participants
95-88-4/table_1.jpg)
Table II. Univariate analysis of pregnancy outcomes in study participants
95-88-4/table_2.jpg)
Table III. Logistic regression analysis on the factors affecting the incidence of hepatic dysfunction, premature birth, and NICU hospitalization in women with preeclampsia
95-88-4/table_3.jpg)
Discussion
In this study, the mean level of uric acid in women with severe preeclampsia was significantly higher than non-severe preeclampsia. In a study by Sultana and colleagues, which compared the mean levels of uric acid in subjects with normal blood pressure and preeclampsia, results showed that preeclampsia was associated with hyperuricemia (14). Also, Gianni et al followed patients for a month after delivery and mentioned uric acid as a reliable predictor of preeclampsia in women with gestational hypertension. They indicated uric acid with cut-off of 309 µm/l as a predictor of preeclampsia (8).
Enaruna et al also showed that uric acid levels in women with severe pre-eclampsia were higher than the control group (11). Chen and co-workers showed a higher level of serum uric acid in women with preeclampsia and the increase occurred with the onset of preeclampsia. There was no significant difference between preeclampsia and normal subjects regarding the mean level of uric acid in the first and second trimesters. Chen et al stated that serum uric acid levels increased with the onset of clinical signs of preeclampsia, but it might not be a predictor of preeclampsia and should not be considered as a predictive biomarker (15). According to results, although preeclampsia might cause an increase in uric acid, the inverse association did not exist. Laughon et al mentioned that the increase of uric acid in the first trimester of pregnancy was associated with preeclampsia and hypertension during pregnancy was related to hyperuricemia (16).
Hawkins et al reported that hyperuricemia in pregnant women with high blood pressure was an important finding which might expose women to adverse maternal and fetal complications. Even women with gestational hypertension, without other signs of pre-eclampsia had adverse embryonic complications such as SGA and pre-maturity. In this study, uric acid was measured near-term period which was similar to ours (17).
Elmas et al showed higher levels of uric acid, xanthine oxidase and Allantoin activity and blood pressure in patients with preeclampsia versus the control group (18). Elmas et al suggested that increased uric acid, xanthine oxidase and Allantoin activity might be noted following the death of placental cells consequent the abnormal activity of trophoblast in preeclampsia. Therefore, currently, clinicians prefer the mentioned causes for increased uric acid in preeclampsia instead of the effect of kidney disease following preeclampsia (19).
Corominas et al showed that up to 20 weeks of gestation, the mean level of uric acid in preeclampsia and normal women were similar. But after 20th wk of gestation, the mean level of uric acid in women with preeclampsia was 1.5 fold higher than control and healthy subjects. This increase coincided with stable creatinin and urea in patients and showed increased uric acid should be separated from kidney disorders (20). However, Zhao et al associated increased uric acid in women with preeclampsia with the systemic inflammation of maternal blood vessels, which could be presented by increased Tumor necrosis factor alpha TNF-alpha and Intercellular adhesion molecule- 1 (21). Matias et al as also expressed the increased uric acid by inflammatory reactions, and this phenomenon was associated with that expression of nod-like intracellular receptors with a pyrin domain NLRP3 gene in pregnant women with preeclampsia (22).
Previous studies showed a significant association between hyperuricemia and adverse obstetric outcomes in pregnant women with hypertension (23, 24) which was similar to the current study. As in this study higher mean level of uric acid was associated with increased rate of PTL and consequently NICU hospitalization. In a study by James et al results showed that women with hypertension and hyperuricemia had a similar or higher risk comparing women with high blood pressure and proteinuria. Risks included a shorter period of pregnancy, lower percentiles of birth weight, increased risk of preterm birth and SGA. They concluded that hyperuricemia was at least as effective as proteinuria to identify pregnancies with the risk of high blood pressure (25).
In this study, although uric acid levels in women who were hospitalized in the NICU was higher than non-hospitalized women, this association was not significant. While Andrews et al which assessed Indian patients with high blood pressure for two years showed that the rate of maternal death in those with increased uric acid levels, LDL, AST, alanine aminotransferase, APTT was higher than the control group (26). In the present study, although the incidence of neonatal complications such as intrauterine fetal death, low Apgar score and SGA in preeclamptic women was slightly higher than the control group, this relation was not significant. While Patel et al which compared levels of uric acid (<6 and ≥6) in women with high blood pressure Indicated hyperuricemia in patients with high blood pressure as a risk factor for several serious maternal and perinatal complications such as <7 Apgar score, intrauterine death, eclampsia, and cesarean delivery in patients with ≥6 level of uric acid versus <6 (27).
Results showed that by 1 mg/dl increase in serum uric acid and hematocrit in pregnant women with preeclampsia, 1.7 and 1.3 folds increases in the risk of hepatic dysfunction were noted, respectively. In addition, by 1 mg/dl increase in serum uric acid and hemoglobin, 1.5 and 1.6 fold increases in the risk of hepatic dysfunction were noted, respectively. In a study by Hawkins et al, with increasing levels of uric acid, the risk of kidney failure which could be diagnosed by the increased level of creatinin in the mothers was four times higher compared with the control group (17).
In the present study by 1 mg/dl increase in serum hemoglobin and creatinine, 1.6 and 1.06 fold increases in the risk of PTL was noted, respectively. While other variables did not increase or decrease the chance of PTL in pregnant women with preeclampsia. Also, the level of uric acid had no effect on neonatal hospitalization in NICU. However, by 1 mg/dl increase in hemoglobin and AST in pregnant women with preeclampsia, 1.6 and 1.022 fold increases in the risk of neonatal hospitalization in NICU were noted, respectively.
The positive history of hypertension before pregnancy indicated 3.8 fold increase in neonatal hospitalization in NICU. Livingston et al stated that level of uric acid was associated with prenatal and maternal complications in women with preeclampsia (3). Wu et al also declared that with one increase in standard deviation of serum uric acid, 1.5 fold increases in the chance of maternal and fetal complications were noted (28). In this study, uric acid was higher in severe preeclampsia and PTL. Whereas in severe preeclampsia, clinicians ought to terminate the pregnancy to save the patient’s life, the higher rate of PTL would be expected.
Conclusion
In this study, we found a significant relationship between the level of uric acid with hepatic dysfunction and PTL in pregnant women with preeclampsia. As assessing serum uric acid in the laboratory can be easily performed, it seems that it might be diagnostic and prognostic criteria for determining the early complications of preeclampsia and can be used to treat and manage women with preeclampsia.
Acknowledgments
Financial support was done with Vice-chancellorships Research of Guilan University of Medical Sciences, Guilan, Iran.
Conflict of interest
The authors declare that they have no conflicts of interest.
Preeclampsia with the prevalence of 10.5% is a blood pressure disorder. It is a multi-systemic disease with unknown etiology. It is indicated by >140/90 mm Hg blood pressure with or without proteinuria after 20 wk of gestation. Hypertension during pregnancy is associated with maternal and neonatal complications (1, 2). In developed countries, 16% of maternal deaths are caused by high blood pressure which is higher than other factors such as bleeding (13%), abortion (8%) and sepsis (2%) (3). In Iran, the prevalence of hypertensive disorders during pregnancy is reported as 8.1% (4, 5). Up to now, there is no reliable, valid, and cost-effective screening test for the early detection of preeclampsia. It seems that measuring the blood level of uric acid is one of the available and cheap screening tests that have already been taken into account. Uric acid is the final product of purine metabolism oxidation which is mainly excreted in the urine. Since increased uric acid is the first and earliest laboratory presentation of preeclampsia as a result of reduced clearance of uric acid due to decreased glomerular filtration clearance, increased tubular reabsorption, and reduced secretion, some investigators use serum uric acid as a criterion for preeclampsia (3).It has been indicated that uric acid might not only have a predictive role in preeclampsia but also play a significant role in the maternal and fetal pathogenesis and presentations (3). However, previous studies mentioned inconsistent results (6, 7). Some previous investigations mentioned a higher level of uric acid in patients with preeclampsia compared to healthy subjects (8, 9). However, other studies mentioned that changes in uric acid levels in preeclampsia might be as a result of associated diseases. They noted no important predictive value for uric acid (10, 11). Also, epidemiological studies on non-pregnant individuals showed that hyperuremia could be associated with hypertension, metabolic syndrome, coronary artery disease, cardiovascular disease and chronic kidney disease (12, 13).
Given the importance of preeclampsia in maternal and neonatal complications, in this study, we aimed to investigate the relationship between the level of uric acid with maternal and neonatal complications in women with preeclampsia. Knowing the effect of uric acid on the severity of preeclampsia and maternal and neonatal complications can help early diagnosis, control, and treatment. Results can be used for clinical decision-making and prevent from maternal and neonatal complications.
Materials and methods
In this cross-sectional study, 160 preeclamptic women (severe and nonsevere) at more than 28 weeks gestational age admitted to Al-Zahra Hospital in Rasht, Iran during 2014-2015 were included. Diagnostic criteria were having hypertension to the extent of 140/90 mmgHg or more after 20 wk of pregnancy in women with or without proteinuria in previously normotensive. Also, hypertension in pregnant women with a history of preeclampsia was noted by >30 mm Hg increase in systolic blood pressure or >15 mmHg increase in diastolic blood pressure. Severe preeclampsia was diagnosed when systolic pressure ≥160 mmHg, diastolic pressure ≥110 mmHg with or without proteinuria, headache, visual changes, upper abdominal pain, oliguria, increased serum creatinine and liver transaminases and thrombocytopenia (<100,000).
Measurement of blood pressure was performed by a single resident of obstetrics and gynecology. All pregnant women with smoking, diabetes or gestational diabetes, hemoglobinopathies, nephropathy, acute and chronic renal failure, glomerulopathy, urinary tract infection, hepatic dysfunction, gout, hypothyroidism or hyperthyroidism, fetal and placental malformations, and multiple pregnancies were excluded.
Of all women who met the inclusion criteria, 5 ml of blood from an anterior Cubital vein was taken and hemoglobin, hematocrit, platelet count, and liver and uric acid tests were assessed. For all women, 24-hr urine protein, creatinine, urine dipstick tests, and random urine samples were also performed. Uric acid was assessed using Pars test kit and by BT2000 (Italy) auto-analyzer system. All laboratory tests were conducted in Al-Zahra hospital.
Data including age, gravidity, parity, gestational age, and history of hypertension before pregnancy were collected through interviews. Weight and height were measured and body mass index (BMI) was calculated. Maternal complications included severity of preeclampsia, placental abruption, preterm labor (PTL), thrombocytopenia, elevated alanine aminotransferase (ALT) and aspartate aminotransferase (AST), HELLP syndrome (Hemolysis, Elevated Liver enzymes, and Low Platelet count), eclampsia and required hospitalization in the ICU were assessed. Neonatal complications including small for gestational age (SGA), intrauterine fetal death, hospitalization in the neonatal intensive care unit, and Apgar score <7 at five minutes were investigated.
Ethical consideration
This study was approved by the Ethics Committee of Guilan University of Medical Sciences (1930596730). Written informed consents were obtained from all participants before enrollment.
Statistical analysis
Data were analyzed using Statistical Package for the Social Sciences (version 21.0, SPSS Inc, Chicago, and Illinios, USA). Independent samples t-test was used to compare means between groups. Also, univariate logistic regression analysis using forward: LR method was used to assess the relationship between levels of uric acid and the incidence of maternal and neonatal complications. In the regression analysis, the effect of uric acid levels, age, gestational age, gravidity, parity, the platelet count, albuminuria, hemoglobin, hematocrit, creatinine, body mass index, and effect of hypertension before pregnancy on maternal and neonatal complications were examined. The p<0.05 indicated statistical significance and 95% confidence interval was noted.
Results
In this study, 160 preeclamptic women participated, which 38 of them were severe preeclampsia (23.8%) and 122 of them were none severe (76.3%). The mean age of participants was 31.18±5.41 yr. 14.4% (n=23) had a history of hypertension before pregnancy and 71.3% (114) had albuminuria. Demographic characteristics and laboratory results have been reported in table I. Mean level of uric acid in women with severe pre- eclampsia (5.66±1.46) was significantly higher than non-severe preeclampsia (5.12±1.29) (p=0.031). In univariate analysis, the mean level of uric acid in women with hepatic dysfunction was significantly higher than the non hepatic dysfunction group (p=0.009). Also, women with preterm delivery had higher uric acid levels than women with normal term pregnancy (p=0.0001). Uric acid levels in women with neonates hospitalized in Neonate invasive care unit (NICU) were significantly higher than other women (p=0.016). In the case of maternal and neonatal complications, there was no significant difference between groups regarding the level of uric acid (Table II).
Based on the logistic regression analysis, 1 mg/dl increase in blood uric acid level induced 1.74 fold increase in the risk of hepatic dysfunction (OR: 1.74, 95% CI: 1.12-2.72). Also, with 1% increase in hematocrit, the chance of hepatic dysfunction will be about 1.3 times higher. Other variables had no effect on increasing or decreasing the risk of hepatic dysfunction in pregnant women with preeclampsia. In the present study by 1 mg/dl, increase in serum uric acid, 1.54 fold increase in the risk of PTL was noted (OR: 1.54, 95% CI: 1.15-2 ). Furthermore, by 1 mg/dl increase in serum hemoglobin and creatinin, 1.6 and 1.06 fold increase in the risk of PTL was noted, respectively. While other variables did not increase or decrease the chance of PTL in pregnant women with preeclampsia.
Based on regression analysis, results showed that the level of uric acid had no effect on hospitalization of infants in the NICU. Also, the level of uric acid had no effect on neonatal hospitalization in NICU. However, by 1 mg/dl increase in hemoglobin and AST in pregnant women with preeclampsia, 1.6 and 1.022 fold increase in the risk of hospitalization in NICU was noted, respectively. The positive history of hypertension before pregnancy indicated 3.8 fold increase in hospitalization in NICU. (Table III).
Table I. Demographic characteristics and laboratory results of the study participants
Table II. Univariate analysis of pregnancy outcomes in study participants
Table III. Logistic regression analysis on the factors affecting the incidence of hepatic dysfunction, premature birth, and NICU hospitalization in women with preeclampsia
Discussion
In this study, the mean level of uric acid in women with severe preeclampsia was significantly higher than non-severe preeclampsia. In a study by Sultana and colleagues, which compared the mean levels of uric acid in subjects with normal blood pressure and preeclampsia, results showed that preeclampsia was associated with hyperuricemia (14). Also, Gianni et al followed patients for a month after delivery and mentioned uric acid as a reliable predictor of preeclampsia in women with gestational hypertension. They indicated uric acid with cut-off of 309 µm/l as a predictor of preeclampsia (8).
Enaruna et al also showed that uric acid levels in women with severe pre-eclampsia were higher than the control group (11). Chen and co-workers showed a higher level of serum uric acid in women with preeclampsia and the increase occurred with the onset of preeclampsia. There was no significant difference between preeclampsia and normal subjects regarding the mean level of uric acid in the first and second trimesters. Chen et al stated that serum uric acid levels increased with the onset of clinical signs of preeclampsia, but it might not be a predictor of preeclampsia and should not be considered as a predictive biomarker (15). According to results, although preeclampsia might cause an increase in uric acid, the inverse association did not exist. Laughon et al mentioned that the increase of uric acid in the first trimester of pregnancy was associated with preeclampsia and hypertension during pregnancy was related to hyperuricemia (16).
Hawkins et al reported that hyperuricemia in pregnant women with high blood pressure was an important finding which might expose women to adverse maternal and fetal complications. Even women with gestational hypertension, without other signs of pre-eclampsia had adverse embryonic complications such as SGA and pre-maturity. In this study, uric acid was measured near-term period which was similar to ours (17).
Elmas et al showed higher levels of uric acid, xanthine oxidase and Allantoin activity and blood pressure in patients with preeclampsia versus the control group (18). Elmas et al suggested that increased uric acid, xanthine oxidase and Allantoin activity might be noted following the death of placental cells consequent the abnormal activity of trophoblast in preeclampsia. Therefore, currently, clinicians prefer the mentioned causes for increased uric acid in preeclampsia instead of the effect of kidney disease following preeclampsia (19).
Corominas et al showed that up to 20 weeks of gestation, the mean level of uric acid in preeclampsia and normal women were similar. But after 20th wk of gestation, the mean level of uric acid in women with preeclampsia was 1.5 fold higher than control and healthy subjects. This increase coincided with stable creatinin and urea in patients and showed increased uric acid should be separated from kidney disorders (20). However, Zhao et al associated increased uric acid in women with preeclampsia with the systemic inflammation of maternal blood vessels, which could be presented by increased Tumor necrosis factor alpha TNF-alpha and Intercellular adhesion molecule- 1 (21). Matias et al as also expressed the increased uric acid by inflammatory reactions, and this phenomenon was associated with that expression of nod-like intracellular receptors with a pyrin domain NLRP3 gene in pregnant women with preeclampsia (22).
Previous studies showed a significant association between hyperuricemia and adverse obstetric outcomes in pregnant women with hypertension (23, 24) which was similar to the current study. As in this study higher mean level of uric acid was associated with increased rate of PTL and consequently NICU hospitalization. In a study by James et al results showed that women with hypertension and hyperuricemia had a similar or higher risk comparing women with high blood pressure and proteinuria. Risks included a shorter period of pregnancy, lower percentiles of birth weight, increased risk of preterm birth and SGA. They concluded that hyperuricemia was at least as effective as proteinuria to identify pregnancies with the risk of high blood pressure (25).
In this study, although uric acid levels in women who were hospitalized in the NICU was higher than non-hospitalized women, this association was not significant. While Andrews et al which assessed Indian patients with high blood pressure for two years showed that the rate of maternal death in those with increased uric acid levels, LDL, AST, alanine aminotransferase, APTT was higher than the control group (26). In the present study, although the incidence of neonatal complications such as intrauterine fetal death, low Apgar score and SGA in preeclamptic women was slightly higher than the control group, this relation was not significant. While Patel et al which compared levels of uric acid (<6 and ≥6) in women with high blood pressure Indicated hyperuricemia in patients with high blood pressure as a risk factor for several serious maternal and perinatal complications such as <7 Apgar score, intrauterine death, eclampsia, and cesarean delivery in patients with ≥6 level of uric acid versus <6 (27).
Results showed that by 1 mg/dl increase in serum uric acid and hematocrit in pregnant women with preeclampsia, 1.7 and 1.3 folds increases in the risk of hepatic dysfunction were noted, respectively. In addition, by 1 mg/dl increase in serum uric acid and hemoglobin, 1.5 and 1.6 fold increases in the risk of hepatic dysfunction were noted, respectively. In a study by Hawkins et al, with increasing levels of uric acid, the risk of kidney failure which could be diagnosed by the increased level of creatinin in the mothers was four times higher compared with the control group (17).
In the present study by 1 mg/dl increase in serum hemoglobin and creatinine, 1.6 and 1.06 fold increases in the risk of PTL was noted, respectively. While other variables did not increase or decrease the chance of PTL in pregnant women with preeclampsia. Also, the level of uric acid had no effect on neonatal hospitalization in NICU. However, by 1 mg/dl increase in hemoglobin and AST in pregnant women with preeclampsia, 1.6 and 1.022 fold increases in the risk of neonatal hospitalization in NICU were noted, respectively.
The positive history of hypertension before pregnancy indicated 3.8 fold increase in neonatal hospitalization in NICU. Livingston et al stated that level of uric acid was associated with prenatal and maternal complications in women with preeclampsia (3). Wu et al also declared that with one increase in standard deviation of serum uric acid, 1.5 fold increases in the chance of maternal and fetal complications were noted (28). In this study, uric acid was higher in severe preeclampsia and PTL. Whereas in severe preeclampsia, clinicians ought to terminate the pregnancy to save the patient’s life, the higher rate of PTL would be expected.
Conclusion
In this study, we found a significant relationship between the level of uric acid with hepatic dysfunction and PTL in pregnant women with preeclampsia. As assessing serum uric acid in the laboratory can be easily performed, it seems that it might be diagnostic and prognostic criteria for determining the early complications of preeclampsia and can be used to treat and manage women with preeclampsia.
Acknowledgments
Financial support was done with Vice-chancellorships Research of Guilan University of Medical Sciences, Guilan, Iran.
Conflict of interest
The authors declare that they have no conflicts of interest.
Type of Study: Original Article |
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12. Feig DI, Kang DH, Johnson RJ. Uric acid and cardiovascular risk. N Engl J Med 2008; 23: 1811-1821. [DOI:10.1056/NEJMra0800885]
13. Powers RW, Ness RB, Cooper KM, Gallaher MJ, Frank MP, Daftary AR, Roberts JM. Uric acid concentrations in early pregnancy among preeclamptic women with gestational hyperuricemia at delivery. AJOG 2006; 194: . [DOI:10.1016/j.ajog.2005.06.066]
14. Sultana R AS, Sultana N, Karim S.M. F, Atia F. Association of Serum Uric Acid with Preeclampsia: A Case Control Study. Delta Med Col J 2013; 1: 46-50. [DOI:10.3329/dmcj.v1i2.15918]
15. Chen Q LS, Tong M, Wei J, Shen F, Zhao J, Zhao M. Serum uric acid may not be involved in the development of preeclampsia. J Hum Hypertens 2016; 30: 136-140. [DOI:10.1038/jhh.2015.47]
16. Laughon SK, Catov J, Powers RW, Roberts JM, Gandley RE. First trimester uric acid and adverse pregnancy outcomes. Am J Hypertens 2011; 24: 489-495. [DOI:10.1038/ajh.2010.262]
17. Hawkins TL, Roberts JM, Mangos GJ, Davis GK, Roberts LM, Brown MA. Plasma uric acid remains a marker of poor outcome in hypertensive pregnancy: a retrospective cohort study. BJOG 2012; 119: 484-492. [DOI:10.1111/j.1471-0528.2011.03232.x]
18. Elmas O AY, Simsek T. The relationship between hypertension and plasma allantoin, uric acid, xanthine oxidase activity and nitrite, and their predictive capacity in severe preeclampsia. J Obstet Gynaecol 2016; 36: 34-38. [DOI:10.3109/01443615.2015.1030608]
19. Masoura S, Makedou K, Theodoridis T, Kourtis A, Zepiridis L, Athanasiadis A. The involvement of uric acid in the pathogenesis of preeclampsia. Curr Hypertens Rev 2015; 11: 110-115. [DOI:10.2174/1573402111666150529130703]
20. Corominas AI, Balconi SM, Palermo M, Maskin B, Damiano AE. Serum uric acid levels and risk of developing preeclampsia. Medicina 2014; 74: 462-471.
21. Zhao J ZD, Yang JM, Wang M, Zhang XT, Sun L, Yun XG. Maternal serum uric acid concentration is associated with the expression of tumour necrosis factor-alpha and intercellular adhesion molecule-1 in patients with preeclampsia. J Hum Hypertens 2016; 30: 456-462. [DOI:10.1038/jhh.2015.110]
22. Matias ML, Romao M, Weel IC, Ribeiro VR, Nunes PR, Borges VT, et al. Endogenous and Uric Acid-Induced Activation of NLRP3 Inflammasome in Pregnant Women with Preeclampsia. PloS One 2015; 10: e0129095. [DOI:10.1371/journal.pone.0129095]
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38. Martin AC BM. Could uric acid have a pathogenic role in pre-eclampsia? Nat Rev Nephrol 2010; 6: 744-748. [DOI:10.1038/nrneph.2010.125]
39. Enaruna NO, Idemudia JO, Aikoriogie PI. Serum lipid profile and uric acid levels in preeclampsia in University of Benin Teaching Hospital. Niger Med J 2014; 55: 423-427. [DOI:10.4103/0300-1652.140387]
40. Feig DI, Kang DH, Johnson RJ. Uric acid and cardiovascular risk. N Engl J Med 2008; 23: 1811-1821. [DOI:10.1056/NEJMra0800885]
41. Powers RW, Ness RB, Cooper KM, Gallaher MJ, Frank MP, Daftary AR, Roberts JM. Uric acid concentrations in early pregnancy among preeclamptic women with gestational hyperuricemia at delivery. AJOG 2006; 194: . [DOI:10.1016/j.ajog.2005.06.066]
42. Sultana R AS, Sultana N, Karim S.M. F, Atia F. Association of Serum Uric Acid with Preeclampsia: A Case Control Study. Delta Med Col J 2013; 1: 46-50. [DOI:10.3329/dmcj.v1i2.15918]
43. Chen Q LS, Tong M, Wei J, Shen F, Zhao J, Zhao M. Serum uric acid may not be involved in the development of preeclampsia. J Hum Hypertens 2016; 30: 136-140. [DOI:10.1038/jhh.2015.47]
44. Laughon SK, Catov J, Powers RW, Roberts JM, Gandley RE. First trimester uric acid and adverse pregnancy outcomes. Am J Hypertens 2011; 24: 489-495. [DOI:10.1038/ajh.2010.262]
45. Hawkins TL, Roberts JM, Mangos GJ, Davis GK, Roberts LM, Brown MA. Plasma uric acid remains a marker of poor outcome in hypertensive pregnancy: a retrospective cohort study. BJOG 2012; 119: 484-492. [DOI:10.1111/j.1471-0528.2011.03232.x]
46. Elmas O AY, Simsek T. The relationship between hypertension and plasma allantoin, uric acid, xanthine oxidase activity and nitrite, and their predictive capacity in severe preeclampsia. J Obstet Gynaecol 2016; 36: 34-38. [DOI:10.3109/01443615.2015.1030608]
47. Masoura S, Makedou K, Theodoridis T, Kourtis A, Zepiridis L, Athanasiadis A. The involvement of uric acid in the pathogenesis of preeclampsia. Curr Hypertens Rev 2015; 11: 110-115. [DOI:10.2174/1573402111666150529130703]
48. Corominas AI, Balconi SM, Palermo M, Maskin B, Damiano AE. Serum uric acid levels and risk of developing preeclampsia. Medicina 2014; 74: 462-471.
49. Zhao J ZD, Yang JM, Wang M, Zhang XT, Sun L, Yun XG. Maternal serum uric acid concentration is associated with the expression of tumour necrosis factor-alpha and intercellular adhesion molecule-1 in patients with preeclampsia. J Hum Hypertens 2016; 30: 456-462. [DOI:10.1038/jhh.2015.110]
50. Matias ML, Romao M, Weel IC, Ribeiro VR, Nunes PR, Borges VT, et al. Endogenous and Uric Acid-Induced Activation of NLRP3 Inflammasome in Pregnant Women with Preeclampsia. PloS One 2015; 10: e0129095. [DOI:10.1371/journal.pone.0129095]
51. Thangaratinam S, Ismail KM, Sharp S, Coomarasamy A, Khan KS, Tests in Prediction of Pre-eclampsia Severity review g. Accuracy of serum uric acid in predicting complications of pre-eclampsia: a systematic review. BJOG 2006; 113: 369-378. [DOI:10.1111/j.1471-0528.2006.00908.x]
52. Koopmans CM vPM, Groen H, Aarnoudse JG, van den Berg PP, Mol BW. Accuracy of serum uric acid as a predictive test for maternal complications in pre-eclampsia: bivariate meta-analysis and decision analysis. Eur J Obstet Gynecol Reprod Biol 2009; 146: 8-14. [DOI:10.1016/j.ejogrb.2009.05.014]
53. Roberts JM BL, Lain KY, Hubel CA, Markovic N, Ness RB, Powers RW. Uric acid is as important as proteinuria in identifying fetal risk in women with gestational hypertension. Hypertension 2005; 46: 1263-1269. [DOI:10.1161/01.HYP.0000188703.27002.14]
54. Andrews L ML, Sharma A, Haridas N, Vaishnav S, Jadav P. Maternal outcome in relation to Biochemical parameters in Hypertensive disorders in Pregnancy. IOSR J Dental Med Sci 2014; 13: 18-22.
55. Patel Tejal DA. R elationship of Serum Uric Acid Level to Maternal and Perinatal Outcome in Patients with Hypertensive Disorders of Pregnancy. GUJARAT MED J 2014; 69: 45-47.
56. Wu Y, Xiong X, Fraser WD, Luo ZC. Association of uric acid with progression to preeclampsia and development of adverse conditions in gestational hypertensive pregnancies. Am J Hypertens 2012; 25:711-717. [DOI:10.1038/ajh.2012.18]
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