ULTRASOUND MASS SCREENING OF NEONATES WITH CONGENITAL ANOMALIES OF THE KIDNEY AND URINARY TRACT (CAKUT)

Document Type : Original Article

Authors

1 Departments of Pediatrics, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

2 Departments of Diagnostic Radiology, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

Abstract

Background: Congenital anomalies of kidney and urinary tract represent the most common cause of end stage kidney disease in infant and children. Early detection of these changes allows timely initiation of more specific diagnostic studies, and of therapeutic interventions.
Objective: This study was done to detect the incidence and risk factors of (CAKUT) in neonate.
Patients and methods: This study was carried out on 390 neonates in the incubator of Al-Matariya Teaching Hospital and Al-Hussein University Hospital during the period from July 2014 to July 2015.All neonates were included except those with apparent congenital anomalies, surgical emergency orinborn errors of metabolism. All neonates after parent consents were subjected to full history, clinical examination and investigated by pelvi-abdominal ultrasound, serum creatinine level, and some cases subjected to more investigations in the form of computed tomography scan with intravenous urographin contrast medium, ascending cystourethrography and TC 99m DTPA dynamic renal scan.                                         
Results: The overall incidence of congenital anomalies of kidney and urinary tract was 3.3%. Positive family history of renal anomalies together with maternal history of diabetes mellitus and maternal age above 35 years were considered predictors for renal anomalies by binary logistic regression.
Conclusion: Congenital anomalies of kidney and urinary tract (CAKUT) were major health issues and were the leading cause of ESRD in pediatric population.

Keywords


ULTRASOUND MASS SCREENING OF NEONATES WITH CONGENITAL ANOMALIES OF THE KIDNEY AND URINARY TRACT (CAKUT)

 

By

 

Moftah M. Rabeea, Ibrahim A. Al Qshlan, Susan E. Eltahlawy­

and Mohammad M. Shaarawy

                                                                                                              

Departments of Pediatrics and Diagnostic Radiology,
Faculty of Medicine, Al-Azhar University, Cairo, Egypt

 

ABSTRACT

Background: Congenital anomalies of kidney and urinary tract represent the most common cause of end stage kidney disease in infant and children. Early detection of these changes allows timely initiation of more specific diagnostic studies, and of therapeutic interventions.

Objective: This study was done to detect the incidence and risk factors of (CAKUT) in neonate.

Patients and methods: This study was carried out on 390 neonates in the incubator of Al-Matariya Teaching Hospital and Al-Hussein University Hospital during the period from July 2014 to July 2015.All neonates were included except those with apparent congenital anomalies, surgical emergency orinborn errors of metabolism. All neonates after parent consents were subjected to full history, clinical examination and investigated by pelvi-abdominal ultrasound, serum creatinine level, and some cases subjected to more investigations in the form of computed tomography scan with intravenous urographin contrast medium, ascending cystourethrography and TC 99m DTPA dynamic renal scan.                                         

Results: The overall incidence of congenital anomalies of kidney and urinary tract was 3.3%. Positive family history of renal anomalies together with maternal history of diabetes mellitus and maternal age above 35 years were considered predictors for renal anomalies by binary logistic regression.

Conclusion: Congenital anomalies of kidney and urinary tract (CAKUT) were major health issues and were the leading cause of ESRD in pediatric population.

Key words: Ultrasound, neonates, CAKUT.

 

 

INTRODUCTION

   Congenital anomalies of kidney and urinary tract (CAKUT) comprise a spectrum of malformations that occur at the level of the kidney as hypoplasia and dysplasia, collecting system as hydronephrosis and megaureter, bladder as ureterocele and vesicoureteral reflux, or urethra as posterior urethral valves(Song and Yosypiv, 2011).

   Cases of CAKUT were detected in3.7 % of kidneys in one ultrasound examination at the following points of time at least: (i) prenatally in 18.2 % of newborns (ii) 3 - 7 days postnatally in 65.2 % and (iii) 17 %during the 6-month follow-up (Richter et al., 2012).

    The main etiologic factor of chronic kidney disease in children is represented by CAKUT(Harambat et al.,2012).

    Genetic as well as environmental factors that are present before or during pregnancy are presumed to be involved in deficient kidney development (Schwaderer et al., 2007) 

  Every child who suffers from CAKUT was born with a different set of nephrons. Our duty as pediatricians is to preserve as long as possible the function, avoiding a worse dysplasia caused by obstruction and recurrent UTIs(Rodriguez, 2014).

  Practical criteria for surgical intervention in CAKUT are recurrent UTIs, especially in children under 1 year of age, children with VUR of high bilateral grade, worsening hydronephrosis > 3 cm or with noticeable changing during the follow-up, bilateral dilation and pain symptoms. Surgical correction involves preferably endoscopic, laparoscopic and robotic approach(Arlen and Cooper, 2015).

  The aim of this work was to detect the incidence and risk factors of CAKUT.

PATIENTS AND METHODS

    This study was carried out on 390 neonates in the incubator of Al- Matariya Teaching Hospital and Al-Hussein University Hospital during the period from July 2014 to July 2015.

Inclusion criteria: All neonates (preterm and term) of  both genders (male and female) from 3 days to 30 days.

Exclusion criteria:1- Apparent congenital anomalies. 2- Inborn errors of metabolism 3-Neonates with surgical emergencies.

    After parent consents, all those neonates were subjected to full history, clinical examination, serum creatinine level and pelvi-abdominal ultrasound for congenital anomalies of kidney and urinary tract. By using Simens–Adara ultrasound machine – Japan, we measured the kidneys as regard length, width, thickness, corticomedullarydifferentiation. Also, detection of any urinary tract abnormalities and renal pelvic measure-ment were included.

    Selected cases were subjected to further investigations in the form of:

- Computed tomography (CT) scan with intravenous urographin contrast medium, after skin sensitivity test.

- TC 99m DTPA dynamic renal scan.

- Ascending cystourethrography.

Statistical methodology: Analysis of data was done by IBM computer using SPSS (statistical program for social science version 16) as follows:

● Description of quantitative variables as mean, SD and range.

● Description of qualitative variables as number and percentage.

● Unpaired t-test was used to compare two groups as regard quantitative variables.

● Chi-square test was used to compare two groups as regard qualitative variables.

● Fisher exact test was used instead of chi-square when one expected cell less than or equal 5.

    Binary logistic regression was used for detection of independent predictors by using enter technique.

P<0.05 was significant.

RESULTS

    Statistical analysis of the demographic data of the studied cases showed that the male gender was more than female.Gestational age was between 37-42 weeks, and maternal ages of studied cases were in the age group 20-35 years, with more cases delivered by cesarean section. The body weight of studied cases was in the category of 2.5-3.99 kg. There was an irrelevant prenatal history (Table 1).

 

 

Table (1): Statistical analysis of the demographic data of the studied cases

Count

Variables

No.

%

1) Gender

Males

females

 

218

172

 

56%

44%

2) Gestational age (weeks)

<28

29-32

33-36

37-42

 

16

58

128

188

 

4.1%

14.9%

32.8%

48.2%

3) Post natal age (days)

3-7

8-30

 

247

143

 

63.3%

36.7%

4) Maternal age (years)

Less than 20

20-35

More than 35

 

24

290

76

 

6.1%

74.4%

19.5%

5) Mode of delivery

Vaginal

Cesarean section

 

130

260

 

33.3%

66.7%

6) Body weight (kg)

<1

1-1.49

1.5-2.49

2.5-3.99

>4

 

15

53

114

205

3

 

3.8%

13.6%

29.2%

52.6%

0.8%

7) Prenatal history

Consanguinity

Medical history

Irrelevant

Diabetes mellitus

Hypertension

Rheumatic heart

Epilepsy

Asthma

 

65

 

334

21

20

7

3

5

 

16.6%

 

85.6%

5.4%

5.1%

1.8%

0.8%

1.3%

 

 

Pelvi-abdominal ultrasound of  the studied cases showed that the overall incidence of congenital anomalies of kidney and urinary tract was 3.3% (Table 2).


 

Table (2): Pelvi-abdominal ultrasound of the studied cases

Count

 

Ultrasound

Number

Percent

Normal

377

96.7%

Abnormal

13

3.3%

 

 

    Distribution of different types of congenital anomalies of kidney and urinary tract among abnormal cases showed that mild hydronephrosis was considered the most frequent congenital anomaly of UT among the studied cases (Table 3).


 

 

Table (3): Distribution of different types of congenital anomalies of kidney and urinary tract

Count

Variables

No.

%

Mild hydronephrosis

5

38.4%

Moderate hydronephrosis

2

15.4%

Severe hydronephrosis

1

7.7%

Polycystic kidney

1

7.7%

Nephrocalcinosis

2

15.4%

Hypoplasia                 

1

7.7%

Renal agenesis and compensatory hypertrophy

1

7.7%

Total

13

100%

 

 

 

 

A  B

Figure (1): Ultrasound examination showed bilateral mild hydronephrosis, renal pelvic diameter of rt. Kidney was 10.5 mm and of lt. kidney was 92 mm (A). Follow up of the ultrasound one month later showed normal kidney and the case diagnosed as transient hydronephrosis (B).

 

 

 

 

A

B

Figure (2): Ultrasound examination showed moderate hydronephrosis with dilatation of pelvicalyceal system(A). Follow up of the ultrasound 3 months later showed normal kidney and the case diagnosed as transient hydronephrosis (B).

 

 

 

 

 

      A

B

Figure (3): Ultrasound examination showed bilateral moderate hydronephrosis and enlarged filled bladder (LK: left kidney, RK: right kidney, U: ureter B bladder, L: liver) (A). The case underwent at 1 month old an ascending cystourethrography showed that there was a congenital posterior urethral valve (B).

 

 

AB

Figure (4): Ultrasound examination showed severe left hydronephrosis with dilatation of pelvicalyceal system and loss of corticomedullary differentiation (A). 3 months later, the case underwent computed tomography (CT) scan with intravenous urographin contrast medium showed that there is pelvi-ureteric junction obstruction (B).

 

A B

Figure (5): Ultrasound examination showed left enlarged polycystic kidney with marked thinning out of parenchyma (A). The case was subjected to TC 99m DTPA dynamic renal scan showed compensated overall renal function with markedly diminished left renal function (B).

 

 

 

A

 

 

B

Figure (6): Ultrasound examination showed bilateral nephrocalcinosis of two cases (A) and (B).

 

 

 

 

 

 

Figure (7): Ultrasound examination showed bilateral renal hypoplasia with longitudinal diameter of left kidney 25mm, and longitudinal diameter of right kidney 32mm.

 

 

 

Figure (8): Ultrasound examination showed left renal agenesis with compensatory right renal hypertrophy.

 

 

    Comparison between abnormal cases and normal neonates in relation to demographic data showed that there was no significant difference between both groups by using chi-square test and no significant relation to other variables (Table 4).


 

 

Table (4): Comparison between abnormal cases and normal neonates in relation to demographic data.

Count

 

 

Variables

Urological congenital anomaly

No                               Yes

P

Gestational age (weeks)

<28

29-32

33-36

37-42

 

19(5%)

56(14.9%)

123(32.6%)

179(47.5%)

 

1(7.7%)

2(15.4%)

1(7.7%)

9(69.2%)

0.27

Body weight (kg)

<1

1-1.49

1.5-2.49

2.5-3.99

>4

 

15(4%)

52(13.8%)

111(29.4%)

196(52%)

3(0.8%)

 

0

1(7.7%)

3(23.1%)

9(69.2%)

0

0.76

Post natal age (days)

<7

8-30

 

239(63.4%)

138(36.6%)

 

8(61.5%)

5(38.5%)

0.77

Maternal age (years)

Less than 20

20-35

More than 35

 

24(6.4%)

280(74.3%)

73(19.4%)

 

0

10(76.9%)

3(23.1%)

0.63

 

 

 

Comparison between abnormal cases and normal neonates in relation to mode of delivery showed that majority of cases with congenital anomaly group delivered vaginally with significant difference by using chi-square test, and no significant relation to other variables. Comparison between abnormal cases and normal neonates in relation to prenatal history showed that no statistically significant difference between both groups by using chi-square test. Comparison between abnormal cases and normal neonates in relation to family history of CAKUT showed that frequency of positive family history was more among positive group with statistically significant difference by using  Fisher exact test. Comparison between abnormal cases and normal neonates in relation to serum creatinine level showed that positive group had higher creatinine level compared to negative with significant difference  by using unpaired t-test (Table 5).


 

Table (5): Comparison between abnormal cases and normal neonates in relation to prenatal history, family history, mode of delivery and serum creatinine level.

Count

 

Variables

Urological congenital anomaly

No                               Yes

P

Mode of delivery

Vaginal

CS

 

122(32.6%)

255(67.4%)

 

8(61.5%)

5(38.5%)

0.04

Prenatal history

Consanguinity

Irrelevant

DM

HTN

RH

Epilepsy

Asthma

 

65(98.4%)

316(97.5%)

18(75.7%)

19(95%)

7(100%)

3(100%)

5(100%)

 

1(1.6%)

8(2.5%)

3(14.3%)

1(5%)

0

0

0

6.02

 

Family history of CAKUT

No

Yes

 

374(99.2%)

3(0.8%)

 

11(84.6%)

2(15.4%)

 

0.001

 

serum creatinine level                         Mean +SD

n = 377

0.46+0.07

N =13

0.69+0.3

0.001

 

 

 

    Comparison between abnormal cases and normal neonates in relation to different risk factors showed that Positive family history of renal anomalies together with family history of  DM and maternal age above 35 were considered predictors for renal anomalies by binary logistic regression (Table 6).


 

 

Table (6): Comparison between abnormal cases and normal neonates in relation to different risk factors.

Variables

P

Odd’s (95%CI)

Family history of renal congenital anomalies (+ve)

0.04

1.1(-0.4-16)

Mode of delivery (vaginal)

0.12

0.9(0.02-11)

Maternal history of DM

0.08

1.09(0.2-13.6)

Maternal age >35yrs

0.09

0.8(-0.3-12)

CI= Confidence interval

 

 

Prognosis of abnormal cases detected by ultrasound showed that the majority of abnormal cases had good prognosis, and only 24% for surgical intervention (Table7).


Table (7):Prognosis of abnormal cases.

Number

Prognosis

Percent

6 cases (5 cases with mild hydronephrosis and one case with moderate hydronephrosis)

Spontaneous improvement

46%

2 cases (one case with nephrocalcinosis of prematurity and other case with unilateral agenesis)

Follow up

15%

2 cases (one case with renal tubular acidosis and other case with bilateral renal hypoplasia and renal impairment)

Medical treatment

15%

3 cases (one case with severe hydronephrosis diagnosed by C.T. as pelviureteric junction obstruction and another with moderate hydronephrosis diagnosed by ascending cystourethrography as posterior urethral valve and a case with left poly cystic nonfunctioning kidney

Surgical intervention

24%

 

 

DISCUSSION

    Our study showed that the overall incidence of neonates with congenital anomalies of kidney and urinary tract (CAKUT) was 3.3%,which was similar to Richter et al. (2012).

    The most prevalent anomaly was hydronephrosis which was differentiated in groups according to the degree. Grading systems of hydronephrosis have been devised to communicate the degree of upper collecting system dilation. The most common system used was originally designed for grading neonatal and infant hydronephrosis (Keays et al., 2008). Our study showed that 38.4% of abnormal cases were mild hydronephrosis, moderate hydronephrosis represented 15.4%, and severe hydronephrosis represented 7.7%. So, cases with hydronephrosis represented 2% of all sample size. The follow up ultrasound revealed that all cases with mild hydronephrosis showed improve-ment, and also one case with moderate hydronephrosis. These cases were diagnosed as transient hydronephrosis and represented 46% of positive cases. The case with bilateral moderate hydro-nephrosis underwent ascending cysto-urethrography and showed posterior urethral valve. The case with severe hydronephrosis underwent computed tomography with contrast showed pelviureteric junction obstruction. The remaining cases were two cases with nephrocalcinosis represented 15.4%; one of them was nephrocalcinosis of prematurity, and the other was renal tubular acidosis. One case showed polycystic kidney represented 7.7%. One case with unilateral renal agenesis represented 7.7%, and one case with bilateral renal hypoplasia represented 7.7%. Results of our study were similar to Susanne et al.(2012) who stated that ultrasound screening of the kidneys and urinary tract showed hydronephrosis representing about 1.5%.

    Our study showed that transient hydronephrosis represented 46% of positive cases which was similar to Nguyen et al. (2010) who stated that transient hydronephrosis represents 41-88 % of detected prenatal hydronephrosis which is resolved at birth or in early infancy.

    Comparison between abnormal cases and normal neonates in relation to demographic data as gestational age, maternal age and body weight showed no significant difference between both groups and no significant relation to other variables. These results were different from a study which showed that advanced maternal age associated with increased risk of CAKUT (Margarett et al., 2011). And different from a study which showed that there were significant differences between cases and controls with regard to average gestational age and average birth weight with increased risk with low birth weight and prematurity (Nicola et al., 2011). These differences from these studies can be explained by small sample size of our study.

    In comparison between abnormal cases and normal neonates in relation to mode of delivery, our study showed majority of cases with in congenital anomaly group delivered vaginally with significant difference and no significant relation to other variables. These results were different from a study which showed that increased incidence of CAKUT with cesarean section and the reason for this finding is not clear because it is not related to prenatal diagnosis of the malformation (Nicola et al., 2011). These differences from this study can be explained by small sample size of our study.

    In relation to prenatal history, our study showed no statistically significant difference between both groups. These results were different from a study which showed that maternal DM is significantly associated with CAKUT (Margarett et al., 2011). This difference can be explained by small sample size of our study.

    In relation to family history of renal anomalies, our study showed that frequency of positive family history was more among positive group with statistically significant difference which suggests a genetic predisposition. This resultwas similar toToka et al.(2010) who stated that familial cases of CAKUT have been reported which suggests a genetic predisposition.

    Serum creatinine level in our study showed that positive group had higher serum creatinine compared to negative with significant difference. The elevated value of creatinine in CAKUT group was related to the case with bilateral renal hypoplasia with high serum creatinine Level. This result was similar to Lewis et al. (2008) who stated that small kidneys (decreased amount of functional renal tissue) are the leading cause of renal replacement therapies in children and are much more common than congenital nephrotic syndromes or polycystic kidney disease.

    Different risk factors in our study showed that positive family history of renal anomalies together with family history of diabetes mellitus and maternal age above 35 were considered predictors for renal anomalies by binary logistic regression.

    Follow up showed that five cases with mild hydronephrosis and one case with moderate hydronephrosis represented 46% of abnormal cases showed spontaneous improvement, and one case with nephrocalcinosis of prematurity and other case with unilateral agenesis for follow up represented 15%,and one case with renal tubular acidosis and other case with bilateral renal hypoplasia and renal impairment for medical treatment represented 15%,and one case with severe hydronephrosis diagnosed by C.T. as pelviureteric junction obstruction, and another case with moderate hydro-nephrosis diagnosed by ascending cystourethrography as posterior urethral valve, and a case with left poly- cystic nonfunctioning kidney. The three cases for surgical intervention represented 24%. These results were similar to a study which showed that most cases with hydronephrosis give spontaneous resolution except cases with larger initial APD, grade 4 hydronephrosis are independently associated with lower likelihood of resolution, and large initial APD has predictive value for surgical intervention (Michelle et al., 2011).

    Quirino et al. (2012) stated that, after about 20 years of systematic approach to prenatally detected nephrouropathies, understanding of clinical course and natural history of CAKUT has clearly improved.

CONCLUSION

    Patients with CAKUT must be followed until adulthood with strict control of BP and renal function, especially for the high-risk subgroup of infants with associated hydronephrosis at baseline. Prediction of the risk of CKD and hypertension in individual cases is difficult, and therefore, regular follow-up remains the only way of recognizing these subjects.

REFERENCES

1. Arlen AM and Cooper CS. (2015): Controversies in the Management of Vesicoureteral Reflux. Curr Urol Rep., 16(9):538-539.

2. Harambat J, van Stralen KJ and Kim JJ. (2012): Epidemiology of chronic kidney disease in children. Pediatr Nephrol, 27: 363–373.

3. Keays MA, Guerra LA, Mihill J , Mihill J, Raju G, Al-Asheeri N, Geier P, Gaboury I, Matzinger M, Pike J and Leonard MP. (2008): Reliability assess-ment of Society for Fetal Urology ultra-sound grading system for hydronephrosis. J Urol., 180(4):1680–1689.

4. Lewis MA, Shaw J, Sinha M,Adalat S, Hussain F and Inward C. (2008) : UK Renal Registry 11th Annual Report (December 2008): Chapter 13 Demography of the UK paediatric renal replacement therapy population. Nephron Clinical Pract.,111 (Suppl 1): c257–267

5. Margarett S, Rachel B, Jonathan LW and Stephen MS. (2011): Maternal Risk Factors for Congenital Urinary Anomalies: Results of a Population-based Case-control Study. Urology, 78: 1156–1161.

6. Michelle L, Angela N, Andrew E, MacNeily and Kourosh A (2011): Prediction of the outcome of antenatally diagnosed hydronephrosis: A multivari-able analysis. Journal of Pediatric Urology, 8: 135-139.

7. Nguyen HT, Herndon CD, Cooper C,Gatti J, Kirsch A, Kokorowski P, Lee R, Perez BM, Metcalfe P, Yerkes E, Cendron M. and Campbell JB. (2010): The Society for Fetal Urology consensus statement on the evaluation and management of antenatal hydronephrosis. Journal of  Pediatric Urology, 6:212–231.

8. Nicola F, Juanita H, Pedro M,Jaime P, and Ignacio Z. (2011): https://www.researchgate.net/profile/Ignacio_Zarante/publication/51654721_Association_between_maternal_prenatal_vitamin_use_and_congenital_abnormalities_of_the_genitourinary_tract_in_a_developing_country/links/55102f4b0cf2a7335e849af1.pdf Association between maternal prenatal vitamin use and congenital abnormalities of the genitourinary tract in a developing country. Journal of Pediatric Urology, 8: 121-126.

9. Quirino IG, Diniz JS, Bouzada MC, Pereira AK, Lopes TJ, Paixa˜o GM, Barros NN, Figueiredo LC, CabralAC, Silva AC. and Oliveira EA.(2012): Clinical course of 822 children with prenatally detected nephrouropathies. Clin J Am Soc Nephrol., 7:444-451.

10. Richter RM, Lange AE, Hinken B, Hofmann M, Stenger RD, Hoffmann W, Fusch C. and Haas JP.(2012): Ultrasound Screening Strategies for the Diagnosis of  Congenital Anomalies of the Kidney and Urinary Tract. Ultraschall in Med., 33(7): E333-E338.

11. Rodriguez MM. (2014): Congenital anomalies of the kidney and the urinary tract (CAKUT). Fetal Pediatr. Pathol., 33(5-6): 293-320.

12. Schwaderer AL, Bates CM, McHugh KM and McBride KL. (2007): Renal anomalies in family members of infants with bilateral renal agenesis/a dysplasia. Pediatr Nephrol., 22:52-56.

13. Song R and Yosypiv IV.(2011): Genetics of congenital anomalies of the kidney and urinary tract. Pediatr Nephrol, 26: 353-364.

14. Susanne EG, Katja K, Corinna P, Eva B, Jenny W and Volker K. (2012): Ultrasound screening of the kidneys and urinary tract in 11,887 newborn infants: A 10-year experience, Open Journal of Obstetrics and Gynecology, vol. 2 No. 4 Article ID: 24484, 5 pages.

15. Toka HR, Toka O, Harir A andNguyen HT. (2010): congenital anomalies of kidney and urinary tract. Semin Nephrol., 30:374-486.


 مسح بالموجات فوق الصوتیة لحدیثى الولادة لإکتشاف التشوهات الخلقیة فى الکلى والمسالک البولیة

مفتاح محمد ربیع- إبراهیم عبد الفتاح القشلان- سوزان السید الطحلاوى

محمد منیر عبد المجید شعراوى

قسمى طب الأطفال والأشعة التشخیصیة-کلیة الطب-جامعة الأزهر

خلفیة البحث:التشوهات الخلقیة فی الکلى والمسالک البولیة تمثل السبب الأکثر شیوعا للمراحل المتأخرة من أمراض کلى الأطفال، کما أن الإکتشاف المبکر لتلک التغیرات یتیح الوقت المناسب للتدخل المبکر وعمل الفحوصات اللازمة وبدایة العلاج.

الهدف من البحث: تحدید نسبة حدوث التشوهات الخلقیة فی الکلى والمسالک البولیة لحدیثی الولادة، وکذلک تحدید الأطفال الأکثر قابلیة لحدوث تلک التشوهات الخلقیة.

المرضى وطرق البحث: أجریت هذه الدراسة على 390 طفلاً من حدیثی الولادة تتراوح أعمارهم بین 3-30 یوماً بقسم حدیثی الولادة بمستشفى المطریة التعلیمی ومستشفى الحسین الجامعی، وذلک فی الفترة من یولیو 2014 إلى یولیو  2015، وقد تم ضم جمیع الأطفال الموجودین بالقسم فیما عدا الأطفال الذین یعانون من تشوهات خلقیة ظاهریة، أو یعانون من مشاکل جراحیة طارئة، أو خلل بالتمثیل الغذائی وقد خضعت جمیع الحالات بعد أخذ الموافقة من الأهل لأخذ التاریخ المرضى الکامل والفحص الإکلینیکی الشامل و فحص بالموجات فوق الصوتیة وإخبار وظائف الکلى، کما خضعت بعض الحالات إلى فحوصات إضافیة عبارة عن عمل أشعة مقطعیة بالصبغة، وعمل تصویر بالنظائر الضوئیة،وأشعة تصاعدیة بالصبغة.

النتائج: أسفرت الدراسة عن اکتشاف 3.3% حالة إیجابیة من العینة الخاضعة للدراسة، کما أسفرت الدراسة أن الأطفال الذین لدیهم إستعداد أعلى للإصابة بتشوهات خلقیة بالکلى والمسالک البولیة هم من لدیهم تاریخ عائلی للإصابة بتشوهات الکلى، ومن یزید سن الأم لدیهم عن 35 عاماً، أو تکون الأم مصابه بالبول السکری.

الخلاصة: التشوهات الخلقیة فی الکلى والمسالک البولیة تمثل مشکلة صحیة رئیسیة وهی السبب الرئیسی للمراحل المتأخرة من المرض الکلوی فی الأطفال، کما أن التشخیص المبکر یتیح وقتا للمتابعة والتدخل المبکر لمنع أو على الأقل إبطاء التدهور.    

 

REFERENCES
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