Annals of Pediatrics and Child Care

Sodium Bicarbonate Administration and Metabolic Acidosis of Preterm Infants: A Useless Therapy?

Bérengère FRANCOIS1*, Coralie LO PRESTI2, Sophie HASSID1, Renaud VIALET1 and Claire NICAISE1

1Service de réanimation pédiatrique et néonatale, Hôpital Nord, Marseille, France

2Pharmacie centrale, Hôpital Nord, AP-HM, chemin des Bourrely, France

*Corresponding author: Bérengère FRANCOIS, Service de réanimation pédiatrique et néonatale, Hôpital Nord, AP-HM, chemin des Bourrely, 13015 Marseille, France.

Citation: Francois B, Presti CL, Hassid S, Vialet R, Nicaise C (2019) Sodium Bicarbonate Administration and Metabolic Acidosis of Preterm Infants: A Useless Therapy?. Ann Pediatr Child Care: APCC-100005.

Received Date: 20 March, 2019; Accepted Date: 25 April, 2019; Published Date: 07 May, 2019

 

Abstract

Background: Metabolic acidosis due to renal loss is a common complication of prematurity. Sodium bicarbonate is still frequently used in this indication despite the lack of recommendation. The objective was to evaluate the restriction of the indication of sodium bicarbonate therapy in metabolic acidosis due to renal immaturity in preterm infants in two historical series of patients. In addition, we measured the effect of this therapy on acid-base status.

Methods: This was a retrospective monocentric study from two historical cohorts. All preterm infants under 28 weeks of gestation with metabolic acidosis (pH <7.20 and excess base (EB) £ -10 mmol / L) were included. During the first period (June 2011 to May 2012) patients were treated with sodium bicarbonate if the EB was £ -10 mmol / L. In the second period (October 2012 to September 2013), patients were treated if EB £ -13 mmol /L.

Results: Twenty-seven patients were included during the first period with an average gestational age of 26.5 weeks versus 38 patients during the second period with an average gestational age of 26.1 weeks (p = 0.41). In period 1, 27/27 patients (100%) were treated against 21/38 (55.2%) during the second period (p <0.001). There was no significant difference over the two periods regarding the difference in pH, pCO2 and EB between the end and the beginning of sodium bicarbonate treatment.

Conclusions: Changing our protocol decreased sodium bicarbonate use and was not associated with any change in pH, pCO2 and EB.


Keywords: Metabolic acidosis; Preterm infants; Sodium bicarbonate

Introduction

Metabolic acidosis with loss of bases is a common complication of prematurity. It is mainly due to renal immaturity [1]. Full performance of renal functions depends on gestational age and postnatal age, so that glomerular and tubular functions are immature [2,3]. Tubulopathy of preterm is responsible for excessive loss of bicarbonate due to a lack of tubular reabsorption of bicarbonate, electrolytes and small proteins that lead to metabolic acidosis, fluid, electrolyte disturbances, and weight problems [2,4,5]. Metabolic acidosis may have serious consequences: impaired cardiovascular function, cardiac arrhythmia, inflammation and decreased immune response [6]. Metabolic acidosis in prematurity has been associated with the development of intraventricular hemorrhage, periventricular leukomalacia and delayed psychomotor development [1]. For more than 60 years, sodium bicarbonate administration has been used in case of metabolic acidosis management in order to normalize the pH by acid-base reaction [7-10]. There are no recommendations in the treatment of metabolic acidosis of premature renal failure, although this treatment is widely used. Several authors, however, have described occasional severe complications such as intraventricular hemorrhage (IVH) following the use of bolus bicarbonate infusion in preterm newborns [1,11].

The main objective of our study was to evaluate the restriction of the indication of sodium bicarbonate in metabolic acidosis due to renal immaturity in preterm under 28 weeks of gestation during two periods and to assess the outcome of untreated patients during the second period.

The secondary objective was to evaluate the consequences of this change of practice on acid-base status.

Materials and Methods

Patients and methods: This is a retrospective monocentric study in the neonatal intensive care unit of the Hôpital Nord of Marseille (France) from two historical cohorts. All preterm infants under 28 weeks of gestation with metabolic acidosis were included. Metabolic acidosis was defined as pH less than 7.20 and EB less than or equal to -10 mmol / L. During the first period, from June 2011 to May 2012, patients were treated with continuous sodium bicarbonate infusion at 1 to 2 mEq / kg / day if the EB was less than or equal to -10 mmol / L, until correction of metabolic acidosis. During the second period, from October 2012 to September 2013, patients were treated if the EB was less than or equal to -13 mmol / L. The factors taken into account were: gestational age, birth weight, age at the time of treatment, pH, pCO2 and EB (before, during and at the end of sodium bicarbonate treatment), duration of treatment, the total dose administered, the occurrence of intraventricular hemorrhage stage III and / or IV according to the classification of Papile [12].

Primary outcome was the evolution of pH, pCO2 (mmHg) and EB (mmol/l). Secondary outcome were theoccurrence of IVH III and IV and duration of treatment. The first day (D 0) considered is the first day of treatment ie when the EB was less than or equal to - 10 mmol / L in the "first period" group and less than or equal to -13 mmol / l in the "second period" group. End day was the last day of treatment. For untreated patients, the D0 was when the patient had an EB less than or equal to -10 mmol / L and the end day was 3 days later.

Statistical analysis: The differences between the end of treatment and the day 0 were calculated, mismatched differences between the values were  ??observed between the end and the beginning of treatment for pH, PCO2 and EB. For untreated patients in the "second period", the difference between first and third day was calculated. The comparisons between the quantitative variables were made by Student's t-test, and by the χ2 test with a risk α fixed at 5%. The software used was PASW Statistics (V 17.0.2). The number of patients required was 32 patients (16 per group) as calculated with BioStat TGV (http://marne.u707.jussieu.fr/biostatgv/), with risk alpha 0.05 and beta 80%.

Ethics: The procedures followed were in accordance with the ethical standards of the responsible committee on human experimentation (institutional and regional) and with the Helsinki Declaration of 1964, as revised in 2013.

Results: Twenty-seven patients were included during the first period with an average gestational age of 26.5 (SD 2.5) weeks versus 38 patients during the second period with an average gestational age of 26.1 (SD 1.1) weeks (p = 0.41). The mean birth weight was 0.96 kg (standard deviation: 0.45) in the first period versus 0.90 kg (standard deviation: 0.17) in the second period (p = 0.57). The main results are summarized in (Table 1).


Figures


 

Period 1 (treatment threshold for EB$ ≤ - 10 mmol/L)

Period 2 (treatment threshold for

 EB$ ≤ - 13 mmol/L)

 

Number of patients

27

38

p < 0.001

Number of treated patients (n^ (%))

27 (100%)

21 (55.2%)

p < 0.001

Age at D0* of treatment(SD**) days

5.17 (1.5)

8.41 (4.07)

p< 0.001

Duration of treatment

H(SD**)

119 (72)

89 (57)

p=0,90

Duration of metabolic acidosis

2.04 (1.19)

2.87 (1.63)

p = 0.027

Cumulated dose grams (SD**)

0.6 (0.4)

0.3 (0.3)

p=0.004

pH D0* (SD**)

7.19 (0.1)

7.14 (0.1)

NS

pH End# – pH D0*(SD**)

-0.01 (0.15)

0.02 (0.19)

p=0.40

pCO2 D0* mmHg (SD**)

44.7 (9.6)

47.9 (14.8)

NS

pCO2 End# – pCO2 D0*mmHg (SD**)

9 (15)

2 (17)

p=0.10

EB$D0*(SD**)

-11.9 (2)

-12.9 (2.7)

NS

EB$ End# – EB$D0*(SD**)

3.5 (4.5)

3.3 (4.8)

p=0.85

Intraventricular hemorrhage III and  IV (n^ (%))

3 (11.1%)

9 (23.7%)

p=0.198

Mean and standard deviation

*D0 : 1st day of treatment, #End : end of treatment or at 3 days of evolution,$EB : excess base,  H : hours, ^n = number,  **SD = standard deviation

Table 1: Results of all patients

 

Period 1 (treatment threshold for EB$ ≤ - 10 mmol/L)

Period 2 (treatment threshold for

 EB$ ≤ - 13 mmol/L)

 

Number of patients

16

17

 

Patients treated (n (%))

16 (100%)

0%

 

pH End# – pH D0*

-0.02 (0.13)

-0.04 (0.12)

p=0.61

pCO2 End# – pCO2 D0* (mmHg)

12 (15)

8 (16)

p=0.49

EB$ End# – EB$ D0*

2.7 (3.35)

0.5 (4.3)

p=0.12

Mean and standard deviation

*D0 = 1st day when EB < - 10 mmol/L, # End = end of treatment or at 3 days of evolution, $EB : base excess,  n = number.

Table 2: Patients with EB between – 10 et -13 mmol/L


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Citation: Francois B, Presti CL, Hassid S, Vialet R, Nicaise C (2019) Sodium Bicarbonate Administration and Metabolic Acidosis of Preterm Infants: A Useless Therapy?. Ann Pediatr Child Care: APCC-100005.