Retrospective cohort study of neonatal blood transfusion in China

The development of neonatal hematopoietic system is not mature, and the condition changes rapidly during hospitalization. Transfusion therapy is widely used in neonatal patients. Due to these characteristics in very low birth weight (VLBW) neonates, transfusion rates during hospitalization can be as high as 80% [1‐5]. Gestational age is known to be inversely proportional to the number of blood transfusions [6]. However, improper blood transfusion treatment also brings transfusion reactions. For example, excessive blood transfusion can lead to iron overload, heavy circulatory load, intraventricular hemorrhage and adverse reactions [7‐11]. On the other hand, insufficient blood transfusion treatment will affect neonatal development and therapeutic effect disease treatment, and can lead to apnea, neurodysplasia or poor weight gain [12]. Therefore, it is extremely important to determine the threshold of neonatal blood transfusion treatment. A small group of countries including Britain, the United States and Australia have formulated clear neonatal blood transfusion programs [6, 13‐15]. However, thresholds for neonatal transfusions vary from country to country. This may be due to regional, racial and ethnic differences in approach to medical conditions and treatment [16]. The standardization of neonatal blood transfusion protocols, however brings potential risks, especially for VLBW infants. A large number of studies have reported that strict blood transfusion thresholds increase the frequency of adverse neurologic events, reduce long-term brain volume, increase the incidence of periventricular leukomalacia and a series of intraventricular hemorrhage complications [17]. On the other hand, recent studies take the opposite view, particularly in two large cohort studies that found no difference in mortality or complications between lower and higher blood transfusion thresholds [18, 19]. Doctors in some parts of China refer to clinical experience and foreign neonatal transfusions standards when conducting neonatal transfusion therapy. The recommended threshold for neonatal blood transfusion treatment in China is otherwise taken from Practical Neonatology (5th edition) [20]. For neonates weighing less than 1500 g, the recommended transfusion threshold is as published in the UK in 2015. The other neonatal-weight groups’ transfusions were judged comprehensively according to clinical experience, normal range of Hb range. Up until now, clinical studies to determine a suitable threshold for Chinese newborns are lacking. Therefore, it is important to establish a multi-center retrospective cohort study to evaluate whether the blood transfusion scheme is suitable for newborns in China.

In this study, a multi-center retrospective cohort study was established to observe the transfusion treatment status, clinical symptoms, signs and other variables in neonates during hospitalization, and at 1 week and 1 month follow-up points after discharge. The cohort involved 5669 transfused newborns from 46 hospitals in 21 provinces and 7 regions of China. Each case contained 280 variables, out of a total of 2.98 million variables. The main objectives of this cohort study included the following: Newborns with different body weights were defined as restricted blood transfusion (RBT) and non-restricted blood transfusion (NRBT) cohorts respectively according to the recommendations on neonatal transfusion thresholds in Practical Neonatology (5th edition) (Supplementary Table 1), so that the applicability of this protocol in Chinese neonates could be evaluated according to outcome. From this, appropriate neonatal transfusion thresholds and neonatal transfusion protocols were sought for future guidance in Chinese hospitals. This study was approved by the Ethics Committee of the Institutional Evaluation Committee of Shaanxi Provincial People's Hospital (NO: 2020-R001).

In the three cohorts with different weights, the baseline distribution of mothers' baseline age, delivery mode, multiple births, parity, pregnancy times and accompanying complications were not statistically different (Table 1). The baseline characteristics of newborns in the three groups were basically also similar in terms of sex, birth weight, birth length, birth head circumference, admission weight, Apgar score, and number of concomitant diseases. The < 1500 g group had differences in Apgar at 5 min, 10 min and ventilator use. There were differences in gender, birth length, admission weight and ventilator use in the 1500-2500 g group. The birth weight, Apgar score and ventilator use were significantly different in the ≥ 2500 g group (Table 2).

The investigation of blood transfusion treatment in the < 1500 g group showed that compared with the NRBT group, the RBT group had lower levels of Hb at the time of admission and hospitalization. The number of infusions and average total infusion volume were larger in the RBT group, but the average infusion volume per infusion was the same between the two groups (Table 3). Among secondary outcome indicators, the RBT group had fewer costs. The main outcome indicators showed that there was a statistical difference between the two groups. The implementation of this standard significantly increased the risk of death. The mortality rate in the RBT group (11.41%) was higher than that in the NRBT group (5.12%) (Tables 4, 5).

The study of blood transfusion treatment in the 1500-2500 g group suggested that compared with the NRBT group, the RBT group had lower levels of Hb at the time of admission, hospitalization and discharge. There were no differences in other blood transfusion treatments between the two groups. Among the secondary outcome indicators, the RBT group had less hospitalization time, NICU time, and hospital costs. The incidence of necrotizing enterocolitis (NEC) was lower in RBT group (Table 6). The mortality rate of RBT group (3.53) was lower than that of NRBT group (4.71) (Tables 4, 5), but there was still no statistical significance between the two groups.

Blood transfusion treatment in the ≥ 2500 g group suggest that compared with the NRBT group, the RBT group had lower levels of Hb at the time of admission, hospitalization and discharge. There was no significant difference between the two groups in the methods of red blood cells, plasma and platelet transfusion. Among the secondary outcome indicators, the restricted transfusion group had less hospitalization time and hospital costs. The incidence of retinopathy of prematurity (ROP) was lower in the RBT group (Table 6). The death outcome of the two groups showed that the mortality rate of RBT group (3.02) was significantly lower than that of the NRBT group (9.55) (Tables 5, 6).

Multivariate logistic regression model analysis showed that mortality rate of NRBT group was 0.52 times than that of RBT group (95% CI: 0.282–0.959, P < 0.05) in the < 1500 g group. There was no significant difference between the two groups in the 1500–2500 g group. The mortality rate of the NRBT group was 3.052 times higher than that of RBT group (95% CI: 1.128–8.255, P < 0.05) in the ≥ 2500 g group, and the application of ventilator intervention had a protective factor against death. The results showed that neonatal mortality with different weights were consistent with those of the univariate analysis (Supplementary Table 3).

This multi-center cohort study was the largest epidemiological analysis of neonatal blood transfusion practice in China to evaluate the application of blood transfusion thresholds to newborns. Included were basic information regarding transfused newborns and mothers and detailed information on the blood transfusion treatment given, examination results, complications and mortality. In the < 1500 g group, the RBT mortality rate was significantly higher than the NRBT group, and the risk of death was increased. We disagree whether this threshold was applicable to the newborns in < 1500 g group. There was no difference in mortality between the 1500-2500 g group, but the hospital stays and costs were significantly lower when the lower restrictive threshold was implemented. The incidence of acute NEC was lower. The outcome of the RBT group showed better performance. The mortality rate of RBT in > 2500 g group was significantly lower than that in the NRBT group. The threshold treatment scheme was protective to newborns, and the incidence of ROP was lower and produced fewer hospital stays and fewer medical costs. This group also showed better discharge outcome in the RBT threshold group.

It has been reported that different blood transfusion thresholds should be adopted for newborns with different weights, and a higher threshold should be carried out in NRBT for newborns with very low weights, so as to ensure the development of the nervous system. More and more studies have shown that the adverse effects of RBT on newborns have inconsistent results, especially for low birth weight infants and newborns with severe diseases [21‐25]. Some recently published prospective studies show that there is no difference in mortality between restricted and non-restricted transfusion thresholds for premature infants [18, 19]. Some researchers believe that a broader blood transfusion threshold is not beneficial, citing increased mortality and complications [26‐29]. However, it is obvious that the threshold of neonatal blood transfusion is not consistent among countries, which may be one of the reasons for different research results. The results of this study showed that the overall mortality rate was significantly increased in the < 1500 g body weight group using the current blood transfusion threshold. The other two groups showed a positive effect in reducing mortality, especially in the > 2500 g group, while RBT showed the same trend.

Transfusion will disturb the microcirculation regulation of the body and may lead to a series of transfusion-related complications [30]. Blood transfusion has been correlated with death, bronchopulmonary dysplasia (BPD), periventricular leukomalacia (PVL), necrotizing enterocolitis (NEC), intraventricular hemorrhage (IVH) and retinopathy of prematurity (ROP). The long-term results of neurological development under different blood transfusion criteria have shown contradictory results in a large number of studies [17‐19]. The results of the previous studies show that the incidence of early ROP in RBT group is slightly lower. Frequent and large-scale blood transfusion may be related to increased risk of inflammatory state [24, 31]. Blood transfusion rates are higher in premature infants than in full-term infants, accordingly results here also found that the incidence of ROP in very low birth weight (< 1500 g) newborns was higher than 10%. Moreover, the incidence of ROP with restricted blood transfusion regimens was lower in the group with body weights of ≥ 2500 g.

Results on the incidence of NEC showed that the incidence was lower when a restrictive blood transfusion threshold was applied [31]. However, Patel et al. concluded that Anemia will increase the risk of NEC [32]. A prospective cohort study conducted by Ozcan B. in 2020 showed that the level of L-fatty acid binding protein in premature infants with anemia increased, suggesting that anemia aggravated intestinal injury [33]. Meta-analysis of several studies showed contradictory results about blood transfusion and NEC incidence [34]. The incidence of NEC was lower in our study on newborns with a lower blood transfusion threshold of 1500 g-2500 g weight. There was no difference in the incidence of NEC between the other weight groups whether restricted or unrestricted transfusions were performed.

Research into IVH caused by blood transfusion also show different conclusions. Most research results show that blood transfusion will increase the occurrence of IVH, however a few reports suggest that preventing anemia is beneficial to IVH. This study’s results were consistent with the ETTNO and TOPs studies outlined above, and no significant difference was found in different blood transfusion thresholds for IVH. Higher blood transfusion thresholds did not reduce the incidence of IVH [7, 17].

In literature concerning red blood cell transfusion dosage, neonatal red blood cell transfusion dosage is usually reported at between 5—20 mL/kg worldwide. BCSH guidelines stipulate that the infusion amount of neonatal red blood cells should be 10-20 mL per kilogram. When accompanied by bleeding and severe anemia, the infusion amount should be appropriately increased, however there is no recommended amount for appropriate increase. At present, the recommended red blood cell infusion dose for newborns in China is generally small at (10—20) ml/kg per time, while for premature infants, especially at very low birth weights, it is generally (5—15) ml/kg per time. The results of this study showed that the infusion volume for different body weight groups was (8–10) ml/kg per time. There was no difference in the comparison between restricted and unrestricted transfusions and different weight groups, so different blood transfusion thresholds had no effect on the infusion volume per kilogram of body weight, and the blood transfusion volume per kilogram of body weight was consistent between the two groups. Chinese doctors show a high degree of consistency in the application of blood transfusion volume. The number and total amount of blood transfusions in the < 1500 g group were significantly higher than those in the unrestricted group because of the lower Hb value in the restricted group.

In summary, we question whether a recommended blood transfusion threshold is suitable for Chinese newborns. The results show that the 1500-2500 g newborns had no significant difference in mortality and no complications was found between the two groups except for the incidence of NEC. The lower blood transfusion threshold played a protective role in NEC. The shortened newborns’ hospital stays and reduced treatment cost were also encouraging. Restricted blood transfusion thresholds in newborns (≥ 2500 g) significantly reduced mortality, and the incidence of ROP was lower than that in non-restricted blood transfusion groups. The hospital stays and treatment costs were also reduced. It is worth noting that although there was no difference in complications relating to blood transfusions in very low birth weight infants, lower blood transfusion thresholds lead to a significant increase in mortality. From these results, it is clear that we need to find a more suitable blood transfusion scheme for very low birth weight infants (< 1500 g).