First experience with Tolvaptan for the treatment of neonates and infants with capillary leak syndrome after cardiac surgery

Our retrospective analysis encompasses a single center experience (Department of Pediatric Cardiology at the Friedrich-Alexander-University of Erlangen-Nürnberg, Germany). We included 25 patients with CHD after cardiac surgery, treated with TLV in ICU between June 2011 and May 2017, evaluating effects of postoperative TLV therapy in patients with CLS. Criteria for the use of add-on therapy was 1) fluid overload 2) no increase in urinary output under conventional diuretic therapy 3) persisting renal function (no anuria) 4) low serum sodium. Descriptive patient’s auxologic and clinical characteristics, leading cardiologic diagnosis and the respective surgical procedures are displayed in Tables 1 and 2. Our cohort included four preterm patients (1: 31 + 6; 2: 35 + 6; 3: 34 + 5; 4: 34 + 5). Corrected age for preterm infants at TLV treatment was 35 + 3, 39 + 5, 41 + 0 and one infant received therapy 8 month after birth.

We evaluated Risk Adjusted Congenital Heart Surgery score (RACHS-1) [26, 27] and basic Aristotle score [28] to quantify risk and complexity of the performed surgeries. STS-EACTS mortality category and associated major complications (95% CrI) were implemented to express mortality associated with congenital heart surgery and classifying congenital heart surgery procedures on the basis of their potential for morbidity [29, 30]. Team of surgeons, anesthesiologists and pediatric cardiologists remained unchanged during the study period. All patients underwent median sternotomy. Post-operative treatment was exclusively supervised on the pediatric cardiology ICU, beat-to-beat circulatory and pulmonary status, fluid and electrolyte homeostasis was digitally monitored, clinical status and organ function was monitored and digitally documented routinely by critical care nursing staff. Co-medication including conventional diuretic therapy before and during the treatment course with TLV was analyzed.

CLS was defined by clinical symptoms (volume overload, intravascular hypovolemia, low total protein, hypoalbuminemia, hemoconcentration) and subcutaneous-thoracic ratio (ST-Ratio; > 97. percentile). ST-Ratio was evaluated to quantify CLS by chest x-ray with anterior-posterior beam path [6]. X-rays were documented with Web Ris (celsius37.​com AG, Mannheim, Germany).

Responder to TLV were classified according to the definition from adult studies by Imamura et al. [21, 22, 31] “responders as patients with any increase in urine volume (UV) at day 1 when TLV administration was started”. To classify individuals as responder in our population to TLV we permitted an increase of > 10% in urinary output within 24 h after the first TLV administration. Others were classified as non-responder [20‐22].

TLV (“Samsca”, Otsuka, Japan) was administered as individual healing attempt in critically ill children with complicated postoperative course. Off-label use was explained and informed consent was obtained by all participating families. Starting dose of TLV was 25% of target dose (1 mg/kg/d). Dose finding was titrated based on clinical symptoms, side effects (see below) and serum sodium levels. Tablets are available in 15 mg and 30 mg. Provision of small dosages was performed by the department of pharmacology of the University hospital Erlangen. Tablets were pulverized and encapsulated. At the ICU the pulverized aliquots were diluted and administered via nasogastric tube.

Adverse events were retrospectively analyzed according to the criteria of Otsuka applying for the planned Phase 3b, multicenter study trial “effects of TLV in hospitalized children with euvolemic or hypervolemic serum hyponatremia”.

Adverse events are classified: 1) absolute serum sodium level > 145 mmol/L or an overly rapid rise in serum sodium level (an increase in serum sodium of > 8 mmol/L over a 10-h period, 12 mmol/L over a 24-h period. 2) neurological symptoms, or other signs or symptoms suggestive of osmotic demyelination. 3) worsening symptoms of hyponatremia. 4) elevations in AST or ALT that are > 2 x ULN (upper limit of normal) or levels that increase > 2 times their previously observed level.

TLV doses were calculated in mg/kg (preoperative weight)/d. Volume overload was quantified, assuming preoperative weight as 100%. TLV application period, time on mechanical ventilation, time until extubation, body weight, urinary output and total daily dose of selected concurrent medications were recorded by Integrated Care Manager (ICM, Drägerwerk AG & Co. KGaA, Lübeck, Germany) software solutions. Retrospective data acquisition of laboratory values before surgery, before TLV treatment and during TLV treatment was performed using Lauris (version 15.09.29.9, Swisslab GmbH, Berlin, Germany) (Table 1).

Post-operative indication for transfusion was alike and followed our departmental transfusion algorithm: packed red blood cells (PRBC) were administered at a hemoglobin (Hb) level of 14 g/dl in cyanotic patients and 10 g/dl in non-cyanotic patients. In the case of on-going bleeding, fresh frozen plasma (FFP, 10-15 ml/kg) was transfused if quick reached below 50%. Platelets were transfused at a platelet count below 50 × 10³/μl.

Postoperative indication for fluid substitution of kristalloids (NaCl and Jonosteril) is central venous pressure (CVP) < 5, and low blood pressure (BP) according to age related reference ranges. Administration of colloidal volume expanders, i.e. albumin and hydroxyethyl starch (HAES) is performed in hemodynamically unstable cases or low serum albumin levels.

Quantitative approximately normally distributed variables are expressed as mean ± standard deviation (SD). For ordinally scaled data (e.g. RACHS-1) and for variables with skewed distribution median value together with minimum and maximum are given. As most of variables in Table 1 (demographic parameters, co-medication and laboratory parameters) and 3 (co-medication and laboratory parameters) seem to be normally distributed and due to the rather small sample sizes non-parametric Mann-Whitney-U tests have been performed in order to compare the median values of the two groups. For qualitative factors (i.e. cardiac malformation or procedures) absolute frequencies are presented. Fisher’s exact tests have been used.

In order to investigate changes over time (regarding weight, serum sodium, osmolality, and urinary output) ANOVAs for repeated measurements have been performed including time point and responder group as fixed factors and patients’ ID as a random factor. For the liver enzymes, Friedman’s test was performed instead of ANOVA for repeated measurements, because of the skewed distribution. Multiple regression analysis including all parameters was performed to identify predictive parameters for TLV responder.

The retrospective study was approved by the ethics committee of the University of Erlangen-Nürnberg (Re.-No. 145_13B). The study was conducted in accordance with the Declaration of Helsinki [32].

Postoperative CLS was diagnosed in 25 patients after cardiac surgery. Clinical parameters to define CLS are displayed in Table 1.

According to the definition of TLV responder by Imamura et al. [21, 22, 31] 17 individuals were identified as responder to TLV defined by an increase in urinary output > 10% in 24 h and 8 infants were identified as non-responder [20‐22] (Table 1).

Age was similar in both groups (median 35 and 37.5 days; p = 0.3821). The underlying cardiac malformation and surgical procedures are displayed in Table 2. Extracardiac malformations and syndromes were Trisomy 21 in one responder and one non-responder patient, Turner syndrome in one non-responder and omphalocele in one responder patient. Surgical parameters (cardio pulmonary bypass (CPB) time, cross clamp time and surgical risk scores RACHS-1 and Aristotele score) are displayed in Table 1. In 15 patients, primary chest closure was not possible and secondary closure was performed. Both groups presented with increased ST-ratio > 97. percentile (p = 0.6408). A significant positive correlation was identified between ST-ratio and time on CPB (p = 0.0305, Pearson‘s correlation coefficient r = 0.4333). STS-EACTS mortality category was 4 in responder and 3 in non-responder (p = 0.2201) and estimated major complication rates are 15.3% in responder compared to 12.4% in non-responder (p = 0.2190). Four responder patients showed severe infection with elevated procalcitonin (PCT) (n = 1 necroticing enterocolitis, n = 1 positive blood culture with Straphylococcus epidermidis, n = 1 pneumonia with Enterococcus faecalis, n = 1 Enterococcus faecium wound infection). Infection rates normalized before TLV treatment in all responder patients. One non-responder patient presented with an infection during treatment (n = 1 Staphylococcus epidermidis in intraoperative pericardial swab). Postoperative major complications are demonstrated in Table 3.

Postoperative days on ICU, before TLV therapy was started (p = 1.0000), preoperative weight (p = 0.7487) and absolute weight (p = 0.8673) when TLV was started were not significantly different between responder and non-responder. All individuals presented with increased body-weight with a median of 131.8% over their preoperative weight in the responder group and 133.5% in the non-responder group, when TLV was started (p = 0.8151). The duration of TLV application (p = 0.6391) and average dose of TLV (p = 0.6204) administered were similar. Median length of stay in the ICU after TLV administration was significantly shorter in responder compared to non-responder patients (15 vs. 40.5 days; p = 0.0155).

Laboratory parameters were analyzed at several time points. Preoperative parameters did not show significant differences between both groups (Additional file 1: Table S1). Before TLV treatment non-responder group presented with a higher hematocrit (p = 0.0169) and higher hemoglobin level (p = 0.0168). According to CLS criteria: total protein was lowered in both groups (responder: 37.0 g/l and non-responder: 38.84 g/l; p = 0.9303) and median albumin levels were decreased in responder 20.15 g/l and non-responder 21.50 g/l (p = 0.7983). Serum sodium levels were low/normal in both groups (responder: 135 mmol/l vs. 130.5 mmol/l; p = 0.1269). No differences were observed for serum blood urea nitrogen (BUN), creatinine, potassium and serum osmolality before TLV treatment was started (Table 4).

Vital parameters including (BP, heart rate (HR) and CVP) were analyzed. CVP decreased during TLV treatment in both groups, but was not significantly different. Mean BP was lower in non-responder on day 2 (p = 0.0035) and day 3 (p = 0.0309) of treatment (Additional file 1: Table S2).