Cytokine serum levels during post-transplant adverse events in 61 pediatric patients after hematopoietic stem cell transplantation

In 5 (8.2 %) of 61 patients, VOD was diagnosed according to the clinical and laboratory criteria. The first clinical symptoms and noticeable changes in laboratory parameters of VOD occurred in these patients at a median on day 18 (range day 13 – 28) after HSCT. All 5 patients had significantly increased serum levels of IL-6 (P = 0.0313), IL-8 (P = 0.0156) and TNF-α (P = 0.0313) compared to the baseline before start of conditioning (Table 2). This occurred at the same time or shortly before (median 2 days, range 1–3 days) clinical symptoms were diagnosed (Table 2). None of the 5 pediatric patients with VOD had a GvHD grade III or IV or a sepsis simultaneously.

An acute GvHD appeared in 24 (39.3 %) out of 61 patients. 11 (45.8 %) of these 24 patients experienced a grade I, 9 (37.5 %) a grade II, 3 (12.5 %) a grade III and 1 (4.2 %) a grade IV GvHD (Table 1). 9 (37.5 %) patients developed an isolated acute organ GvHD; 6 (25 %) occurred in the skin, 2 (8.3 %) were isolated intestinal GvHD and one (4.2 %) occurred as an isolated liver GvHD. Liver GvHD: Two of the pediatric patients experienced liver GvHD stage III and stage IV, respectively. In both cases, a clear increase in the levels of IL-6, IL-8, IL-10, sIL-2R and TNF-α could be observed. In one patient, these increases occurred two days before laboratory chemical changes were seen for direct and indirect bilirubin and the transaminases ALT and AST. In the other patient, the cytokine levels and the laboratory chemical markers changed simultaneously. However, due to the small number of cases, it was not possible to detect any statistical significance (Table 2). Intestinal GvHD: In 9 (14.8 %) of the 61 patients an acute intestinal GvHD was observed. Acute intestinal GvHD stage I occurred in 2 (22.2 %) patients, while intestinal GvHD stage II was seen in 6 (66.7 %) . One patient (11.1 %) suffered from intestinal GvHD stage III. At the onset of the first clinical symptoms of acute intestinal GvHD with an increase of feces quantity, significant increases of IL-6 (p = 0.0010), IL-10 (p = 0.0039), sIL-2R (p = 0.0020), and TNF-α (P = 0.0020) were observed in all pediatric patients with acute intestinal GvHD stage II and III. In both patients with intestinal GvHD stage I, there was only an increase in cytokine levels of sIL-2R and IL-10. The cytokine levels of IL-8 and IL-1ß did not significantly change in the 9 patients with intestinal GvHD stage I to III (Table 2). Skin GvHD: A total of 15 (24.59 %) of the 61 pediatric patients experienced an acute GvHD of the skin. 6 (40 %) out of 15 patients had a skin GvHD stage I. 8 (53.3 %) patients suffered from skin GvHD stage II, while 1 (6.67 %) patient experienced acute skin GvHD stage III. The 9 patients with a skin GvHD stage II and III, developed significant increases of IL-6 (P = 0.0010), sIL-2R (P = 0.0049) and TNF-α (P = 0.0020) in the serum, whereas IL-8, IL-10 and IL-1ß did not significantly change. 8 of the 9 patients with skin GvHD stage II and III had an increase in IL-6 a few days before (median 2 days) the appearance of exanthema of the skin. Cytokines sIL-2R and TNF-α increased in all 9 pediatric patients with the appearance of exanthema. The patients with skin GvHD stage I had either no changes in cytokine levels or only an increase of IL-6 (Table 2).

11 (18.0 %) of the 61 patients developed sepsis. 5 (8.2 %) patients had a bacteremia with positive blood cultures. In 21 (34.4 %) out of 61 patients 25 localized bacterial infections were detected over the course of the observation period. Bacterial infections appeared in the urine (n = 11), feces (n = 8), throat (n = 5) and bronchoalveolar lavage (n = 1). In the case of sepsis a significant increase of IL-6 (P = 0.0020), IL-8 (P = 0.0020), sIL-2R (P = 0.0156), and TNF-α (P = 0.0078) was observed in all pediatric patients (n = 8) for which an analysis of the cytokine levels was performed on the day of the occurrence of sepsis. These patients also had a body temperature ≥38.3 °C at that point in time. In the remaining 3 patients that experienced a sepsis, the final analysis of cytokine levels was done more than 24 h prior. Fever was not present at the time blood was taken. There was no change in the analyzed cytokine levels at this time. In all 5 (10.42 %) of the 61 patients diagnosed with bacteremia, a significant increase of IL-6 (P < 0.0001) and IL-8 (P = 0.0006) was observed (Table 3).

8 (13.2 %) of 61 patients had a viremia (Table 3). CMV invasive infection was observed in the blood of 6 patients and an ADV infection was found in the blood of 5 patients. Consequently, both infections occurred in 3 patients. These patients had CMV and ADV infection in the post-transplant period. In all 11 invasive viral infections there was a significant increase of IL-6 (P = 0.0008). These increases occurred at median 3 days (range 1–4 days) prior to positive PCR testing (Table 3).

6 (9.84 %) of the 61 patients experienced fungemia. In one case, a probable invasive fungal infection came about, while 5 cases showed a possible invasive fungal infection. In all 6 cases, there were positive signs of Aspergillus galactomannan antigen in the blood in at least two consecutive samples. No proven invasive fungal infections were observed. No specific cytokine pattern and no significant alterations of IL-1ß, sIL-2R, IL-6, IL-8, IL-10 and TNF-α could be observed in any of these cases (Table 3).

The comparison of IL-1β values for sepsis (1.7 ± 1.21 pg/ml) and bacteremia (0.3 ± 0.27 pg/ml; P = 0.125), sepsis and viremia (0.4 ± 0.39 pg/ml; P = 0.062), sepsis and fungemia (0.3 ± 0.29 pg/ml; P = 0.125), bacteremia and viremia (P = 0.843), bacteremia and fungemia (P = 0.625), and viremia and fungemia (P = 0.875) showed no significance after Bonferroni correction (adjusted α = 0.0083) (Fig. 1).

sIL-2R serum levels during sepsis (5509 ± 2908 U/ml) and bacteremia (1803 ± 1416 U/ml; P = 0.250), sepsis and viremia (1783 ± 1374 U/ml; P = 0.375), bacteremia and viremia (P = 0.983), bacteremia and fungemia (1224 ± 805 U/ml; P = 0.431), and viremia and fungemia (P = 0.695) were not significantly different. There was a significant difference (P = 0.031) between sepsis (5509 ± 2908 U/ml) and fungemia (1224 ± 805 U/ml). However, this was insignificant after Bonferroni correction (adjusted α = 0.0083) (Fig. 2).

A significant decrease (P = 0.002) of IL-6 was found between sepsis (650 ± 989 pg/ml) and bacteremia (39.63 ± 58.58 pg/ml), as well as between sepsis and viremia (17.47 ± 22.40 pg/ml; P = 0.002). There was also a significant difference (P = 0.001) between sepsis and fungemia (24.07 ± 58.85 pg/ml). After Bonferroni correction (adjusted α = 0.0083) the decrease of IL-6 between bacteremia and viremia (P = 0.0094) and between bacteremia and fungemia, (P = 0.0194) was not significant. The comparison of serum IL-6 concentration between viremia and fungemia (P = 0.305) was neither significant (Fig. 3).

There was a significant decrease (P = 0.002) of IL-8 between sepsis (2406 ± 3190 pg/ml) and bacteremia (93.53 ± 168.8 pg/ml), as well as between sepsis and viremia (32.31 ± 46.23 pg/ml; P = 0.002), and between bacteremia and viremia (P = 0.0064). There was a decrease (P = 0.0341) between sepsis and fungemia (47.26 ± 56.93 pg/ml). This was, however, insignificant after Bonferroni correction. The comparison of IL-8 serum concentration between viremia and fungemia (P = 0.161) and between bacteremia and fungemia (P = 0.15), showed no significant changes. Due to the large scattering of the measured values and high maximum values, the standard deviations are often much larger than the mean values (Fig. 4).

A significant decrease (P = 0.005) of IL-10 serum concentration was found between sepsis (32.82 ± 36.91 pg/ml) and viremia (12.60 ± 26.47 pg/ml). All other pairwise comparisons were statistically insignificant. IL-10 serum concentrations in occurrence of sepsis showed no significant changes in comparison to bacteremia (28.12 ± 15.96 pg/ml). The comparison of sepsis with the fungemia (10.59 ± 13.39 pg/ml), also showed no significant change. When comparing viremia and fungemia (P = 0.50), bacteremia and fungemia (P = 0.50) and bacteremia and viremia (P = 0.31), no significant changes in IL-10 serum concentration were found after Bonferroni correction (adjusted α = 0.0083) (Fig. 5).

After Bonferroni correction, there was no significant decrease (P = 0.046) of TNF-α between sepsis (55.42 ± 63.04 pg/ml) and fungemia (13.37 ± 12.60 pg/ml). Sepsis compared to bacteremia (25.95 ± 68.32; P = 0.85) and to viremia (18.88 ± 22.64; P = 0.322) showed no significant changes in TNF-α serum concentrations. Moreover, the comparison of TNF-α concentrations in occurrence of bacteremia in relation to both fungemia (P = 0.614) and viremia (P = 0.884) was not significant. A comparison of the TNF-α concentration between viremia and fungemia also showed no significance (P = 0.091) after Bonferroni correction (adjusted α = 0.0083) (Fig. 6).