|Year : 2017 | Volume
| Issue : 1 | Page : 23-27
Noninvasive ventilation in cancer children with acute respiratory failure
Sema Yilmaz1, Riza Dincer Yildizdas2, Oguz Dursun3, Bulent Karapinar4, Tanil Kendirli5, Demet Demirkol6, Agop Citak7, Alphan Kupesiz3, Hakan Tekguc3, Muhterem Duyu4, Pinar Yazici4, Ufuk Yukselmis2, Caglar Odek5, Ayhan Yaman5, Suleyman Bayraktar6, Guntulu Şık7, Fatma Betul Cakir8
1 Department of Pediatric Hematology/Oncology, Faculty of Medicine, Yeditepe University, Istanbul, Turkey
2 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Cukurova University, Adana, Turkey
3 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Akdeniz University, Konyaaltı, Antalya, Turkey
4 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Ege University, Bornova, Izmir, Turkey
5 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Ankara University, Ankara, Turkey
6 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Bezmialem University, Istanbul, Turkey
7 Intensive Care Unit, Department of Pediatric, Faculty of Medicine, Istanbul University, Istanbul, Turkey
8 Department of Pediatric Hematology/Oncology, Faculty of Medicine, Bezmialem University, Istanbul, Turkey
|Date of Web Publication||15-Sep-2017|
Department of Pediatric Hematology/Oncology, Faculty of Medicine, Yeditepe University, Istanbul
Source of Support: None, Conflict of Interest: None
Objective: To establish the effectiveness of noninvasive ventilation in cancer children with acute respiratory failure.
Methods: The data of 33 cancer patients were obtained prospectively from six different pediatric intensive care units in Turkey between the years of 2012 and 2013.
Results: The diagnosis was leukemias in 25 (75.8%), lymphomas in 3 (9.1%) and other solid tumors in 5 (15.1%) patients. Pneumonia in 12 (36.3%) and sepsis in 15 (45.4%) patients were seen as the common reasons of respiratory failure. The mean PaO2/FiO2 ratios were (164.22 ± 37.24) and (126.80 ± 42.73) in noninvasive ventilation success and failure group, respectively. Noninvasive ventilation was successful in 18 (54.5%) patients. The failure group consisted of 15 patients required intubation. A total of 14 (42.4%) patients died. The clinical outcome in terms of success and failure was meaningful statistically (P = 0.0 00 1).
Conclusions: Our results could encourage the use of noninvasive ventilation in children with cancer who develop acute respiratory failure. It should be considered as a useful therapeutic approach to avoid endotracheal intubation
Keywords: Noninvasive ventilation, Respiratory, Children, Cancer
|How to cite this article:|
Yilmaz S, Yildizdas RD, Dursun O, Karapinar B, Kendirli T, Demirkol D, Citak A, Kupesiz A, Tekguc H, Duyu M, Yazici P, Yukselmis U, Odek C, Yaman A, Bayraktar S, Şık G, Cakir FB. Noninvasive ventilation in cancer children with acute respiratory failure. J Acute Dis 2017;6:23-7
|How to cite this URL:|
Yilmaz S, Yildizdas RD, Dursun O, Karapinar B, Kendirli T, Demirkol D, Citak A, Kupesiz A, Tekguc H, Duyu M, Yazici P, Yukselmis U, Odek C, Yaman A, Bayraktar S, Şık G, Cakir FB. Noninvasive ventilation in cancer children with acute respiratory failure. J Acute Dis [serial online] 2017 [cited 2022 Jan 26];6:23-7. Available from: http://www.jadweb.org/text.asp?2017/6/1/23/214609
| 1. Introduction|| |
Noninvasive ventilation (NIV) is a treatment for patients with respiratory dysfunction accomplished by an external interface and a positive pressure ventilator. NIV has been applying increasingly in pediatric patients with acute respiratory failure of various etiologies. Several recent trials have shown major benefits of NIV as a preventive measure during episodes of acute hypoxemic respiratory failure in solid organ transplant patients or patients with severe immunosuppression, particularly related to hematological malignancies and neutropenia. NIV may decrease the risk of life- threatening complications associated with invasive mechanical ventilation in patient with hematologic malignancies. Early initiation of NIV seems necessary to avoid endotracheal intubation and provide benefit to patients.
Few studies were presented about the using of NIV in children diagnosed with cancer. Some of studies had encouraging results in pediatric hematological malignancies. With our study in PICU (Pediatric Intensive Care Unit) setting, the experience of NIV was presented in cancer children with acute pulmonary disease. Our aim was to determine the acceptability of NIV in critically care children with cancer and to evaluate the activity of NIV clinically in these patients.
| 2. Materials and Methods|| |
2.1. Study design and study population
This study is a prospective study conducted in six Turkish university hospitals (Akdeniz, Ege, Bezmialem, Cukurova, Ankara and Istanbul). In the study, 33 patients, aged between 1 and 18 years old, required NIV for acute respiratory failure were admitted to the PICU. The study was approved by the ethics committee of Cukurova University (Document number: 12 and date: 01.03.2012). Written informed consent was given by the parents of patients. We studied the success of NIV in a total population of 33 hematology and oncology patients who were referred to PICUs between April 2012 and June 2013.
For each patient, the following population features such as age, gender, cancer type (hematologic and organ cancers), disease status [active, remission, relapse/refractory or bone marrow transplantation (BMT)] and admission status to PICU (neutropenic or nonneutropenic), PICU length of stay and NIV hours were recorded. Malignancies included acute lymphoid leukemia, acute myeloid leukemia, chronic myeloid leukemia, non-Hodgkin (Burkitt and T-cell) lymphoma and Hodgkin disease, brain tumor, rabdomyosarcoma and neuroblastoma. The below parameters were received before beginning of respiratory assistance at the first PICU admission: measurements of Glasgow's coma score, Pediatric Logistic Organ Dysfunction (PELOD) and Pediatric Risk of Mortality (PRISM) III scores, blood cell count, baseline blood gases, in particular pH, PaO2, PaCO2 and PaO2/FiO2 ratio within the first 24 h of the patient's intensive care unit stay. Leukopenia was defined as a total white blood cell count of < 1.0 × 109 cells/L. The blood gas results was obtained by using of peripheral arterial catheter. The symptoms of respiratory problems described by thorax X-ray, existence of hemodynamic instability (intense sepsis/septic shock) and various organ insufficiency were recorded. various organ insufficiency, intense sepsis/septic shock was identified based on the International Pediatric Sepsis Consensus Conference. The observation of infiltrative area in the thorax X-ray was described as a symptom of pulmonary disease. The infiltration area of lung were classified as < 25%; 25% to 50%; 50% to 75%; and > 75%. The duration of hospitalization (in days) in PICU was also enrolled. The criteria for success or failure during NIV application designated outcome of diseases.
Acute respiratory failure was defined as an acute and rapid deterioration of respiratory function leading to hypoxemia in blood gas tensions as PaO2 < 60 mmHg while breathing air, or a PaCO2 > 50 mmHg. Both clinical condition of the patient and the work of breathing were important factors when deciding of NIV. Patients were selected regardless of the underlying cancer type contributed to respiratory failure. Exclusion criteria were: cardiorespiratory arrest, hemodynamic instability despite vasoactive treatment, Glasgow coma score <8, contraindications to NIV (facial or digestive tract surgery). Patients with NIV after extubation were not included, although it was used as a method of weaning from mechanical ventilation in this study. Also babies below one year old and children who had coagulopathy and major congenital malformations were excluded.
2.2. Applying of NIV
The study group included NIV was identified in children who applied NIV as a primary mechanical ventilation method. NIV was continuously applied for at least 24 h and provided by bilevel pressure ventilation (BIPAP vision; Respironics; Murrysville, PA) or assisted spontaneous breathing (Evita 4; Drager Medical, Telford, PA, USA). Ventilatory mode was oriented an inspiratory pressure support with positive end- expiratory pressure. Bilevel devices were constituted in the spontaneous mode reply to an alteration of phase in inspiratory flow rate with the providing a preset level of positive pressure. The ventilator was not induced in response to flow changes in the timed mode, but at a set rate distributing of intermittent pulses of positive airway pressure. NIV was applied through pressure-support ventilation using a nasal mask (Fisher & Pykel flexiFit Auckland, New Zealand and Respironics comfortful Andover, MA. USA) hold on to a ventilator. Ventilatory masks were provided for the best fit and comfort to the children with cancer. For the patients good collaboration, positive end-expiratory pressure and inspiratory positive airway pressure with a minimal flow were provided. The ventilator settings such as positive end-expiratory pressure between 3 and 8 cm H2O to which inspiratory pressures up to 10 cm H2O were added. After that, positive end-expiratory pressure was step by step raised to regulate oxygenation for achieving oxygen saturation as 90% and a decrease in oxygen demand. An augmentation in ventilation was considered by reducing in pCO2. A well-trained critical care team managed cautiously the patients during NIV.
The application was continuous for the first 6 h and no limit was set on the duration unless failure appeared. NIV was considered to be successful if the patient remained in spontaneous respiration for at least 48 h after the withdrawal of NIV and therefore did not need endotracheal intubation. The major criterion for intubation was defined as a high oxygen necessity as FiO2 > 80% one hour after the beginning of NIV.
2.3. Statistical analysis
Data were tested with descriptive statistical methods (mean values ± SD). In addition, categorical variables were evaluated by the χ2 test. The student's t test (for parametric data) or the Mann–Whitney U test (while not normally distributing of the continuous variables) were used for contrasting of continuous variables, as appropriate. Data were analyzed using number Cruncher statistical system 2007 statistical software (Utah, USA) and P-values P < 0.05 were considered to be statistically significant.
| 3. Results|| |
Between April 2012 and June 2013, 33 patients, 16 (48.5%) boys and 17 (51.5%) girls with mean age (9.54 ± 5.67) years old, were assigned to NIV. Information of potentially eligible patients who were admitted was only obtained from six centers during the study period. The diagnosis was leukemia in 25 (75.8%), lymphoma in 3 (9.1%) and solid tumor in 5 (15.1%) patients. A total of 15 (45.5%) patients had active disease (first diagnosed disease or continuing therapy), 1 (3%) in complete remission and 14 (42.4%) was in relapse. Pneumonia in 12 (36.3%) and sepsis in 15 (45.5%) patients were seen as the common reasons for acute respiratory failure. The applying of NIV was successful in 18 (54.5%) patients. The breakdown on the number of NIV successful/failure cases (15) were recorded in different centers (Akdeniz 7/5, Ege 4/4, Bezmialem 3/1, Cukurova 2/3, Ankara 1/1 and Istanbul 1/1), respectively. The characteristics of patients at enrollment were listed in [Table 1].
[Table 2] presents blood gas analysis and vital data (Respiratory rate, heart rate, PRISM, PELOD and Glasgow coma score) at PICU admission in NIV success and failure group. PaO2/FiO2 ratio was calculated at the first admission. The mean PaO2/FiO2 ratios were (164.22 ± 37.24) and (126.80 ± 42.73) in NIV success and failure group, respectively. The difference was significant statistically (P = 0.011). While the median length of PICU stay was (6.65 ± 4.36) in NIV succsess group, (15.32 ± 46.21) days were seen in NIV failure group. There was no significant difference statistically between two group (P = 0.777). The mean duration of NIV was (52.46 ± 44.31) and (55.82 ± 56.72) h in patients who were success and failure group, respectively. No statistically significant differences were found for NIV hours in patients who were successful and failure (P = 0.624).
Gender and type of underlying malignancy had no significance in between success and failure group. Disease status referred active, remission, relapse/refractory and BMT showed prominent difference between in NIV success and failure group (P = 0.016). At the PICU, 8 (44.44%) patients were neutropenic. Although NIV was unsuccessful in these patients than that of nonneutropenic, no prominent significance was seen (P = 0.373). Septic shock had an effect on NIV, distinctly (P = 0.027) and the failure group showed increased rate. Steroid use were stated for the success and failure group (seven success and twelve failures in children who applied NIV). Statistically significant difference was found in both group (P = 0.017), but not inotropic and granulocyte colony stimulating factor use. [Table 3] shows intensive care unit and outcome in whole cancer children and NIV group (success and failure group of NIV).
The NIV failure patients who indicated intubation were fifteen. Refractory hypoxemia as the primary diagnosis closely anticipated the need for endotracheal intubation. A total of 33 patients of 14 (42.4%) were applied invasive ventilation and they died. The clinical outcome in terms of NIV success and failure was different statistically (P = 0.000 1) [Table 3].
| 4. Discussion|| |
Although the role of NIV is not well defined in pediatric-age patients with acute respiratory distress, it is increasingly being applied safely in children. The success rate of NIV was found as 74.2% in previous studies. Dohna-Schwake et al. presented that NIV had a valuable impact in children with acute pulmonary insufficiency and 38% of patients practised NIV were found as failure in their study. We found the success rate of NIV as 54.5% in children affected by acute respiratory distress. We believed that most patients diagnosed neutropenic, sepsis and severe septic shock were successful in our study. In one study performed by Lum et al. pediatric patients had 76% success result. Along with these studies, the results emerged from our study motivated the applying of NIV in cancer children who diagnosed acute pulmonary problem to be necessary ventilation.
In the present study, the underlying malignancy type did not associated with NIV success or failure. One study presented that organ cancers were determinant evident for NIV failure in critically care children. Since chemotherapeutic agents used for malignancies can lead to the tissue damage, pulmonary problems likely may occur. Because of small sample size, our investigation could lead to not statistically significant result. Depuydt et al. showed that patients with relapse/refractory status had bone marrow insufficiency due to extensive chemotherapy. In addition, it was reported that patients with hematologic cancers also had the same risk. The status of the disease had an effect on NIV success in the present study. While 9 of 14 patients with relapse/refractory were failure, that of 12 with active disease had success during the applying of NIV. An immunosupression caused by an intensive chemotherapy could cause to NIV failure in relapse/refractory patients.
The usefulness of NIV has been widely demonstrated in immunocompromised adults,,,. While requiring of mechanical ventilation for the pulmonary disease, particularly immunosuppressed patients generally came face to face miserable outcome. It was presented by Fuchs et al. that 27% of immunosuppressed children responded to NIV. The survival rate in neutropenic children was 42.1% in our investigation. Several recent trials have shown major benefits of NIV as a preventive measure during episodes of acute hypoxaemic respiratory failure in solid organ transplant patients or patients with severe immunosuppression, particularly related to hematological malignancies and neutropenia. Even though neutropenic patients [17/33 (51.5%)] with acute respiratory failure showed no meaningful outcome in our NIV practice, that of few [8/17 (47%)] with NIV conducted in a successful manner in PICU. In collaboration with these data, cancer children may have benefit from NIV during the immunosuppression period.
NIV was mainly used for the treatment of patients with acute severe hypoxic failure. The lower initial oxygen requirement expressed by the PaO2/FiO2 ratio was reported in patients with NIV. In one study, patients who practiced successful NIV had prominent oxygenation recovery in the course of NIV application at first hour. Even though there wasn't a statistically significant level, the distinction of increased PaO2/FiO2 ratio was seen in all treatment period.
Our findings also indicate that considerably improved PaO2/FiO2 was recorded during the first hour in NIV success group. Munoz- Bonet et al. pointed that the using of NIV was possible; therefore NIV can lead to avoid an endo-tracheal intubation in children. Invasive mechanical ventilation in patient with cancer may increase the risk of life-threatening complications. The length of hospital stay and mechanical ventilation are important risk factors for development of ventilator-associated pneumonia in adult cancer patients. Accordingly, it could be concluded that early initiation of NIV seemed necessary to avoid the possible risks of endo-tracheal intubation and provided benefit to patients. However, we need to verify these findings in a prospective controlled study in children with cancer.
Previous studies were associated with sustained improvement of reduction in PICU length of stay in patients applied NIV,,,,. Although the meaningful relationship was not established in our study, the mean duration of hospitalization was much longer in NIV failure group than that of success group in PICU. Other studies also support these data. Other investigation performed by Piastra. et al pointed that children with NIV had shorter period of hospitalization and PICU. Also the success of NIV reduced NIV hours as well as the length of PICU stay in children with cancer in the present study. It could be thought that NIV provided short PICU stay and NIV duration in cancer children.
Pancera et al. reported that the majority of patients with worse hemodynamic status were NIV failure. A recent prospective study stated that mortality rates can be reduced in pediatric patients with NIV. In comparison to the others, the mortality rate (93.33%) was high among patients with hemodynamic instability in our NIV failure group. As can be observed from our patient characteristics, septic shock was associated with NIV failure. Almost all patients used inotropic agent. Once again, it seems therefore likely that an important finding in our analysis was to diagnose acute respiratory failure early and NIV application should be done without delay. Depuydt et al. reported that a majority of patients required immediate endotracheal intubation as well as vasopressor therapy because of circulatory shock. In one study, when patients with circulatory shock arrived in an advanced stage of respiratory failure, a reduced potential benefit of NIV was reported. Although we believed that NIV failure could be seen in cancer patients who had severe hemodynamic status, the similar vital data and severity scores of all patients could be incapable for presenting of NIV success in our small population. Much comprehensive investigation should be performed in terms of clarifying the beneficence of NIV for cancer children.
The present study had some limitations. Our investigation lacked a control arm. Other an important limitation was the decision of ventilation type planned by the patients' physician according to severe respiratory failure. The respiratory predictive factors of clinical features could not be used in our study as well. Therefore, large multicenter controlled study should be warranted to predict outcomes more reliably.
In conclusion, NIV should be considered a favorable treatment approach to abstain from endotracheal intubation while ameliorating of cancer children who suffering from acute pulmonary problem indicating the ventilation type. The requirement of intubation could be decreased in children with NIV. In spite of few sample, it is conceivable the regarding of NIV in children diagnosed with malignancy. Our experience also suggests that NIV should not be postponed. Large pediatric studies are required to reveal the usefulness of NIV and who will benefit from NIV in the future.
Conflict of interest statement
The authors report no conflict of interest.
| References|| |
Demaret P, Mulder A, Loeckx I, Trippaerts M, Lebrun F. Noninvasive ventilation is useful in paediatric intensive care units if children are appropriately selected and carefully monitored. Acta Paediatr
Bello G, De Pascale G, Antonelli M. Noninvasive ventilation for the immunocompromised patient: always appropriate? Curr Opin Crit Care
Piastra M, De Luca D, Pietrini D, Pulitanò S, D'Arrigo S, Mancino A, et al. Noninvasive pressure-support ventilation in immunocompromised children with ARDS: a feasibility study. Intensive Care Med
Workman JK, Ames SG, Reeder RW, Korgenski EK, Masotti SM, Bratton SL, et al. Treatment of pediatric septic shock with the surviving sepsis campaign guidelines and PICU patient outcomes. Pediatr Crit Care Med
Abadesso C, Nunes P, Silvestre C, Matias E, Loureiro H, Almeida H. Non-invasive ventilation in acute respiratory failure in children. Pediatr Rep
Pancera CF, Hayashi M, Fregnani JH, Negri EM, Deheinzelin D, de Camargo B. Noninvasive ventilation in immunocompromised pediatric patients: eight years of experience in a pediatric oncology intensive care unit. J Pediatr Hematol Oncol
Dohna-Schwake C, Stehling F, Tschiedel E, Wallot M, Mellies U. Non-invasive ventilation on a pediatric intensive care unit: feasibility, efficacy, and predictors of success. Pediatr Pulmonol
Lum LC, Abdel-Latif ME, de Bruyne JA, Nathan AM, Gan CS. Noninvasive ventilation in a tertiary pediatric intensive care unit in a middle-income country. Pediatr Crit Care Med
(1): e7- 13.
Depuydt PO, Benoit DD, Vandewoude KH, Decruyenaere JM, Colardyn FA. Outcome in noninvasively and invasively ventilated hematologic patients with acute respiratory failure. Chest
Najaf-Zadeh A, Leclerc F. Noninvasive positive pressure ventilation for acute respiratory failure in children: a concise review. Ann Intensive Care
Conti G, Costa R, Antonelli M. Non invasive ventilation in immunocompromised patients. Minerva Anestesiol
Gristina GR, Antonelli M, Conti G, Ciarlone A, Rogante S, Rossi C, et al. Noninvasive versus invasive ventilation for acute respiratory failure in patients with hematologic malignancies: a 5-year multicenter observational survey. Crit Care Med
Fuchs H, Schoss J, Mendler MR, Lindner W, Hopfner R, Schulz A, et al. The cause of acute respiratory failure predicts the outcome of noninvasive ventilation in immunocompromised children. Klin Padiatr
Brochard L. Mechanical ventilation: invasive versus noninvasive. Eur Respir J Suppl
Munoz-Bonet JI, Flor-Macian EM, Rosello PM, Llopis MC, Lizondo A, Lopez-Prats JL, et al. Noninvasive ventilation in pediatric acute respiratory failure by means of a conventional volumetric ventilator. World J Pediatr
Park SA, Cho SS, Kwak GJ. Factors influencing ventilator- associated pneumonia in cancer patients. Asian Pac J Cancer Prev
Wang T, Zhang L, Luo K, He J, Ma Y, Li Z, et al. Noninvasive versus invasive mechanical ventilation for immunocompromised patients with acute respiratory failure: a systematic review and meta-analysis. BMC Pulm Med
Mayordomo-Colunga J, Medina A, Rey C, Diaz JJ, Concha A, Los Arcos M, et al. Predictive factors of non invasive ventilation failure in critically ill children: a prospective epidemiological study. Intensive Care Med
Chawla R, Mansuriya J, Modi N, Pandey A, Juneja D, Chawla A, et al. Acute respiratory distress syndrome: predictors of noninvasive ventilation failure and intensive care unit mortality in clinical practice. J Crit Care
[Table 1], [Table 2], [Table 3]