Prospective Study on Febrile Batteries in Pediatric Oncohaematological Patients (SuBiTo)
NCT ID: NCT06419426
Last Updated: 2024-05-17
Study Results
Results pending
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
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Recruitment Status
ACTIVE_NOT_RECRUITING
Total Enrollment
2000 participants
Study Classification
OBSERVATIONAL
Study Start Date
2020-04-22
Study Completion Date
2024-12-31
Brief Summary
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The aim of this study is to define prospectively the incidence of multi-resistant germ batteries in paediatric oncoematological patients, to assess associated mortality, antibiotic resistance profile and the type of implemented therapy.
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Detailed Description
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Bacterial infections are the most frequent cause of infectious morbidity and mortality in the patient undergoing chemotherapy or hemopoietic stem cell transplantation (TCSE). The main predisposing factor is the impairment of innate immunity as a result of the alteration of mucous barriers (mucositis/enteritis from chemotherapy or radiotherapy), skin (CVC) and neutropenia (non-specific haematological toxicity due to chemotherapy or radiotherapy on bones with hemopoietic marrow). The most frequent form of infection is represented by fever whose cause remains indeterminate in 60-80% of cases. In about 10-15% of cases fever is accompanied by the positivization of hemoculture and is configured as a microbiologically determined infection (IMD). In the remaining cases, infectious episodes may be clinically documented such as pneumonia or bronchitis confirmed for radiological examination or CT scans, without the identification of the causative agent; these are defined as clinically determined infections (ICDs).
The knowledge, through hemoculture, of the germs responsible for febrile batteries over a given period of time, allows the definition of the predominant typology of germs responsible for systemic infection. On this basis, it is used to define the empirical antibiotic treatment that is given to the patient within a few hours of the onset of fever. Empirical antibiotic therapy must be effective with regard to the germs most represented in the department or in the area in question. Once the result of hemoculture has been received, usually within 48-72 hours, empirical antibiotic therapy can be maintained or modified in relation to the type of isolated germ and its susceptibility to antibiotics included in the empirical scheme. In fact, there is ample evidence that ready-to-treat with broad-spectrum antibiotics reduces mortality from bacterial infection in the immunocompromised patient, so this procedure is now a recommended approach by the guidelines. In addition to the knowledge of prevalent bacterial epidemiology for a certain type of immunocompromised patients in a given geographical area, a second tool capable of allowing appropriate empirical antibiotic therapy is the choice of therapy based on the presence or not of asymptomatic bacterial colonization of the patient. In fact, it is estimated that in 20-30% of cases the colonizing germ can become the cause of a batteriemia, facilitated by favoring factors such as the rupture of skin-mucous reefs or the appearance of neutropenia. The need to start empirical antibiotic therapy with effective molecules against causal germ (appropriate empirical therapy) has been shown to reduce bacterial infectious mortality at a time when antibiotic resistance is gradually increasing. It has been shown that inappropriate empirical antibiotic therapy, based on antibiotics to which the germ is not sensitive, is associated with increased infectious mortality from sepsis and septic shock. Among the adjuvant therapies used in immunosuppressed patients, in addition to antibiotic therapy, especially in patients with septic shock, there is the administration of opsonizing immunoglobulins and able to activate the complement such as, for example, immunoglobulins enriched in IgM. This practice is generally more established in immunocompetent patients while there are no prospective data in immunocompromised patients.
Primary objective Incidence of febrile batteries from antibiotic-resistant gram negative germs (MDR)
Secondary objectives Incidence of batteries from negative Gram germs; Incidence of batteries from gram positive germs; Incidence of fungemie; Incidence of septic shock; Incidence of batteries from colonising germs; Incidence of resistance to the main classes of antibiotics used empirically: cephalosporins of 3 and 4 generation (ceftazidime, cefipime), semisitical penicillins (piperacillin/tazobactam), carbapenemas (meropenem, imipenem), aminoglycosides (aminoglycosides (aikacin), second generation fluorquinolones; Response to empirical antibiotic therapy within 72 hours, without modification of empirical antibiotic therapy and without the use of Pentablobin; Response to empirical antibiotic therapy within 72 hours with the use of Pentaglobin within 72 hours of the onset of fever; Response to empirical antibiotic therapy with modification of the antibiotic (without the addition of antifungal), without the use of Pentaglobin; Response to empirical antibiotic therapy with modification of the antibiotic (without the addition of antifungal), with the use of Pentaglobin; Response of antibiotic therapy with empirical addition of antifungal with or without the use of Pentaglobin; Mortality at 30 days; Mortality at 90 days
Design of the study Prospective, observational, non-interventional study to determine the incidence of febrile batteries from MDR germs in febrile oncohaematological patients.
The study is aimed at the centers belonging to the Italian Society of Pediatric Oncology Hematology (IAEOP). Patients will be enrolled prospectively from the date of activation of the center.
Eligible patients will include patients who develop fever after chemotherapy (either after first diagnosis or relapse) or after hemopoietic stem cell transplantation (TCSE) autologhe or allogenic, managed in ordinary hospitalization, subjected to endovenous antibiotic therapy for at least 72 hours for the treatment of the febrile episode. These patients will be the denominator of the study population. Patients who turn out to have positive hemoculture will represent the cases of the study population. A patient may be enrolled several times in the study both as "denominator/control" (hospitalization and example for several febrile episodes) and as a "case" (second episode of febrile batteriemia). In the latter case, the interval between the conclusion of a febrile episode (stable slibration, negative hemoculture) and the subsequent febrile episode must be at least 7 days. The febrile episodes considered will be only those in ordinary hospitalization (minimum 2 nights of hospitalization) while febrile episodes managed exclusively in day-care (Day-Hospital) or with home, oral or endovenous antibiotic therapy are excluded.
Each participating centre must declare at the opening the standard procedure relating to:
1. Study of colonization: yes, no, method of investigation;
2. Standard antibiotic prophylaxis in acute myeloid leukemia (LLA), acute myeloid leukemia (LMA), non-Hodgkin lymphoma (LNH), allogenic TCSE, autologous TCSE;
3. Standard empirical therapy in non-colonized patient (first 48-72 hours);
4. Use of Pentaglobin (yes/no, criteria for use, dose).
In the study patients, hospitalized by febrile episode in endovenous antibiotic therapy, the following information will be collected: sex, age at the time of the febrile episode, age at diagnosis of the basic disease, type of tumor, stage of treatment in hospitalization, type of transplant, presence or not of transplant disease against the host (only for allogenic transplantation), colonization or not, CVC or not, type of CVC, presence or not of urinary catheter, clinical characteristics of the febrile episode, date onset fever-date end fever, date start-date end of antibiotic therapy, date start-date end antifungal therapy, date start-date end therapy with Pentaglobin, result of haemoculture and antibiogram, number of neutrophils, number of lymphocytes, hypotension (in relation to normal values for age, saturation O2, need or not of hospitalization in intensive care , whether or not fluids are used, ventilatory support, renal replacement therapy, , maximum PCR-value (in the first 72 hours), PCT-value (maximum in the first 72 hours), Galactomanane (maximum value during the episode), β-D glucan (maximum value during the episode), survival at 30 and 90 days, final definition of the infectious episode (FUO, ICD, IMD), and possible toxicity related to antibiotic therapy.
The knowledge, through hemoculture, of the germs responsible for febrile batteries over a given period of time, allows the definition of the predominant typology of germs responsible for systemic infection. On this basis, it is used to define the empirical antibiotic treatment that is given to the patient within a few hours of the onset of fever. Empirical antibiotic therapy must be effective with regard to the germs most represented in the department or in the area in question. Once the result of hemoculture has been received, usually within 48-72 hours, empirical antibiotic therapy can be maintained or modified in relation to the type of isolated germ and its susceptibility to antibiotics included in the empirical scheme. In fact, there is ample evidence that ready-to-treat with broad-spectrum antibiotics reduces mortality from bacterial infection in the immunocompromised patient, so this procedure is now a recommended approach by the guidelines. In addition to the knowledge of prevalent bacterial epidemiology for a certain type of immunocompromised patients in a given geographical area, a second tool capable of allowing appropriate empirical antibiotic therapy is the choice of therapy based on the presence or not of asymptomatic bacterial colonization of the patient. In fact, it is estimated that in 20-30% of cases the colonizing germ can become the cause of a batteriemia, facilitated by favoring factors such as the rupture of skin-mucous reefs or the appearance of neutropenia. The need to start empirical antibiotic therapy with effective molecules against causal germ (appropriate empirical therapy) has been shown to reduce bacterial infectious mortality at a time when antibiotic resistance is gradually increasing. It has been shown that inappropriate empirical antibiotic therapy, based on antibiotics to which the germ is not sensitive, is associated with increased infectious mortality from sepsis and septic shock. Among the adjuvant therapies used in immunosuppressed patients, in addition to antibiotic therapy, especially in patients with septic shock, there is the administration of opsonizing immunoglobulins and able to activate the complement such as, for example, immunoglobulins enriched in IgM. This practice is generally more established in immunocompetent patients while there are no prospective data in immunocompromised patients.
Primary objective Incidence of febrile batteries from antibiotic-resistant gram negative germs (MDR)
Secondary objectives Incidence of batteries from negative Gram germs; Incidence of batteries from gram positive germs; Incidence of fungemie; Incidence of septic shock; Incidence of batteries from colonising germs; Incidence of resistance to the main classes of antibiotics used empirically: cephalosporins of 3 and 4 generation (ceftazidime, cefipime), semisitical penicillins (piperacillin/tazobactam), carbapenemas (meropenem, imipenem), aminoglycosides (aminoglycosides (aikacin), second generation fluorquinolones; Response to empirical antibiotic therapy within 72 hours, without modification of empirical antibiotic therapy and without the use of Pentablobin; Response to empirical antibiotic therapy within 72 hours with the use of Pentaglobin within 72 hours of the onset of fever; Response to empirical antibiotic therapy with modification of the antibiotic (without the addition of antifungal), without the use of Pentaglobin; Response to empirical antibiotic therapy with modification of the antibiotic (without the addition of antifungal), with the use of Pentaglobin; Response of antibiotic therapy with empirical addition of antifungal with or without the use of Pentaglobin; Mortality at 30 days; Mortality at 90 days
Design of the study Prospective, observational, non-interventional study to determine the incidence of febrile batteries from MDR germs in febrile oncohaematological patients.
The study is aimed at the centers belonging to the Italian Society of Pediatric Oncology Hematology (IAEOP). Patients will be enrolled prospectively from the date of activation of the center.
Eligible patients will include patients who develop fever after chemotherapy (either after first diagnosis or relapse) or after hemopoietic stem cell transplantation (TCSE) autologhe or allogenic, managed in ordinary hospitalization, subjected to endovenous antibiotic therapy for at least 72 hours for the treatment of the febrile episode. These patients will be the denominator of the study population. Patients who turn out to have positive hemoculture will represent the cases of the study population. A patient may be enrolled several times in the study both as "denominator/control" (hospitalization and example for several febrile episodes) and as a "case" (second episode of febrile batteriemia). In the latter case, the interval between the conclusion of a febrile episode (stable slibration, negative hemoculture) and the subsequent febrile episode must be at least 7 days. The febrile episodes considered will be only those in ordinary hospitalization (minimum 2 nights of hospitalization) while febrile episodes managed exclusively in day-care (Day-Hospital) or with home, oral or endovenous antibiotic therapy are excluded.
Each participating centre must declare at the opening the standard procedure relating to:
1. Study of colonization: yes, no, method of investigation;
2. Standard antibiotic prophylaxis in acute myeloid leukemia (LLA), acute myeloid leukemia (LMA), non-Hodgkin lymphoma (LNH), allogenic TCSE, autologous TCSE;
3. Standard empirical therapy in non-colonized patient (first 48-72 hours);
4. Use of Pentaglobin (yes/no, criteria for use, dose).
In the study patients, hospitalized by febrile episode in endovenous antibiotic therapy, the following information will be collected: sex, age at the time of the febrile episode, age at diagnosis of the basic disease, type of tumor, stage of treatment in hospitalization, type of transplant, presence or not of transplant disease against the host (only for allogenic transplantation), colonization or not, CVC or not, type of CVC, presence or not of urinary catheter, clinical characteristics of the febrile episode, date onset fever-date end fever, date start-date end of antibiotic therapy, date start-date end antifungal therapy, date start-date end therapy with Pentaglobin, result of haemoculture and antibiogram, number of neutrophils, number of lymphocytes, hypotension (in relation to normal values for age, saturation O2, need or not of hospitalization in intensive care , whether or not fluids are used, ventilatory support, renal replacement therapy, , maximum PCR-value (in the first 72 hours), PCT-value (maximum in the first 72 hours), Galactomanane (maximum value during the episode), β-D glucan (maximum value during the episode), survival at 30 and 90 days, final definition of the infectious episode (FUO, ICD, IMD), and possible toxicity related to antibiotic therapy.
Conditions
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Bacterial Infections
Study Design
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Observational Model Type
OTHER
Study Time Perspective
PROSPECTIVE
Interventions
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Battery incidence
Incidence of batteries from negative Gram germs; Incidence of batteries from gram positive germs; Incidence of fungemie; Incidence of septic shock; Incidence of batteries from colonising germs; Incidence of resistance to the main classes of antibiotics
Intervention Type
OTHER
Eligibility Criteria
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Inclusion Criteria
* written informed consent,- onset of fever after chemotherapy or after hemopoietic stem cell transplantation (TCSE),
* endovenous antibiotic therapy for at least 72 hours for the treatment of the febrile episode.
* ordinary hospitalization scheme
* age \< 18
* endovenous antibiotic therapy for at least 72 hours for the treatment of the febrile episode.
* ordinary hospitalization scheme
* age \< 18
Minimum Eligible Age
1 Month
Maximum Eligible Age
18 Years
Eligible Sex
ALL
Accepts Healthy Volunteers
No
Sponsors
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Associazione Italiana Ematologia Oncologia Pediatrica
OTHER
Sponsor Role
lead
Responsible Party
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Responsibility Role
SPONSOR
Locations
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Azienda Ospedaliera Universitaria Integrata
Verona, Italia, Italy
Site Status
Azienda Ospedali Riuniti Presidio "G. Salesi"
Ancona, , Italy
Site Status
AOU Policlinico
Bari, , Italy
Site Status
Policlinico Sant'Orsola Malpighi Clinica
Bologna, , Italy
Site Status
Ospedale Regionale
Bolzano, , Italy
Site Status
Spedali Civili, Presidio Ospedale Dei Bambini
Brescia, , Italy
Site Status
Ospedale Pediatrico Microcitemico "Antonio Cao", Azienda Ospedaliera Brotzu
Cagliari, , Italy
Site Status
AOU Policlinico Vittorio Emanuele
Catania, , Italy
Site Status
Azienda Ospedaliero Universitaria Sant'Anna
Ferrara, , Italy
Site Status
Azienda Ospedaliero-Universitaria "Anna Meyer"
Florence, , Italy
Site Status
Istituto G.Gaslini
Genova, , Italy
Site Status
Fondazione IRCCS Istituto Nazionale Tumori
Milan, , Italy
Site Status
Azienda Policlinico Di Modena
Modena, , Italy
Site Status
Fondazione MBBM / AO San Gerardo Clinica
Monza, , Italy
Site Status
A.O.R.N. Santobono - Pausilipon
Napoli, , Italy
Site Status
Oncoematologia Pediatrica AOU di Padova
Padua, , Italy
Site Status
ARNAS Civico Di Cristina E Benfratelli
Palermo, , Italy
Site Status
Azienda Ospedaliero Universitaria Di Parma
Parma, , Italy
Site Status
Fondazione IRCCS, Policlinico San Matteo
Pavia, , Italy
Site Status
A.O.U. "S.M. Della Misericordia"
Perugia, , Italy
Site Status
Ospedale Civile Dello Spirito Santo Dipartimento Di Ematologia, Medicina Trasfusionale E Biotecnologie
Pescara, , Italy
Site Status
IRCCS Ospedale Pediatrico Bambino Gesù Dip.to di Oncoematologia e Terapia cellulare e Genica
Roma, , Italy
Site Status
IRCCS Ospedale "Casa Sollievo Della Sofferenza"
San Giovanni Rotondo, , Italy
Site Status
AOU Citta' Della Salute E Della Scienza Di Torino
Torino, , Italy
Site Status
IRCCS Materno Infantile "Burlo Garofolo"
Trieste, , Italy
Site Status
Countries
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Italy
Other Identifiers
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SuBiTO
Identifier Type: -
Identifier Source: org_study_id
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