Lung Transplant Rejection
Conditions
Keywords
induction therapy, photopheresis
Brief summary
Background/Rationale Acute rejection (AR) is common in the first year after lung transplantation. AR has usually been reversible with treatment, but it can trigger chronic rejection that is the leading causes of late morbidity and mortality. Extracorporeal photopheresis (ECP) has emerged as a promising treatment for chronic rejection. The investigators postulate that the immunoregulatory property of ECP could promote graft tolerance immediately after lung transplantation. Objectives The aim of this trial is to evaluate the safety and efficacy of ECP as induction therapy for prevention of AR in recipients affected with cystic fibrosis in the first year after lung transplantation. The extracellular vesicles in the cell-to-cell communication and immunomodulation will be also investigated. Preliminary results (personal) A preliminary study, conducted in Vienna, demonstrated that 9 patients treated with ECP as induction therapy had 0% of chronic rejection versus 50% in the control group. The Institution hosting the current project is among largest lung transplantation centers in Italy with high rate of cystic fibrosis recipients. The Institution has experience in ECP and a dedicated instrument was specifically bought for the project. Internal collaborators have strong expertise in biological aspects including the extracellular vesicle compartment.
Detailed description
The aim of this pilot trial is evaluate the efficacy and safety of ECP as induction therapy for prevention of AR in recipients affected of cystic fibrosis in the first year after lung transplantation. The investigators postulate that ECP could induce graft immunotolerance avoiding the development of chronic rejection. Exposing T-cells to ultraviolet light results in DNA damage and apoptosis; such form of cell death does not typically stimulate a prolonged inflammatory cascade. When re-infused to the patient, apoptotic T-cells are surrounded by antigen presenting cells (APCs). The large number of APCs encircling the damaged T-cells limits the inflammatory response and stimulates specific signalling cascades in APCs that result in anti-inflammatory cytokine production; finally, immature dendritic cells could gain tolerogenic phenotypes. Based on this process, a theory postulates that the immuno-modulation secondary to ECP is related to a general increase in regulatory T-cells that cause a down-regulation of immune responses involved in chronic rejection onset. Another theory assumes that suppressor T-cells may acquire anti-clonal immunity prompted by the APCs; therefore, a sort of T-cell vaccination is the result of leukocyte apoptosis. The intention is to use this T-cell regulation to induce immunotolerance toward the graft before the development of chronic rejection, in spite to operate when the damage is in progress. To activate this effect from the first hours after transplantation, it can be useful the immunomodulatory activity of extracorporeal photopheresis, already established by clinical studies applied to the treatment of acute and chronic rejection. The efficacy of ECP as induction therapy will be measured with the identification of AR rate in the study group versus the control group. AR is diagnosed with trans-bronchial biopsy and graded using standard histological criteria: A0 (none), A1 (minimal), A2 (mild), A3 (moderate) or A4 (severe). A stable 10% decrease of forced expiratory volume in 1 second (FEV1) on baseline will be considered as AR even though trans-bronchial biopsy is not available. In addition, lymphocyte immunophenotype (with particular regard to CD4 + and CD25 +), the cytokine profile (interleukine (IL) 4, IL-10, IL-12 measured by High Resolution Cytokines Array) and the extracellular vesicles content are tested to assess the therapeutic response. Finally, anti-HLA antibodies are tested to understand their dynamics. The ECP safety is assessed by recording every adverse effect with specific attention to opportunistic infections. In conclusion, this study aims to verify whether the induction therapy with ECP can dramatically decrease the rate of acute rejection in order to impact positively on the main cause of mortality in lung transplantation: the chronic rejection.
Interventions
DEVICEphotopheresis
• Treated group will receive ECP with Therakos online system. Each session consists in 1 treatment for 2 consecutive days. First session stars within 72 hours after transplantation followed by a session weekly for 3 time and 2 sessions for the next 2 months (6 sessions = 12 treatment)
Sponsors
Italian Cystic Fibrosis Research Foundation
Fondazione IRCCS Ca' Granda, Ospedale Maggiore Policlinico
Study design
Allocation
RANDOMIZED
Intervention model
PARALLEL
Primary purpose
PREVENTION
Masking
DOUBLE (Investigator, Outcomes Assessor)
Intervention model description
Pilot study, single center, randomized controlled trial, single blind, 2 parallel arms
Eligibility
Sex/Gender
ALL
Healthy volunteers
No
Inclusion criteria
* Patients with CF undergoing first lung transplantation * Male or female * Any ethnicity * Patients must have a body weight more than 40 kg * Patients must have a platelet count more than 20.000/cmm * Patients must be willing of understanding the purpose and risks of the study and must sign a statement of informed consent * Patients transplanted in the first year from the study beginning.
Exclusion criteria
* Previous organ transplantation * Women who are pregnant and/or lactating * Patients with hypersensitivity or allergy to both heparin and citrate products * Patients who are unable to tolerate extracorporeal volume shifts associated with ECP treatment due to the presence of any of the following conditions:uncompensated congestive heart failure, pulmonary edema, renal failure or hepatic failure * Patients who are transplanted following the Italian criteria for emergency transplantation. * Patients who stay more than 72 hours in ICU
Design outcomes
Primary
| Measure | Time frame | Description |
|---|---|---|
| Acute Rejection (measure: number of events) | 36 months | The diagnosis of acute rejection is done by transbronchial biopsy which are classified according the International Society of Heart and Lung Transplantation (ISHLT) grading. In alternative, the diagnosis of acute rejection is done by presence of one of the following clinical or radiological findings: reproducible decrease in lung function (FEV1), hypoxemia (pO2 \< 60mmHg, Sao2\< 90%), pulmonary infiltrates, pleural effusions or dyspnea without evidence of infection |
Secondary
| Measure | Time frame | Description |
|---|---|---|
| overall survival | 12 months | The overall survival will be registered in the first year after lung transplant. It will be reported as months to death and the cause of death |
| cumulative immunosuppressive therapy (measure: mg) | 12 months after transplant | cumulative doses of Tacrolimus, azathioprine (AZT) and corticosteroids at 12 months |
| total hospitalization days after discharge (measure: days) | at 6 months and 12 months after primary discharge | The average number of days spent in the hospital during the first year after transplant |
| freedom from chronic lung allograft disease (measure: months) | 12 months | The efficacy of ECP as induction therapy will be measured with the identification of AR rate in the study group versus the control group. AR is diagnosed with trans-bronchial biopsy and graded using standard histological criteria: A0 (none), A1 (minimal), A2 (mild), A3 (moderate) or A4 (severe). A stable 10% decrease of forced expiratory volume in 1 second (FEV1) on baseline will be considered as AR even though trans-bronchial biopsy is not available |
| Infections from cytomegalovirus (CMV), bacteria, fungi, non-CMV virus, tuberculosis, parasitic (measure: number of events) | 12 months | Bronchoscopy with microbiologic, bacteriology, mycology, virology, parasitology and tuberculosis investigation will be performed |
| lymphocyte immunophenotype (measure: pg/ml) by cluster of differentiation (CD) | At time zero and 48 hours after the end of each sessions of two ECP treatments peripheral blood samples will be collected | lymphocyte immunophenotype (CD45, CD3, CD19, CD14, CD56/16, CD4, CD8, HLA-DR (human leukocyte antigen D Related), CD16, CD25, CD127, CD11c, Annexin/PI) |
| cytokine profile of interleukyn (IL) (number/mmc; percentage) | At time zero and 48 hours after the end of each sessions of two ECP treatments peripheral blood samples will be collected | the cytokine profile (IL-4, IL-10, IL-12 measured by High Resolution Cytokines Array) are tested to assess the therapeutic response. |
| extracellular vesicles content (measure: number/ml) | At time zero and 48 hours after the end of each sessions of two ECP treatments peripheral blood samples will be collected | extracellular vesicles are important mediators of intercellular communication, being involved in the transmission of biological signals between cells. Number, membrane antigens, mRNA (messenger of ribonucleic acid) and protein content are tested. We use nanoparticle tracking analysis for the testing |
| anti-HLA antibodies profile (measure: µmg/ml) | At time zero, after 7 days of the end of each cycle of treatment, at 3, 6 months and one year after transplantation | the anti-HLA antibodies will be tested by Luminex methodology |
| side effects of ECP (measure: number of events) | 3 months after the latest treatment with ECP | The ECP safety is assessed by recording every adverse effect with specific attention to opportunistic infections |
Countries
Italy
Contacts
Primary Contactmario nosotti, MD
Backup Contactilaria righi
Outcome results
None listed