Advanced Therapies for Liver Metastases

Recruiting

• Conditions: Pancreatic Ductal Adenocarcinoma (PDAC); Colorectal Cancer (CRC); Liver Metastasis

• Registration Number: NCT04622423
• Lead Sponsor: IRCCS San Raffaele

Brief Summary

Liver metastases (MTS) are the main cause of death for patients affected by colorectal carcinoma (CRC) and pancreatic ductal adenocarcinoma (PDAC), thus representing the major unmet clinical need for these malignancies.

Based on preliminary and published data, the investigators hypothesize that innovative immune, gene and cell therapy approaches might overcome the tolerogenic liver microenvironment and represent powerful therapeutic tools for liver MTS of PDAC and CRC.

The investigators have therefore planned an observational clinical study to enroll distinct cohorts of patients (i.e., metastatic CRC, metastatic and non-metastatic PDAC) and finely characterize, through integrated state-of-the-art -omics, the immune and non-immune microenvironment of their primary tumor and/or liver metastases as well as correlate changes in the activation status and phenotype of peripheral blood leukocytes. Healthy volunteers will be enrolled as negative controls.

The investigators aim at identifying: i) actionable tumor associated antigens (TAAs) and local immune suppressive and regulatory pathways; ii) biological parameters for early diagnosis of relapse; iii) the effect of therapies on the shaping of anti-tumor immune responses.

Data collected will be instrumental for the generation of novel advanced therapy medicinal products (ATMPs). Indeed, this protocol is part of a multi-partner translational program, supported by the AIRC 5 per Mille 2019 grant, focused on the development, validation and implementation for clinical testing of ATMPs to ameliorate the cure of CRC and PDAC and possibly help the study of other solid tumors.

Moreover, the systematic and long-term follow-up of enrolled patients will possibly point at early predictors of differential prognosis and patients' categories eligible for tailored therapies, including those with the novel ATMPs.

Detailed Description

Background and rationale - CRC and PDAC are the second and fourth most common cause of cancer death, respectively. Patients affected by these cancers die of liver MTS. Conventional therapies are active in either primary tumors but fail in metastatic disease. The effectiveness of immunotherapy by immune checkpoint blockade and adoptive cell therapy with tumor-specific T cells is only partial or temporary in MTS from solid tumors, because of local immunosuppressive mechanisms. This is particularly relevant for hepatic MTS, in which a natural tolerogenic milieu may further sustain immunosuppression induced by cancer cells and infiltrating immune cells, such as tumor associated macrophages (TAMs), myeloid-derived suppressor cells (MDSCs), neutrophils, and regulatory T or B cells.

In this regard, evidence suggests that progression of primary or metastatic CRC correlates with poor immune infiltration and inflammation. Moreover, our published results in primary PDAC support a correlation between tumor progression and a strong type 2 anti-inflammatory/immunosuppressive signature. Efficacy of chemotherapy is known to rely also on reactivation and/or repolarization of tumor targeting immune responses. Pre-surgical chemotherapy may induce beneficial effects and potentially targetable changes in the immune profile of CRC or PDAC MTS.

The investigators hypothesize that a combination of: i) direct cancer cell killing by adoptively transferred tumor-specific T cells and ii) indirect control of tumor progression via reprogramming of the tumor microenvironment would control hepatic MTS of CRC and PDAC.

Thus the investigators propose a thorough characterization of the metastatic milieu in these two cancer types to rationally shape, on the basis of similarities and differences, innovative ATMPs.

Experimental results obtained from biological samples will be correlated: i) with clinical data from patients at the time of enrollment and along their follow-up; and ii) for a subgroup of patients, with biochemical and immunological data from peripheral blood samples routinely collected as a part of their clinical follow-up, with the additional aim to identify novel biologic parameters and/or signatures to help the stratification of patients and the tailoring of treatments.

Objectives - The investigators want to study:

1. the tumor mutational burden and the composition of the metastatic tumor microenvironment in the liver;

2. the inhibitory pathways that constrain immunity in liver MTS;

3. the antigenic and clonal breadth of anti-tumor T cell responses;

4. the spatial-temporal variations of effector and regulatory immune cells upon therapy;

5. the characteristics of tumor cells and their microenvironment in liver MTS versus (vs) primary tumor;

6. the longitudinal variations of clinical parameters as well as blood-derived biological and immunological markers during the medical follow-up of patients.

7. Moreover, they want to collect and biobank patients'samples to support the validation and selection of the newl ATMPs developed by the other partners of the translational program.

The primary objectives will be:

1. to identify immune suppressive/exhaustion pathways

2. to develop a library of tumor-specific TCR (N≥5/tumor type) and identify new CAR targets (N≥1/tumor type) in CRC and PDAC MTS

Study design - This clinical protocol aims at deeply characterizing MTS tumor cells and their microenvironment, including possibly informative dynamic modifications from pro-tumor to anti-tumor profiles that may follow chemotherapy, which is administered pre-surgery (neo-adjuvant) to a substantial fraction of patients. PDAC and CRC MTS patients will be therefore characterized by either cross-sectional or longitudinal investigations on chemotherapy-naïve vs -treated patients.

In addition, the investigators aim at comparing hepatic MTS with primary tumor, in order to highlight dynamic qualitative modifications in cancer cells, immune infiltrates and not-immune microenvironment that could facilitate disease progression toward metastatic spread. These modifications may offer a window of opportunity for the optimal application of our ATMPs. To this purpose, primary non-metastatic PDAC patients undergoing surgical resection will be enrolled in this study and followed-up for monitoring the development of metachronous liver MTS, that, whenever possible, will be characterized and compared to their matched/not matched, previously collected, primary tumor samples. Peripheral blood samples at the time of liver MTS diagnosis will be also collected and analyzed. Also, in those CRC MTS patients undergoing synchronous resection of primary CRC and hepatic MTS, comparative analyses will be carried out on tumor from both sites, allowing intra- and inter-patient profiling of both tumor niches.

Moreover, results from multi-level research analyses will be correlated with clinical data collected from all patients at the time of enrollment in the study and during their clinical follow-up, whenever possible for up to 2 years, considering PDAC patients, and 3 years, considering CRC.

In particular, for metastatic CRC patients, the clinical follow-up will be associated with concurrent collection of blood samples at serial timepoints, that will be prospectively biobanked for further analyses aimed at: i) studying biological and immunological correlates of the patient's clinical status; ii) evaluating key discriminants previously identified in blood samples analyzed at the time of liver MTS surgery, to serve as early predictors of liver progression or recurrence and possibly as indicators for therapeutic stratification.

The investigators expect to collect tissue/blood samples and clinical data from at least:

* 200 metastatic CRC patients (either synchronous or metachronous);

* 150 non-metastatic PDAC patients;

* 75 synchronous PDAC MTS patients and about 20 metachronous PDAC MTS patients, the latter originally enrolled as primary non-metastatic patients for the longitudinal study, for a total of 95 metastatic PDAC patients;

* 30 healthy volunteers, as negative controls.

Different biological samples (peripheral blood, primary and/or metastatic tumor tissue, portal blood) will be collected, in the course of the standard diagnostic and therapeutic care of those patients, and will be in part directly analyzed and in part biobanked for further studies. In parallel, clinical data will be collected from patients at the time of enrollment in the study and, whenever possible, for a follow-up period of up to 2 years, for PDAC patients, and 3 years, for CRC patients.

The statistical analysis of collected data will be performed throughout the clinical study, starting 6 months after the enrollment of the first patient until 6 months after the end of patients' follow-up, for a total of 7 years. The study will last 7 years.

Different biological samples (peripheral blood, primary and/or metastatic tumor tissue, portal blood) will be collected, in the course of the standard diagnostic and therapeutic care of those patients, and will be in part directly analyzed and in part biobanked for further studies. In parallel, clinical data will be collected from patients since the time of enrollment in the study for a follow-up period of 2 years, for PDAC patients, and of 3 years, for CRC patients.

The statistical analysis of the collected clinical and experimental data will be carried out all along the duration of the clinical study, starting 6 months after the enrollment of the first patient until the end of patients' follow-up, for a total of 7 years. The study will last 7 years.

The research activities will be organized and integrated in 6 work packages (WPs):

1. Collection and biobanking of the material from patients with CRC and PDAC MTS to the liver and with primary non-metastatic resectable PDAC.

2. Definition of the tumor mutational burden, epigenetic and gene expression profile of the CRC and PDAC metastatic liver at bulk and at single cell level.

3. Evaluation of the molecular and cellular composition of CRC and, if possible, PDAC liver MTS by spatial transcriptomics technologies (NICHE-seq and Visium).

4. Characterization of the immune landscapes of CRC and, if possible, PDAC liver MTS by high dimensional flow cytometry.

5. Validation of the molecular results obtained in 2) and 4).

6. Definition of the antigenic landscape and TCR repertoire of CRC and PDAC liver MTS.

The results obtained by the above mentioned WPs will be crossed with clinical follow-up data and serve to calibrate the program activities focused on novel ATMPs development.

Study Timeline

• Study Start: 2019-11-06
• Study First Submitted: 2020-11-04
• Study First Submitted QC: 2020-11-04
• Study First Posted: 2020-11-10
• Status Verified: 2024-09
• Last Update Submitted: 2024-09-30
• Last Update Posted: 2024-10-01
• Primary Completion: 2026-06-30
• Study Completion: 2026-06-30

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 475

Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Primary Outcome Measures

Name	Time	Method
Definition of tumor mutational burden, epigenetic and gene expression profile of the CRC and PDAC metastatic liver at bulk and at single cell level	After liver metastasis/primary tumor resection/biopsy, usually within 12 months	CRC/PDAC MTS samples will be analyzed by: * Whole exome DNA sequencing; * RNA sequencing; * ATAC sequencing; * Single cell RNA sequencing on sorted myelomonocytic and T cells infiltrating CRC/PDAC MTS samples.; Naive vs chemotherapy treated lesions as well as primary vs MTS lesions will be compared to evaluate chemotherapy-induced modifications and the molecular evolution in the distinct tumor sites, respectively.
Characterization of the immune landscapes of CRC and, if possible, PDAC liver MTS by high dimensional flow cytometry	For tissue specimens: immediately after tumor tissue resection/biopsy (analyses on fresh samples); for blood specimens: after blood drawing, usually within 12 months (analyses on fresh and/or thawed samples)	Single cell suspension of CRC and PDAC MTS and paired autologous PBMCs and portal blood harvested before and after pre-operatory chemotherapy, will be analyzed by a series of parallel polychromatic high dimensional 28 color flow cytometry panels to study: * Conventional MHC-restricted Tab cells, the main anti-tumor effectors; * Innate-like T cells; * B cells; * Myelomonocytic populations involved in the stimulation or suppression of anti-tumor responses.; Whenever available, matched primary vs MTS lesions will be compared to evaluate the immune landscapes in the distinct tumor sites.
Histological validation of the molecular results obtained in 1. and 2.	After liver metastasis/primary tumor resection/biopsy, usually within 12 months	Validation of relevant markers and molecular pathways in terms of anatomical distribution, performed by polychromatic immunofluorence (IF, up to 6 colors) and immunohistochemistry (IHC, up to 4 colors) stainings on MTS CRC and PDAC biopsies, perilesional parenchyma and, whenever available, matched primary tumor samples. In addition to multiplex IF and IHC, some specimens will be characterized more deeply with advanced spatial proteomics technologies, such as GeoMx Digital Spatial Profiler (Nanostring).
Definition of the antigenic landscape and TCR repertoire of CRC and PDAC liver MTS	After liver metastasis/primary tumor resection/biopsy, usually within 12 months	Identification of tumor-reactive TCRs will be pursued through different and complementary strategies: * The most relevant inhibitory checkpoint genes/pathways expressed by MTS-TILs will be used to enrich for tumor specificities by cell sorting harvested from CRC/PDAC MTS tumors, portal, hepatic and peripheral blood sample. After their activation, responding T cell cultures will be subject to bulk and single-cell TCR seq; * In samples characterized by a low percentage of MTS-TILs, single cell immune profiling will be performed in order to simultaneously determine gene expression and correctly pair chain TCR sequences from individual T cells; * The library of tumor-specific TCRs identified will be transiently expressed in reporter Jurkat cells to confirm their tumor antigen specificity; * Identification and functional validation of transmembrane molecules enriched in cancer cells as possible targets for CAR design.

Secondary Outcome Measures

Name	Time	Method
Collection of clinical follow-up data	CRC patients: throughout the postoperative follow-up, for a maximum of 36 months; PDAC patients: throughout the postoperative follow-up, for a maximum of 24 months	Overall survival (OS), disease free survival (DFS) and other follow-up parameters (patient's status, CEA levels, Ca 19-9 levels, adjuvant chemotherapy after surgery, date and site of recurrence, treatment at recurrence) will be collected and possibly correlated with the markers and pathways identified and validated in primary outcome measures.
Evaluation of the molecular and cellular composition of CRC and, if possible, PDAC liver MTS by spatial transcriptomics technologies (NICHE-seq and Visium)	After liver metastasis/primary tumor resection/biopsy, usually within 12 months	Application of NICHE-seq to freshly isolated human tissues using photoactivatable (cages) fluorophores able to permeate within the cells, in particular comparing ≥5 chemotherapy treated vs ≥5 naive CRC MTS samples and ≥3 PDAC MTS samples in order elucidate the high-order spatial organization of immune cell types in the NICHE-seq area and their molecular pathways, at the same time. NICHE-seq and conventional single-cell RNA seq will proceed side-by-side to compare results. Some selected specimens will be analyzed with more advanced spatial transcriptomics techniques developed in recent years, like Visium Spatial Gene Expression (10X Genomics).
Biobanking of biospecimens collected from CRC and PDAC patients and from healthy donors	Throughout the protocol (7 years)	* blood samples as detailed in the "biospecimen description" section: cryopreservation in liquid nitrogen of whole blood, plasma and purified mononuclear cells.; * tissue samples as detailed in the "biospecimen description" section: i) formalin-fixation and paraffin embedding; ii) OCT-based embedding and cryopreservation in liquid nitrogen.; Biobanked samples will be studied as described in 1-5, but possibly also with new state-of-the-art technologies developed in the next future.; Moreover, they will be used to set up in vitro and in vivo systems (e.g., patient-derived organoids, tissue chips, possibly patient-derived xenograft models) to validate the efficacy and safety of the novel ATMPs developed by research program.
Collection and biobanking of follow-up samples from patients with CRC and metachronous PDAC MTS to the liver	CRC: during the postoperative follow-up (up to 36 months), at six-month intervals; PDAC: during the postoperative follow-up (up to 24-months), at time of liver recurrence	* CRC MTS patients: part of peripheral blood collected for hematochemical testing during follow-up visits; * newly-diagnosed metachronous PDAC MTS patients, previously enrolled in the non-metastatic PDAC cohort: peripheral blood and, whenever possible, tumor tissue from liver metastasis (fine-needle bioptic sample) collected at the time of liver recurrence diagnosis, during the follow-up after the primary tumor surgery.

Trial Locations

Locations (1)

IRCCS San Raffaele; 🇮🇹 Milan, Italy