Official Title
A Research Protocol for Collection of Peripheral and Portal Vein Blood From Patients With Pancreatic Adenocarcinoma for Translational Research
Brief Title
PDAC Peripheral and Portal Vein Sampling
Protocol ID
NCT04289961
Lead Sponsor
The Christie NHS Foundation Trust
Brief Summary
This is a research study in which bio-specimens (whole blood, plasma and serum from
peripheral circulation and portal vein) will be collected from patients with pancreatic
adenocarcinoma for translational research. These samples will be used for (but not
limited to) identification and characterisation of blood-borne biomarkers at the genomic
and protein expression level. Examples of such biomarkers are circulating tumour cells
(CTCs), CTC clusters and circulating DNA (which can be tumour derived, or from
unaffected/normal cells). CTC-enriched blood samples may also be used to generate
CTC-derived tumour explant (CDX) models in immunocompromised mice in order to produce
suitable disease models in which to test novel therapies and identify new molecular
targets. In addition, permission will be sought from study participants for the research
team to access clinical information from medical notes to aid in determining the clinical
relevance of biomarkers identified during the course of this study. Validated biomarkers
are anticipated to be used in designing future biomarker-directed clinical trials in
these disease groups.
Detailed Description
Pancreatic Ductal Adenocarcinoma (PDAC) presents an urgent medical need. Approximately
9000 new cases of pancreatic cancer are diagnosed every year in the United Kingdom (UK)
and worldwide it is projected to become the second most common cause of cancer related
death by 2030. Currently the diagnostic pathway starts with pancreatic protocol Computed
Tomgraphy (CT) scan which demonstrates sensitivity of 90% and specificity of 99% in
diagnosis of pancreatic cancer. Magnetic Resonance Imaging (MRI) and Positron Emission
Tomography (PET) can assist with ambiguous masses. Despite the high sensitivity and
specificity of imaging modalities, definitive diagnosis is routinely obtained only by
endoscopic ultrasound (EUS)-guided fine-needle aspiration (FNA). During this procedure
four "passes" (biopsies) on average are required to obtain sufficient tissue for
diagnosis.
Patients usually present with locally advanced or metastatic disease and are offered
standard of care chemotherapy, which has only a limited impact on overall survival.
Consequently the 5-year overall survival (OS) is only 2% with no significant improvement
over the last 40 years. Approximately only 20% of the patients are eligible for surgical
resection which is followed by adjuvant chemotherapy. However, 66% of these patients will
experience local or distant recurrence, leading to a median overall survival in the range
of 28 months. Improved stratification of patients for existing treatments may thus avoid
unnecessary overtreatment and associated side effects to improve quality of life;
conversely, it may also enable selection for a more appropriate treatment.
A significant reason for the lack of progress in tackling metastatic disease is the poor
understanding of the biology and pathophysiology of metastasis. Studying the biology of
PDAC metastasis is hampered by the fact that it is difficult to obtain tissue from the
primary and metastatic sites. Moreover, serial biopsies following progression during
treatment is largely not feasible, further hindering insight into the mechanisms of
development of treatment resistance. The only easily-accessible blood-borne biomarker
that is currently used in clinic is the serum marker carbohydrate antigen (CA) 19-9.
However, its clinical use is limited firstly by the fact that 5-10% of the population are
Lewis blood group negative and do not express CA19-9. Furthermore it is elevated in
non-malignant pancreatic and extra-pancreatic diseases. Finally, CA19-9 cannot provide
information about the genetic landscape that drives PDAC metastasis.
Metastatic spread is primarily haematogenous whereby tumour cells enter the circulation
to metastasize mainly to the liver and lung. Such tumour cells have been shown to travel
either as single circulating tumour cells (CTCs) or as groups of cells termed Circulating
Tumour Microemboli (CTM). Heterogeneous CTM composed of cells expressing either
epithellial or mesenchymal markers were isolated from patients with pancreatic cancer
using a filtration-based method, the Isolation by Size of Epithelial Tumour cells
platform (ISET), in a study performed at the Christie NHS Foundation Trust. As such,
isolation and characterisation of CTCs and CTM will provide new insight into the
underlying biological dependencies of metastasizing tumour cells and may thus provide
opportunities to develop better and more accurate diagnostic and prognostic assays as
well as opportunities to treat metastatic disease.
Detection and isolation of CTCs and CTM is limited by the fact that they represent very
rare events compared to other cellular elements in the circulation. To this end, methods
exploiting characteristics that differentiate CTCs from blood cells have been developed
to overcome this obstacle. These CTC workflows usually start by enriching CTCs from a
blood sample utilizing either surface markers present exclusively on CTCs, or their
unique physical properties such as size, inertia, dielectric charge and density.
Following enrichment, CTCs are isolated and can be simply enumerated or they are used for
more advanced downstream analysis including genomic, transcriptomic and proteomic
analysis as well as in vivo applications in cell culture and mouse models, with the aim
of gaining insight into their function as metastatic seeds and biomarker development.
In the clinical setting, CTCs can be used to aid decision making. Indeed, enumeration of
CTCs detected by the CellSearch platform has been FDA approved for prognosis and
monitoring of metastatic breast, colorectal and prostate cancer. However, isolation and
enumeration of CTCs in pancreatic cancer has given inconsistent results between studies
as to whether CTCs can be used as prognostic biomarkers. These studies analysed CTCs
isolated from peripheral blood. However, as the main venous drainage of the pancreas is
through the portal vein to the liver, it may be hypothesized that CTCs could be filtered
and removed as they pass through the liver capillaries. Hence, in order to define the
biological and prognostic role of CTCs in pancreatic adenocarcinoma, it is critical to
initiate studies with blood isolated from the portal vein to bypass confounding effects.
Indeed, detection of CTCs in portal vein (PV) blood acquired at operation was recently
reported by Bissolati et al.. By obtaining peripheral vein samples at the same time, this
study confirmed that CTC number was greater in portal compared to peripheral samples and
also demonstrated significant correlation between CTC positivity in portal vein samples
and frequency on liver metastasis. However, it failed to show significant correlation
with OS or Disease Free Survival (DFS). PV sampling has been performed safely; in
December 2015 Catenacci et al. reported collection of PV blood from 18 patients with
pancreatobilliary cancers by EUS-FNA with no complications during the procedure. PV
puncture has also been previously reported for islet cell transplantation in patients
with Type 1 Diabetes Mellitus. This procedure has low morbidity and also, potential
complications, such as portal vein thrombosis, perihepatic or intraparenchymal hepatic
haemorrhage and haemothorax are reported at a low rate.
During EUS-FNA a curvilinear echoendoscope is advanced to the distal stomach or duodenal
bulb to provide a window of access to a branch of the PV. After verifying venous flow by
Doppler signal, a 19-gauge EUS-FNA needle is advanced transhepatically into the portal
vein branch. With the needle in the portal vein, the stylet is removed and
negative-pressure suction is applied to aspirate blood. A transhepatic approach for
portal vein branch access is an absolute requirement of this technique in order to
minimize the risk of bleeding. The puncture site is monitored under EUS for
complications. As tumour tissue will be obtained at the same time, a potential risk is
the introduction of cancer cells into the circulation as the needle is withdrawn from the
tumour. This risk however is circumvented as the route of the needle into the portal vein
would avoid the primary mass.
The primary reason for drug failure in PDAC is the failure to identify predictive
biomarkers for treatment response which would allow enrichment of patient sub-groups most
likely to benefit from an individual therapy. This is in contrast to other major cancer
types, in which advances in development of new cancer therapeutics and resulting
improvement in survival outcomes are mainly due to the use of predictive biomarkers to
select patients who will derive differential benefit from a particular therapeutic agent.
Trastuzumab in breast cancers over-expressing HER-2, cetuximab for KRAS wild-type
colorectal cancer, and gefitinib and erlotinib for Epidermal Growth Factor Receptor
(EGFR) mutant non-small cell lung cancer best exemplify this therapeutic paradigm. By
providing greater numbers of CTCs and CTM, analysis of PV sample will enable studies of
their biology as well as development of cell lines and CDX models to allow identification
of novel biomarkers and targets for new treatments.
Considering current gaps in knowledge of tumour biology of PDAC and the lack of progress
in therapeutics, there is an urgent clinical need to develop a research strategy that
will allow the discovery and validation of new biomarkers in this group of patients, and
inform on biomarker-directed clinical trials to ultimately improve survival. To initiate
such a research strategy, there is a need for systematic, prospective collection and
analysis of blood samples acquired from peripheral and portal vein circulation to
identify blood-borne surrogate tumour markers that will enable physicians to obtain
relevant information for making personalised therapeutic decisions, in a
minimally-invasive way.
Study Period
-
Enrollment Count
26 participants
Eligibility Criteria
Inclusion Criteria:
1. Patients with clinically-suspected or cytologically/histologically-proven Pancreatic
Adenocarcinoma who have been referred for EUS-FNA. Patients who are already on
treatment would also be eligible.
2. Patients who are 18 years or older.
3. Patients must be able to receive and understand verbal and written information
regarding the study and give written informed consent.
4. Patients must be able to comply with trial requirements.
Exclusion Criteria:
1. Patients with other active malignancy would not be eligible with the exception of
patients with squamous or basal cell carcinoma of the skin. An exception to this
statement would be those patients with a known/suspected germ-line predisposition to
suffer multiple malignancies, such as, but not limited to Hereditary Breast and
Ovarian Cancer Syndrome (BRCA1/2), Lynch syndrome or multiple endocrine neoplasia
(MEN) syndrome.
2. Patient with INR >1.5 and/or platelets ≤50.
3. Patients with bleeding disorders.
4. Patients on anti-platelet or anti-coagulation treatment that cannot be temporarily
discontinued around the procedure.
5. Patients who cannot give informed consent.
6. Patients with known Hepatitis C viral infection.
7. Patients with known Human Immunodeficiency Virus (HIV) infection.
8. If clinically judged by the investigator that the patient should not participate in
the study.
Filters
Pancreatic Adenocarcinoma
NA
COMPLETED
ADULT
OLDER_ADULT