Neoadjuvant Stereotactic Ablative Radiotherapy for Pancreatic Ductal Adenocarcinoma

Borderline Resectable Pancreatic Adenocarcinoma Clinical Trial

— ANSR-PDAC  

Official title:

A Pilot Study to Assess the Safety and Feasibility of Neoadjuvant Stereotactic Ablative Radiotherapy for Pancreatic Ductal Adenocarcinoma

Clinical Trial Details — Status: Not yet recruiting

Administrative data

• NCT number: NCT04915417
• Other study ID #: 118543
• Status: Not yet recruiting
• Phase: N/A
• Start date: August 1, 2021
• Est. completion date: August 1, 2024

Study information

• Verified date: May 2021
• Source: Lawson Health Research Institute
• Contact: Stewart Gaede
• Phone: 5196858605
• Email: stewart.gaede[@]lhsc.on.ca
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

Pancreatic cancer (PC) is expected to be the third leading cause of cancer death in Canada in 2019 [1]. Localized pancreatic cancer may be classified as resectable, borderline resectable, or locally advanced. To date, radical surgical resection and adjuvant treatment provide the greatest chance of long-term disease control and overall survival [2,3]. Despite this favourable group, the five-year survival rates are approximately 20% [4].

Neoadjuvant therapy (NAT) for resectable pancreatic cancer (RPC) has been widely accepted for the management of borderline resectable PC (BRPC) to increase the likelihood of achieving R0 resection [4-7]. However, to date, NAT for RPC is still an area of debate due to the lack of large prospective randomized controlled trials that compare this technique to surgery plus adjuvant therapy.

Stereotactic ablative radiation therapy (SABR) uses modern radiotherapy planning and targeting technologies to precisely deliver larger, ablative doses of radiotherapy in 1-8 fractions. The role of SABR in RPC has yet to be fully established. The typical goal of radiation therapy in the neoadjuvant setting is to improve local control and increase R0 resection rates. However, there are still concerns about the timing of surgery after SABR and any implementation should be evaluated for safety.

Treatments inherently changes the tumour and can cause immunomodulatory effects. SABR has anti-neoplastic effects both directly on the tumour and by its interactions with the immune system. In addition to the direct DNA damage, it is felt that SABR also increases T-cell priming, antigen production and presentation. Pancreatic cancer's dense, collagen rich stroma has prevented patients from receiving the same benefits of checkpoint inhibition that have been achieved in other cancer sites.

Description:

Goals: The primary goals of this study are to evaluate the safety and feasibility of neoadjuvant SABR patients with surgical PC. This proposal is specifically intended to strengthen the correlative sciences evaluating pre- and post-treatment tissue samples and serial plasma samples evaluating the immunomodulatory effects of neoadjuvant SABR.

Population: Patients with upfront resectable pancreatic adenocarcinoma (RPC) with a plan to proceed directly to curative surgery or borderline resectable pancreatic adenocarcinoma (BRPC) with a plan for neoadjuvant FOLFIRINOX chemotherapy with the hopes of then proceeding to a curative surgical resection will be accrued.

Objectives and Endpoints: The primary objective is to determine the safety and feasibility of neoadjuvant SABR in patients with PC. Secondary objectives include (1) determining the tumor perfusion with serial dynamic contrast enhanced CT imaging studies; (2) evaluating serial peripheral blood samples for changes in markers of inflammation or immune activation using O-link's plasma-based proteomics platform; (3) T-cell receptor (TCR) sequencing from RNA isolated from the buffy coat from serial whole blood samples; (4) Digital spatial profiling on FFPE samples from pre-treatment biopsy tissue and post-treatment surgical resection samples to examine CD3, CD8, PD-L1 expression and other markers of immunomodulation; (5) RNA sequencing (RNA-Seq) will be conducted on pre- and post-treatment samples to examine the gene expression profile within specific areas of the tumor environment; (6) examining the influence of SABR on classic biomarkers such as CEA and CA19-9.

Methodology: Upfront RPC (n=10) and BRPC (n=20) with the expectation of approximately 10 participants receiving neoadjuvant SABR on study.

Imaging Studies: Patients in both arms will receive both a hybrid PET/MRI scan and a dynamic contrast enhanced (DCE-CT) scan prior to SABR to define high metabolic regions (using 18F-FDG PET), define the whole tumour border (using MRI), and to define baseline perfusion parameters such as blood flow, blood volume, permeability surface, and mean transit time (using DCE-CT). This information will be used to define regions that will receive high doses of radiation therapy. These patients will also receive a DCE-CT scan six hours after the first of three radiation treatments and 4 weeks following SABR (before surgery) to investigate changes in blood flow.

Recruitment information / eligibility

• Status: Not yet recruiting
• Enrollment: 30
• Est. completion date: August 1, 2024
• Est. primary completion date: August 1, 2023
• Accepts healthy volunteers: No
• Gender: All
• Age group: 18 Years and older

Eligibility

Inclusion Criteria (Both Arms):

• Age 18 or older

• Able to provide informed consent

• Histologically confirmed primary pancreatic cancer, or willing to undergo endoscopic ultrasound (EUS) with synchronous fiducial marker placement and biopsy

• No evidence of distant metastases (M0)

• Medically fit to undergo surgical resection

• Life expectancy >6 months

• Adequate renal function to tolerate contrast dye for imaging

• ECOG Performance Status 0-2 Inclusion Criteria (Arm 1)

• Upfront resectable pancreatic cancer

• No evidence of nodal disease (N0)

• Appropriate to undergo a pancreaticoduodenectomy within 4-6 weeks of registration

Inclusion Criteria (Arm 2)

• Borderline resectable or upfront resectable pancreatic cancer

• Plan for surgical resection independent of the biochemical or radiographic response to SABR

Exclusion Criteria (Both Arms):

• Serious medical comorbidities or other contraindications to radiotherapy or surgery

• Gross disease involving duodenum or stomach

• Unable to have fiducials placed.

• Recurrent pancreatic cancer

• Prior abdominal radiation at any time

• Inability to attend full course of radiotherapy, surgery, or follow-up visits

• Contrast allergy

• Pregnant or lactating women

Exclusion Criteria (Arm 1):

• Receipt of any neoadjuvant system therapy, standard cytotoxic therapy or experimental

Exclusion Criteria (Arm 2):

• Elevated bilirubin or liver enzymes considered to be a contraindication to irinotecan chemotherapy, unless an intervention is planned to improve hepatic functioning

Related Conditions & MeSH terms

• Adenocarcinoma
• Borderline Resectable Pancreatic Adenocarcinoma
• Resectable Pancreatic Adenocarcinoma

Intervention

Radiation:
• Stereotactic Ablative Body Radiotherapy (SABR)
Patients will receive 27-30 Gy in 3 fractions to the planning target volume (PTV) with a simultaneous in-field boost to the metabolically active areas of the gross tumor volume (GTV) to a maximum of 45 Gy. Patients will be treated every other day.

Locations

Country	Name	City	State
n/a

Sponsors (2)

Lead Sponsor	Collaborator
Lawson Health Research Institute	London Health Sciences Foundation

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Toxicity of Neoadjuvant SABR	Patients will be evaluated for toxicity during their follow-up exams according to the Common Terminology Criteria for Adverse Events (CTCAE) v4.0	2 years
Primary	Quality of Life (QOL)	QOL will be measured using the Functional Assessment of Cancer Therapy for Hepatobiliary and Pancreatic Subscale (FACT-Hep HCS)	2 years
Secondary	Change in tumor blood flow assessed by dynamic contrast enhanced CT imaging	Dynamic Contrast enhanced CT imaging will be used to calculate tumor blood flow (ml^-1) within 2 weeks after completion of chemotherapy and calculate the change compared to baseline	<2 weeks after completion of chemotherapy (Arm 2 only)
Secondary	Change in tumor blood flow assessed by dynamic contrast enhanced CT imaging	Dynamic Contrast enhanced CT imaging will be used to calculate tumor blood flow (ml^-1) within 6 hours after first fraction of radiation therapy and calculate the change compared to baseline	<6 hours after first fraction of radiation therapy (Arm 1 only)
Secondary	Change in tumor blood flow assessed by dynamic contrast enhanced CT imaging	Dynamic Contrast enhanced CT imaging will be used to calculate tumor blood flow (ml^-1) within 6 hours after first fraction of radiation therapy and calculate the change compared to that post-chemotherapy	<6 hours after first fraction of radiation therapy (Arm 2 only)
Secondary	Change in tumor blood flow assessed by dynamic contrast enhanced CT imaging	Dynamic Contrast enhanced CT imaging will be used to calculate tumor blood flow (ml^-1) within 2-4 weeks after completion of radiation therapy and calculate the change compared to baseline	2-4 weeks after radiation completed (Arm 1 only)
Secondary	Change in tumor blood flow assessed by dynamic contrast enhanced CT imaging	Dynamic Contrast enhanced CT imaging will be used to calculate tumor blood flow (ml^-1) 2-4 weeks after completion of radiation therapy and calculate the change compared to that post-chemotherapy	2-4 weeks after radiation completed (Arm 2 only)
Secondary	Predictive Value of Imaging Biomarkers of tumor metabolic uptake	Predictive value of 18F-2-fluoro-2-deoxy-D-glucose fluorodeoxyglucose (FDG)-PET imaging biomarkers compared to pathologic outcome (complete response or non-complete response to treatment	2 years
Secondary	Tumor recurrence	Time to local recurrence, regional recurrence, and distant recurrence of disease will be measured	2 years
Secondary	Change in Cancer Antigen (CA) 19-9 expression	Change in CA19-9 detected in blood samples acquired before and after radiation therapy	2 years
Secondary	Change in Carcinoembryonic antigen (CEA) expression	Change in CEA detected in blood samples acquired before and after radiation therapy	2 years
Secondary	Detection of CD8+ T-cells	Peripheral blood samples will be evaluated using a plasma-based proteomics platform to detect T-cells after radiation therapy to examine peripheral markers of tumor immunity	2 years
Secondary	Changes in markers of immune expression (CD3)	FFPE samples from pre-treatment biopsy tissue and post-treatment surgical resection samples to examine CD3 expression	2 years
Secondary	Changes in markers of immune expression (CD8)	FFPE samples from pre-treatment biopsy tissue and post-treatment surgical resection samples to examine CD8 expression	2 years
Secondary	Changes in markers of immune expression (PD-L1)	FFPE samples from pre-treatment biopsy tissue and post-treatment surgical resection samples to examine PD-L1 expression	2 years
Secondary	Downstaging Rate (Arm 2)	Arm 2 patients will be re-evaluated for surgical resection. The ratio of the number of patients who proceed to surgery to the total number of patients that receive neoadjuvant FOLFIRINOX + SABR will be determined and subsequent therapy will be decided.	2-4 weeks post SABR
Secondary	Negative Margin Resection Rate	Arm 1 patients (rPC) will be evaluated to ensure they remain fit for surgery. R0 vs. R1 resection will be determined and subsequent therapy will be decided. R0 vs. R1 resection will also be determined for Arm 2 (BRCP) patients that receive resection and subsequent therapy will be decided.	Immediately post surgery
Secondary	True Pathological Complete Response (PCR)	For both arms, those who exhibit a lack of viable tumor after surgical resection (e.g. a pathologic complete response [pCR]), which will be reported as the patients with a complete response, divided by the total number of patients undergoing resection, with a 95% confidence interval (CI).	2 years