IMPROVE: Circulating Tumor DNA Analysis to Optimize Treatment for Patients With Colorectal Cancer

Colorectal Cancer Clinical Trial

Official title: Implementing Non-invasive Circulating Tumor DNA Analysis to Optimize the Operative and Postoperative Treatment for Patients With Colorectal Cancer

Status Active, not recruiting

Clinical Trial Summary

The overall objective of these studies are to confirm that ctDNA detected in plasma after intended curative treatment for CRC can be applied in clinical practice as a marker of subclinical residual disease and risk of recurrence.

Clinical Trial Description

1. INTRODUCTION Colorectal cancer (CRC) is the third most common cancer worldwide. Approximately two-thirds of patients initially present with potentially curable disease but in spite of curatively intended treatment 30-40% experience relapse of disease. When diagnosed, survival of CRC can basically be improved in two ways, 1) by reducing the risk of recurrence all together, e.g. by improving surgery or by offering adjuvant chemotherapy to the patients with high risk of recurrence, or 2) by early detection of recurrence enabling early intervention which improve patient survival significantly. Radical surgery is the most important factor for recurrence and survival of CRC, and free margins of resection are of paramount importance. Initiatives to optimize the quality of surgery, including resection within the correct planes and adherence to the concept of complete mesocolic excision with central ligation of the tumor feeding arteries, are currently being implemented in Denmark. A single Danish center (Hillerød Hospital) which have implemented this technique have reported substantial higher survival rates compared to similar Danish centers using standard surgery. Randomized trials have shown that the therapeutic benefit of adjuvant chemotherapy is modest, while the toxicity is substantial. Accordingly, treatment benefit has only been documented for the patients with the highest risk of recurrence (stage III). Nevertheless, also a subset of stage I and stage II patients recur and could potentially benefit from adjuvant therapy. Development of a sensitive approach for assessing if occult residual disease is present after surgery is highly desirable to identify a high-risk sub-group who should be offered adjuvant therapy. Moreover, for stage III disease it is well documented that many patients are overtreated with adjuvant therapy. Surgery alone cures > 40% of such patients and the number needed to treat to prevent a relapse is ~7. Also for these patients, there is need for better and more specific markers of risk of recurrence. Solid tumors, including CRC, release DNA fragments into plasma. The plasma of cancer patients contains DNA fragments from both normal and cancer cells. This DNA is referred to as cell free DNA (cfDNA), while the specific fraction that originates from tumor cells is called circulating tumor DNA (ctDNA). The investigators have recently presented results that, in line with others, indicate that patients with ctDNA detected post-surgery are at extremely high risk of a later radiologic recurrence (HR=37.66; 95% CI, 4.23 to 335.49; P<0.0001). This risk is greater than that in patients with stage III colorectal cancer who are routinely treated with adjuvant therapy. These findings show that post-operative ctDNA analysis has potential to become a highly valuable tool for assessment of the quality of the primary surgery and for guiding the use of adjuvant therapy. In agreement with others, the investigators have shown that ctDNA changes detected through longitudinal analysis correlates closely with changes in tumor volume as assessed by CT-imaging. Thus, ctDNA analysis has potential as a tool for assessing the impact of intervention (e.g. chemotherapy, surgery, radio frequency ablation (RFA), and stereotactic body therapy (SRBT)). The investigators have shown that serial ctDNA analysis enable detection of incipient clinical disease recurrence on average 10 months before by the conventional modalities (primarily CT-scan. Accordingly, ctDNA analysis has the potential to provide a critical window of opportunity for intervention at an early time-point where curative modalities are still an option. 2. INVESTIGATIONAL PLAN 2.1 Overall study design The IMPROVE - OBSERVATIONAL STUDIES are based on a comprehensive series of blood sampling and ctDNA analysis performed in CRC patients before and after surgery, during and after adjuvant chemotherapy, and during surveillance. Patients are followed 5 years from date of surgery. The IMPROVE OBSERVATIONAL STUDIES logistically consist of two parts: IMPROVE OBSERVATIONAL STUDY PART I - SURGERY This part comprises blood sampling and ctDNA analysis pre-operative and immediately after surgery (post-OP day 14) and sampling of tissue from the resected specimen. IMPROVE OBSERVATIONAL STUDY PART II - SURVEILLANCE This part comprises longitudinal blood sampling over a 5 year surveillance period. IMPROVE INTERVENTIONAL STUDY - IMPROVE IT A subset of patients included in IMPROVE PART I - SURGERY are candidates for inclusion in the IMPROVE INTERVENTIONAL STUDY - IMPROVE IT. The IMPROVE IT study is described in detail in a separate protocol. 2.2 Sample size We will include at least 1800 patients treated with curative intend for stage I-III disease. We have recently reported a study showing that ctDNA was detectable in plasma (drawn shortly after surgery) from 57% of relapsing stage II and III patients and in 0% of the non-relapse patients. In the present study, we expect a higher sensitivity as we will be analyzing ~8 times larger blood volumes than previously. We expect the following stage distribution: stage I, 28%; stage II, 37%; stage III, 35%9; and estimated ~223 relapse events (expected relapse rates: stage I, 7%; stage II, 12%; stage III, 17%). When combining our previous results with the size of the suggested cohort and with the expected distribution and relapse events, this translates into a power of >99.9% at a precision level of 1% (two-tailed) for confirming prognostic significance of ctDNA at the end of the study. 2.3 Collection of biological samples (Blood and tissue) 2.3.1 Time points for sample collection - IMPROVE PART I -SURGERY For all patients included in part I (Surgery) blood samples will be drawn prior to and after surgery. Whenever possible fresh tumor and adjacent normal mucosa biopsies will be collected from the surgical resected specimen, otherwise formalin-fixed paraffin-embedded tissues will be obtained from the archives. 2.3.2 Time points for sample collection - IMPROVE PART II - SURVEILLANCE For all patients included in part II (surveillance) blood samples will be drawn longitudinally during the post-surgical follow-up period: three times in year 1, three times in year 2, twice in year 3, and once a year in years 4 and 5. 2.3.3 Time point for identification of candidates for IMPROVE IT. The candidates are patients with stage I or II disease and WITHOUT risk factors qualifying for adjuvant chemotherapy, and who's day 14 blood sample is ctDNA positive. Patients that consented to receive the day 14 blood sample result are approached and invited to participate in IMPROVE-IT. Before inclusion the patients are offered a PET-CT scan, to ensure that no metastases have been overlooked. If the day 14 sample is ctDNA negative the patients are informed that their relapse risk is low and that they will receive surveillance according to DCCG guidelines. Patients with indications for adjuvant chemotherapy are informed that they will NOT receive information about the analysis results of their day 14 blood sample, since this will not change their planned treatment course. The patients are asked to consent to longitudinal blood sampling and ctDNA analysis (inclusion in IMPROVE PART II - SURVEILLANCE), no matter whether they will receive adjuvant chemotherapy or not. 2.4 Molecular analysis 2.4.1 Detection and quantification of circulating tumor DNA Detection and quantification of ctDNA will be performed using our recently developed ultra-sensitive targeted duplex sequencing approach. Using this approach, we will sequence more than 5,000 unique DNA molecules from each plasma sample. Thereby, detection of somatic mutations with allele frequencies down to ~0.1% is possible. Further, our improved method includes multiple steps aimed at reducing the error rate, including the use of unique strand-specific molecular barcodes (UMIs) and redundant sequencing of each cfDNA fragment. Thereby we can distinguish polymerase induced errors from true mutations. The sequencing approach targets <100.000 of the 3 billion bases in the human genome. The panel comprise the most common and important CRC driver mutations identified in the IntOGEN and TCGA databases. Multiple redundant capture probes are used for each gene to improve coverage and provide higher specificity. Targeting these regions is sufficient to ensure that at least one somatic mutation will be identified in each CRC case and should therefore enable assessment of the ctDNA level in all included patients. The gene regions included in the panel are: TP53 exon 5-8 (1792 bases), KRAS codons 12, 13, 61, 117, and 146 (738 bases), SMAD2 selected frequently mutated regions (463 bases), SMAD4 selected frequently mutated regions (513 bases), FAM123B selected frequently mutated regions (669 bases), SOX9 selected frequently mutated regions (693 bases), APC selected frequently mutated regions (5477 bases), TCF7L2 selected frequently mutated regions (920 bases), NRAS codons 12, 13, and 61 (405 bases), BRAF codon 600 and others nearby (200 bases), FBXW7 selected frequently mutated regions (868 bases), PIK3CA 8 hotspot mutations (905 bases). 2.5 Collection of clinical Information A central part of the project involves comparison and correlation of the ctDNA assessments (gathered from the blood samples) with the clinical information on treatment and outcome. Clinical information regarding the treatment and outcome of the treatment will be collected from hospital records and health registries. 2.6 Definitions of predictor variables, co-variates and end-points 2.6.1 Primary endpoint - Disease free survival at 3 years (3y-DFS) 2.6.2 Secondary endpoints - Local and/or distant recurrence (pathological, radiological or clinical) - Time to recurrence (TTR) - Disease free survival at 1 year (1y-DFS)) - Overall survival at year 5 (5y-OS) - Molecular residual disease - Time to molecular recurrence (TTMR) 2.6.3 Safety Endpoint - Frequency and severity of adverse events (AE) in relation to the per protocol blood draws. 2.6.4 Definition of endpoints - DFS is defined as the time from surgery to the first occurrence of any of the following events; loco-regional recurrence, distant metastases, or death from any cause. - Time to recurrence is calculated from date of surgery until loco-regional recurrence or distant metastases, or death from colorectal cancer. - Overall survival is defined as the time from surgery to death from any cause. - Molecular residual disease is defined as detection of circulating tumor DNA (ctDNA) in a blood sample drawn shortly after the end of a curatively intended treatment (between day 1 and day 30 post-surgery, or between day 1 and day 30 after end of adjuvant therapy). - Time to molecular recurrence is calculated from first time of no detectable ctDNA until detectable ctDNA. 2.7 Statistical analysis 2.7.1 Analysis of DFS, OS, TTR Kaplan-Meier estimates will be used for the estimation of median times to recurrence (clinical and molecular), disease or death and their confidence intervals, stratified according to UICC stage and/or post-OP ctDNA status. Endpoints will be assessed using the log-rank test or a Cox regression model, with time to event (clinical or molecular recurrence or death) as response variable and ctDNA post-surgery or adjuvant therapy as factor. ;

Related Conditions & MeSH terms

• Colorectal Cancer
• Colorectal Neoplasms

• NCT number: NCT03637686
• Study type: Observational
• Source: University of Aarhus
• Status: Active, not recruiting
• Start date: June 14, 2018
• Completion date: July 1, 2028