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Clinical Trial Details — Status: Recruiting

Administrative data

NCT number NCT05314400
Other study ID # 120191
Secondary ID
Status Recruiting
Phase N/A
First received
Last updated
Start date July 1, 2022
Est. completion date May 1, 2026

Study information

Verified date December 2023
Source Lawson Health Research Institute
Contact Harry Marshall, MD/PhD
Phone 519-685-8500
Email harry.marshall@lhsc.on.ca
Is FDA regulated No
Health authority
Study type Interventional

Clinical Trial Summary

After a patient is diagnosed with colon cancer, they receive a CT of the chest, abdomen, and pelvis to see if the cancer has spread (metastasized) to other parts of the body. A common site for the cancer to spread to is the liver. If an abnormality is seen in the liver on CT, sometimes an MRI of the liver is required to determine a) whether it is cancer or not and b) whether there are small tumours in the liver that were not visible on CT. During the MRI, the patient is injected with intravenous (IV) contrast. This makes liver lesions more conspicuous and also helps determine if they are cancerous or not. The most commonly used IV contrast agent is called Gadovist. However, there is another IV contrast agent called Primovist that is better at detecting liver metastases from colon cancer than Gadovist. This is very important information for surgeons, because if they considering cutting out (resecting) the liver tumours, they want to make sure they get them all. Unfortunately, Primovist is used sparingly in Canadian hospitals because it is more expensive than Gadovist and the MRI takes longer. Some early small studies have suggested that it may be possible to shorten the Primovist MRI significantly (e.g. from 60 minutes to 15 minutes), making it economically feasible to offer Primovist to more patients. However, there have not been any large studies performed to confirm these findings. The purpose of this study is to compare the accuracy of colon cancer liver metastasis detection between a regular, full-length Primovist MRI versus a shortened Primovist MRI protocol. The economic impact will also be assessed.


Description:

BACKGROUND Colorectal cancer (CRC) is the third most commonly diagnosed cancer in Canada and the second leading cause of death in both men, and women (1). In 2021, 24800 Canadians were diagnosed with CRC and 9,600 died from the disease (1). Over their lifetime, 1 in 18 Canadians will be diagnosed with CRC and 1 in 37 will die (1). Accurate staging is essential to improving outcomes, providing appropriate patient management, and improving the health care costs associated with caring for patients with CRC. London Health Sciences Centre (LHSC) is a tertiary care referral centre for a catchment area of 2 million people in Southwestern Ontario. Annually, approximately 200 patients present to the London Regional Cancer Program with a diagnosis of colorectal cancer. Of these, about 100 patients will have potentially resectable colorectal liver metastasis (CRCLM). Staging algorithms for CRC include contrast enhanced computed tomography (CECT) of the thorax/abdomen/pelvis, with MRI of the liver in some centres. The objective for performing imaging tests is to accurately determine the extent of local and distant disease to direct patient management. Accurate assessment of the hepatic disease burden is crucial for surgical planning since resection of liver metastases is a core component of CRCLM treatment (2). At LHSC, all patients are initially imaged with CECT of the thorax/abdomen/pelvis. MRI of the liver is reserved for patients that require further characterization of equivocal liver lesions detected on CT. When performed, liver MRI is often performed with extracellular agents such as gadobutrol (Gadovist), i.e. EC-MRI. Hepatobiliary MRI contrast agents such as gadoxetic acid (aka gadoxetate, trade name Primovist in Canada), i.e. EOB-MRI, provide superior accuracy in detection of CRCLM compared to both CECT (3) and EC-MRI (4). Moreover, the use of EOB-MRI can alter management decisions and improve patient outcomes (3,5,6). It is also the modality of choice in CRCLM patients post-systemic therapy as per the 9th International Forum for Liver MRI Consensus Report (7). Despite these data, hepatobiliary agents are being used sparingly in most Canadian hospitals, including at LHSC as a problem-solving tool. This is due to two factors: (a) the higher unit cost of gadoxetate compared to gadobutrol and iodine-based CT contrast agents, and (b) the increased MRI scan time required for EOB-MRI compared to EC-MRI or CECT. The increased scan time is a result of the need to acquire images in the "hepatobiliary (HPB) phase" for EOB-MRI, typically 20 minutes post-injection, a longer delay than is required for EC-MRI or CECT. These factors result in increased operational costs for EOB-MRI and opportunity costs from reduced magnet time for other MRI studies. To address the increased scan time with EOB-MRI, some studies have retrospectively examined the potential role of abbreviated MRI protocols (aMRI) compared to a full protocol (fMRI) (8-11). The premise of EOB-aMRI protocols involves an injection of gadoxetate at the outset of the study, often outside the scanner room. During the 20 min waiting period prior to image acquisition in the HPB phase, an "abbreviated" set of sequences is acquired, usually including DWI/ADC and sometimes T2 weighted images. At the 20 min mark, the HPB phase images are acquired, and the study is complete. The aim of abbreviated protocols is to increase patient throughput without compromising diagnostic accuracy. The initial results in this relatively nascent field are promising, showing high interobserver agreement and high diagnostic accuracy not significantly different from the full protocol. For example, Canellas et al reported both κ and area under the ROC curve (AUC) of greater than 0.9 for both aMRI and fMRI, with an estimated cost savings of 41% per scan (10). Ghorra et al found similar detection rates of about 86% for both aMRI and fMRI with slightly lower accuracy of the aMRI protocol of about 87% vs 93% for fMRI, but no consistent statistical trends were present (11). However, existing studies in the literature have simulated an aMRI examination by using a subset of fMRI sequences; some sequences, including the dynamic post contrast sequences acquired before 20 min are removed retrospectively (8-11). Currently there are no published studies comparing fMRI with prospectively acquired aMRI. As retrospective studies may overestimate accuracy and cost savings, there is a need for higher quality, prospective evidence (7). Additionally, retrospective studies are unable to perform a formal economic analysis of costs related to the imaging procedure itself, and importantly downstream costs related to patient management. RATIONALE The primary aim of this study is to prospectively compare the diagnostic accuracy of aMRI compared to fMRI regarding CRCLM, using a composite reference standard. Our hypothesis is that aMRI is noninferior to fMRI in this regard, as measured by sensitivity, specificity, and the AUC. If this is the case, it may serve as evidence that EOB-MRI utilization can be increased even within resource constraints inherent to all Healthcare systems. The rationale for using a composite reference standard is that due to varying patient management strategies, the optimal reference standard (surgical pathology) is not always available, and therefore alternative methods must be considered. The rationale for using fMRI as the control group is that this protocol is the current standard of care for EOB-MRI. A secondary aim is to quantify the economic impact of aMRI vs fMRI both in terms of imaging costs and downstream patient management costs. Our hypothesis is that aMRI will not cost more than fMRI on a per patient basis (i.e. noninferiority). If this is the case, higher patient throughput can be achieved at no increased economic expense. Another secondary aim is to prospectively compare the diagnostic accuracy of CECT vs aMRI and fMRI for diagnosis of CRCLM, using a composite reference standard. Our hypothesis is that both aMRI and fMRI will be superior to CECT, in line with multiple prior trials (3). A third secondary aim is to evaluate patient outcomes (overall survival, cancer-specific survival, and hepatic recurrence / progression free survival) at 1-year post-baseline EOB-MRI, using clinical data and the 1-year follow-up CECT. Our hypothesis is that aMRI will be noninferior to fMRI, indicating that there is no adverse effect on patient outcomes from the using an abbreviated protocol. The fourth secondary aim is to retrospectively compare the diagnostic accuracy of fMRI to a simulated aMRI created from a subset of fMRI pulse sequences. Our hypothesis is that the simulated aMRI will be noninferior to fMRI. This constitutes a 3-factor multireader multicase design, analogous to multiple prior investigations (3,4), enabling direct comparison of our study and adding to the body of literature on the subject. The final study aim is to compare the diagnostic accuracy and interobserver agreement on aMRI, fMRI, and CECT. Our hypothesis is that there will be no significant difference for diagnostic accuracy. We expect interobserver agreement to be moderate to high. The rationale for choosing a study cohort comprised of patients with CRCLM is: 1) this is a large patient population / common patient presentation, and 2) EOB-MRI has been shown to provide added value for staging CRCLM but is likely underutilized in Canada, as detailed above. The rationale for choosing a 1-year follow-up period is that about 30% to 50% of CRCLM will recur or progress within this interval (12,13), enabling a compromise between capturing a significant portion of adverse patient outcomes while minimizing loss to follow-up and unnecessarily prolonging the study, as this is not the primary objective. STUDY DESIGN This is a prospective, block randomized, allocation concealed, single-blind, multireader study with case-nested-within-test split-plot design. The baseline abbreviated or full Primovist MRI will be acquired between day 2 and 14 and a follow-up contrast enhanced CT abdomen pelvis will be performed 1 year from baseline. A combination of histopathology, biological behavior, and imaging findings applied in a hierarchical manner will determine the reference standard for each focal hepatic lesion, i.e. metastasis or not. Sample size is 300 subjects, with equal distribution of 150 per arm. Statistical analysis of the primary endpoint will be conducted via the updated Obuchowski-Rockette (OR) method (14).


Recruitment information / eligibility

Status Recruiting
Enrollment 300
Est. completion date May 1, 2026
Est. primary completion date May 1, 2025
Accepts healthy volunteers No
Gender All
Age group 18 Years and older
Eligibility Inclusion Criteria: - Male or female, 18 years of age or older - Diagnosis of colorectal cancer, biopsy proven - Prior imaging showing liver lesions that may be metastases - Provision of signed and dated informed consent form - Willingness to comply with study procedures and availability for the duration of the study - Able to tolerate MRI required by protocol Exclusion Criteria: - Presence of implanted medical device or metallic object that is MR incompatible - Baseline eGFR of < 30 mL/min/1.73 m2 - Severe claustrophobia not relieved by oral anxiolytics - Documented severe allergic-like reaction gadolinium-based contrast agent - Weight greater than allowable on MRI table - Pregnancy - Diffuse liver metastases, i.e. definitively unresectable - Severe liver dysfunction, ALBI grade 3

Study Design


Related Conditions & MeSH terms


Intervention

Diagnostic Test:
Full Gadoxetate-enhanced liver MRI
Standard pulse sequences
Shortened Gadoxetate-enhanced liver MRI
Fewer pulse sequences

Locations

Country Name City State
Canada London Health Sciences Centre London Ontario
Canada St. Joseph's Healthcare London Ontario

Sponsors (2)

Lead Sponsor Collaborator
Lawson Health Research Institute Bayer

Country where clinical trial is conducted

Canada, 

References & Publications (14)

Canadian Cancer Statistics Advisory Committee in collaboration with the Canadian Cancer Society, Statistics Canada and the Public Health Agency of Canada. (2021).

Canellas R, Patel MJ, Agarwal S, Sahani DV. Lesion detection performance of an abbreviated gadoxetic acid-enhanced MRI protocol for colorectal liver metastasis surveillance. Eur Radiol. 2019 Nov;29(11):5852-5860. doi: 10.1007/s00330-019-06113-y. Epub 2019 Mar 19. — View Citation

Choi SH, Kim SY, Park SH, Kim KW, Lee JY, Lee SS, Lee MG. Diagnostic performance of CT, gadoxetate disodium-enhanced MRI, and PET/CT for the diagnosis of colorectal liver metastasis: Systematic review and meta-analysis. J Magn Reson Imaging. 2018 May;47(5):1237-1250. doi: 10.1002/jmri.25852. Epub 2017 Sep 13. — View Citation

Ghorra C, Pommier R, Piveteau A, Rubbia-Brandt L, Vilgrain V, Terraz S, Ronot M. The diagnostic performance of a simulated "short" gadoxetic acid-enhanced MRI protocol is similar to that of a conventional protocol for the detection of colorectal liver metastases. Eur Radiol. 2021 Apr;31(4):2451-2460. doi: 10.1007/s00330-020-07344-0. Epub 2020 Oct 6. — View Citation

Granata V, Fusco R, Avallone A, Cassata A, Palaia R, Delrio P, Grassi R, Tatangelo F, Grazzini G, Izzo F, Petrillo A. Abbreviated MRI protocol for colorectal liver metastases: How the radiologist could work in pre surgical setting. PLoS One. 2020 Nov 19;15(11):e0241431. doi: 10.1371/journal.pone.0241431. eCollection 2020. — View Citation

Jhaveri KS, Fischer SE, Hosseini-Nik H, Sreeharsha B, Menezes RJ, Gallinger S, Moulton CE. Prospective comparison of gadoxetic acid-enhanced liver MRI and contrast-enhanced CT with histopathological correlation for preoperative detection of colorectal liver metastases following chemotherapy and potential impact on surgical plan. HPB (Oxford). 2017 Nov;19(11):992-1000. doi: 10.1016/j.hpb.2017.06.014. Epub 2017 Jul 29. — View Citation

Kim C, Kim SY, Kim MJ, Yoon YS, Kim CW, Lee JH, Kim KP, Lee SS, Park SH, Lee MG. Clinical impact of preoperative liver MRI in the evaluation of synchronous liver metastasis of colon cancer. Eur Radiol. 2018 Oct;28(10):4234-4242. doi: 10.1007/s00330-018-5422-2. Epub 2018 Apr 24. — View Citation

Kim JW, Lee CH, Park YS, Lee J, Kim KA. Abbreviated Gadoxetic Acid-enhanced MRI with Second-Shot Arterial Phase Imaging for Liver Metastasis Evaluation. Radiol Imaging Cancer. 2019 Sep 27;1(1):e190006. doi: 10.1148/rycan.2019190006. eCollection 2019 Sep. — View Citation

Koh DM, Ba-Ssalamah A, Brancatelli G, Fananapazir G, Fiel MI, Goshima S, Ju SH, Kartalis N, Kudo M, Lee JM, Murakami T, Seidensticker M, Sirlin CB, Tan CH, Wang J, Yoon JH, Zeng M, Zhou J, Taouli B. Consensus report from the 9th International Forum for Liver Magnetic Resonance Imaging: applications of gadoxetic acid-enhanced imaging. Eur Radiol. 2021 Aug;31(8):5615-5628. doi: 10.1007/s00330-020-07637-4. Epub 2021 Feb 1. — View Citation

Nordlinger B, Sorbye H, Glimelius B, Poston GJ, Schlag PM, Rougier P, Bechstein WO, Primrose JN, Walpole ET, Finch-Jones M, Jaeck D, Mirza D, Parks RW, Mauer M, Tanis E, Van Cutsem E, Scheithauer W, Gruenberger T; EORTC Gastro-Intestinal Tract Cancer Group; Cancer Research UK; Arbeitsgruppe Lebermetastasen und-tumoren in der Chirurgischen Arbeitsgemeinschaft Onkologie (ALM-CAO); Australasian Gastro-Intestinal Trials Group (AGITG); Federation Francophone de Cancerologie Digestive (FFCD). Perioperative FOLFOX4 chemotherapy and surgery versus surgery alone for resectable liver metastases from colorectal cancer (EORTC 40983): long-term results of a randomised, controlled, phase 3 trial. Lancet Oncol. 2013 Nov;14(12):1208-15. doi: 10.1016/S1470-2045(13)70447-9. Epub 2013 Oct 11. — View Citation

Obuchowski NA, Beiden SV, Berbaum KS, Hillis SL, Ishwaran H, Song HH, Wagner RF. Multireader, multicase receiver operating characteristic analysis: an empirical comparison of five methods. Acad Radiol. 2004 Sep;11(9):980-95. doi: 10.1016/j.acra.2004.04.014. — View Citation

Vreugdenburg TD, Ma N, Duncan JK, Riitano D, Cameron AL, Maddern GJ. Comparative diagnostic accuracy of hepatocyte-specific gadoxetic acid (Gd-EOB-DTPA) enhanced MR imaging and contrast enhanced CT for the detection of liver metastases: a systematic review and meta-analysis. Int J Colorectal Dis. 2016 Nov;31(11):1739-1749. doi: 10.1007/s00384-016-2664-9. Epub 2016 Sep 29. — View Citation

Yamamoto M, Yoshida M, Furuse J, Sano K, Ohtsuka M, Yamashita S, Beppu T, Iwashita Y, Wada K, Nakajima TE, Sakamoto K, Hayano K, Mori Y, Asai K, Matsuyama R, Hirashita T, Hibi T, Sakai N, Tabata T, Kawakami H, Takeda H, Mizukami T, Ozaka M, Ueno M, Naito Y, Okano N, Ueno T, Hijioka S, Shikata S, Ukai T, Strasberg S, Sarr MG, Jagannath P, Hwang TL, Han HS, Yoon YS, Wang HJ, Luo SC, Adam R, Gimenez M, Scatton O, Oh DY, Takada T. Clinical practice guidelines for the management of liver metastases from extrahepatic primary cancers 2021. J Hepatobiliary Pancreat Sci. 2021 Jan;28(1):1-25. doi: 10.1002/jhbp.868. Epub 2020 Dec 12. Erratum In: J Hepatobiliary Pancreat Sci. 2022 Apr;29(4):500. — View Citation

Yan TD, Sim J, Black D, Niu R, Morris DL. Systematic review on safety and efficacy of repeat hepatectomy for recurrent liver metastases from colorectal carcinoma. Ann Surg Oncol. 2007 Jul;14(7):2069-77. doi: 10.1245/s10434-007-9388-6. Epub 2007 Apr 14. — View Citation

* Note: There are 14 references in allClick here to view all references

Outcome

Type Measure Description Time frame Safety issue
Primary Diagnostic accuracy of abbreviated versus full MRI protocol Sensitivity, specificity, area under ROC curve 2 years
Secondary Cost of abbreviated versus full MRI protocol Sum of the following dollar amounts: technical MRI fees + professional MRI fees + MRI time (cost per hour defined by local institution * number hours used) 3 years
Secondary Diagnostic accuracy of abbreviated and full MRI protocol versus CT Sensitivity, specificity, area under ROC curve 2 years
Secondary Overall survival at 1 year post abbreviated versus full MRI protocol Proportion of patients alive at 1 year (dimensionless) 3 years
Secondary Cancer specific survival at 1 year post abbreviated versus full MRI protocol 1 - proportion of patients who died of colorectal cancer or its complications (dimensionless) 3 years
Secondary Progression free survival at 1 year post abbreviated versus full MRI protocol 1 - proportion of patients with evidence of recurrent or progressive hepatic disease at 1 year (dimensionless) 3 years
Secondary Diagnostic accuracy of simulated abbreviated versus full MRI protocol Sensitivity, specificity, area under ROC curve 2 years
Secondary Inter-reader agreement for all modalities Sensitivity, specificity, area under ROC curve, and kappa coefficient 2 years
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