HSI-LGG-2019: HyperSpectral Imaging in Low Grade Glioma

Sponsor

Universitaire Ziekenhuizen Leuven (Other)

Overall Status

Recruiting

CT.gov ID

NCT04859725

Collaborator

Imec (Industry), Carl Zeiss Meditec AG (Industry)

Enrollment

Location

Arm

Anticipated Duration (Months)

0.3

Patients Per Site Per Month

Study Details

Study Description

Brief Summary

Low grade glioma (LGG) is a slowly evolving, highly invasive intrinsic brain tumor displaying only subtle tissue differences with the normal surrounding brain, hampering the attempts to visually discriminate tumor from normal brain, especially at the border interface. This makes anatomical borders hard to define during early maximal resection, which is the initial treatment strategy. Therefore, innovative, robust and easy-to-use real-time strategies for intra-operative detection and discrimination of (residual) LGG tumor tissue would strongly influence on-site, surgical decision making, enabling a maximal extent of resection.

To validate this approach hyperspectral imaging (HSI) - using a SnapScan HSI-Camera (IMEC), stably mounted on an OPMI Pentero 900 microscope (Zeiss) - will be used to generate spectral imaging data patterns that discriminate in vivo low grade glioma tissue from normal brain both on the cortical and subcortical level.

Condition or Disease	Intervention/Treatment	Phase
Low Grade Glioma of Brain	Device: Hyperspectral Imaging with Snapscan camera	N/A

Detailed Description

Included patients will undergo a resection of the low grade glioma as standard-of-care. Before, during and after the resection, HSI data ('datacubes') will be acquired by the SnapScan HSI camera on the microscope of all relevant areas of the exposed cortical surface and subcortical cavity walls. The exact points of which the datacubes will be acquired are defined by unequivocal single points on the neuronavigational system (Brainlab). From the points from which the datacubes have been obtained a corresponding tissue sample will be obtained (labeled biopsy) if tumor tissue is to be expected in that particular point, based on the current standard of care assessments intraoperatively using white light illumination on the microscope, intraoperative navigation and intraoperative ultrasound. As such, normally looking brain in the resection cavity wall, will only be biopsied if tumor free margins should be proven as part of the standard-of-care operative procedure (non-critically eloquent brain regions). The objective of this all is to get an initial high quality in vivo dataset to start exploring the potential of the technology.

The project will follow a 'stop and go' design: during the first 9 months, the initially collected spectrally corrected datacubes will be analyzed using machine learning on coded data sets. After this initial phase, an interim analysis will be made from the full list of analyzed datacubes. If a reliable and robust discriminative signal can be detected in low grade glioma tissue, segregating these signals from those in normal tissue (as defined pathologically and/or radiologically), efficacy is demonstrated (proof of concept) and the trial will go on for further collecting of samples in the following 26 months. Within the expanded dataset, the different spectral data patterns will be translated into user's friendly pattern codes for rapid real-time, on-site detection and interpretation through development of dedicated software. If no reliable signal can be retrieved from low grade glioma tissue in vivo during the surgery, further recruitment of patients will be stopped. At that time, the investigators and partners will decide on whether or not relevant amendments to the study will be proposed or not.

Study Design

Study Type:

Interventional

Anticipated Enrollment :

10 participants

Allocation:

N/A

Intervention Model:

Single Group Assignment

Intervention Model Description:

During the first 9 months, the initially collected spectrally corrected datacubes will be analyzed using machine learning. After 9 months, an interim analysis will be made on the datacubes from this primary set with an estimated 10 participants. If a reliable and robust discriminative signal can be detected in low grade glioma tissue, segregating these signals from those in normal tissue, the trial will go on collecting samples for the following 26 months with an inclusion of 10 to 15 participant per year. Within the expanded dataset, the different spectral data patterns will be translated into user's friendly pattern codes for rapid real-time, on-site detection and interpretation through development of dedicated software. If no reliable signal can be retrieved from low grade glioma tissue in vivo during the surgery, further recruitment of patients will be stopped. At that time, a decision will be taken on whether or not relevant amendments to the study will be proposed.During the first 9 months, the initially collected spectrally corrected datacubes will be analyzed using machine learning. After 9 months, an interim analysis will be made on the datacubes from this primary set with an estimated 10 participants. If a reliable and robust discriminative signal can be detected in low grade glioma tissue, segregating these signals from those in normal tissue, the trial will go on collecting samples for the following 26 months with an inclusion of 10 to 15 participant per year. Within the expanded dataset, the different spectral data patterns will be translated into user's friendly pattern codes for rapid real-time, on-site detection and interpretation through development of dedicated software. If no reliable signal can be retrieved from low grade glioma tissue in vivo during the surgery, further recruitment of patients will be stopped. At that time, a decision will be taken on whether or not relevant amendments to the study will be proposed.

Masking:

None (Open Label)

Primary Purpose:

Device Feasibility

Official Title:

Validation of Label-free, Wide-field, Real-time Intra-operative Tissue Discrimination and Tumor Detection of Low Grade Glioma Using a Hyperspectral Imaging (HSI) Sensor/Camera Integrated in the Operative Microscope

Actual Study Start Date :

May 31, 2021

Anticipated Primary Completion Date :

Apr 30, 2023

Anticipated Study Completion Date :

Jun 1, 2024

Arms and Interventions

Arm	Intervention/Treatment
Experimental: Hyperspectral Imaging with Snapscan camera Included patients will undergo a resection of the low grade glioma as standard-of-care. Hyperspectral imaging data will be acquired by the SnapScan HSI camera mounted on the (standard) surgical microscope. As such, the surgical procedure does not deviate from the common, standard-of-care surgical procedures, apart from the acquisition of intraoperative scanning images using the SnapScan HSI camera on the microscope. The objective of this all is to get an initial high quality in vivo dataset to start exploring the potential of the technology.	Device: Hyperspectral Imaging with Snapscan camera Before, during and after the resection, HSI data ('datacubes') will be acquired by the SnapScan camera of all relevant areas of the exposed cortical surface and subcortical cavity walls. The exact points of which the datacubes will be acquired are defined by unequivocal single points on the routinely used neuronavigational system. From the points from which the datacubes have been obtained a corresponding tissue sample will be obtained (labeled biopsy) if tumor tissue is to be expected in that particular point, based on the current standard of care assessments intraoperatively using white light illumination on the microscope, intraoperative navigation and intraoperative ultrasound. As such, normally looking brain in the resection cavity wall, will only be biopsied if tumor free margins should be proven as part of the standard-of-care operative procedure (non-critically eloquent brain regions).

Arm

Intervention/Treatment

Experimental: Hyperspectral Imaging with Snapscan camera

Included patients will undergo a resection of the low grade glioma as standard-of-care. Hyperspectral imaging data will be acquired by the SnapScan HSI camera mounted on the (standard) surgical microscope. As such, the surgical procedure does not deviate from the common, standard-of-care surgical procedures, apart from the acquisition of intraoperative scanning images using the SnapScan HSI camera on the microscope. The objective of this all is to get an initial high quality in vivo dataset to start exploring the potential of the technology.

Device: Hyperspectral Imaging with Snapscan camera

Before, during and after the resection, HSI data ('datacubes') will be acquired by the SnapScan camera of all relevant areas of the exposed cortical surface and subcortical cavity walls. The exact points of which the datacubes will be acquired are defined by unequivocal single points on the routinely used neuronavigational system. From the points from which the datacubes have been obtained a corresponding tissue sample will be obtained (labeled biopsy) if tumor tissue is to be expected in that particular point, based on the current standard of care assessments intraoperatively using white light illumination on the microscope, intraoperative navigation and intraoperative ultrasound. As such, normally looking brain in the resection cavity wall, will only be biopsied if tumor free margins should be proven as part of the standard-of-care operative procedure (non-critically eloquent brain regions).

Outcome Measures

Primary Outcome Measures

Comparison of hyperspectral image patterns of superficial and deep tumor tissue with patterns of normal brain [During the surgical procedure]
Assessment of discriminate power of HSI data between 468 and 780 nm between tumor and normal brain tissue by comparison of data acquired on imec VNIR HSI Snapscan camera and gold standard image segmentation of brain tissue. Image segmentation of white light images acquired on the Pentero 900 surgical microscope will be performed based on the assessment of the surgeon and on histopathological assessment of biopsies taken within the standard of care procedure. A co-registration of the segmented images and will be transferred to subsequently acquired HSI data and used to statistical assess whether HSI data can be used to discriminate the spectral signatures of healthy and tumorous tissue in vivo.

Eligibility Criteria

Criteria

Ages Eligible for Study:

18 Years and Older

Sexes Eligible for Study:

All

Accepts Healthy Volunteers:

Inclusion Criteria:

Age ≥ 18 years
Radiologically suspected low grade glioma (newly diagnosed or recurrent)
Scheduled for tumor resection at UZ Leuven
Signed informed consent document prior to resection

Exclusion Criteria:

Children with age < 18 years
If final pathology reveals other pathological diagnosis than low grade glioma, datacubes will not be included in the final analysis

Contacts and Locations

Locations

	Site	City	State	Country	Postal Code
1	UZ Leuven	Leuven	Vlaams-Brabant	Belgium	3000

Sponsors and Collaborators

Universitaire Ziekenhuizen Leuven
Imec
Carl Zeiss Meditec AG

Investigators

Principal Investigator: Steven De Vleeschouwer, MD, PhD, UZ Leuven

Study Documents (Full-Text)

None provided.

More Information

Publications

None provided.

Responsible Party:

Prof. Dr. Steven De Vleeschouwer, Member of Staff Neurosurgery, Clinical Professor, Universitaire Ziekenhuizen Leuven

ClinicalTrials.gov Identifier:

NCT04859725

Other Study ID Numbers:

S63174

First Posted:

Apr 26, 2021

Last Update Posted:

May 18, 2022

Last Verified:

May 1, 2022

Individual Participant Data (IPD) Sharing Statement:

Plan to Share IPD:

Studies a U.S. FDA-regulated Drug Product:

Studies a U.S. FDA-regulated Device Product:

Keywords provided by Prof. Dr. Steven De Vleeschouwer, Member of Staff Neurosurgery, Clinical Professor, Universitaire Ziekenhuizen Leuven

Hyperspectral imaging

Low grade glioma

Tissue discrimination

Additional relevant MeSH terms:

Glioma

Study Results

No Results Posted as of May 18, 2022