Lightfield hyperspectral imaging in neuro-oncology surgery: an IDEAL 0 and 1 study

Hyperspectral imaging (HSI) has shown promise in the field of intra-operative imaging and tissue differentiation as it carries the capability to provide real-time information invisible to the naked eye whilst remaining label free. Previous iterations of intra-operative HSI systems have shown limitat...

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Published in:Frontiers in neuroscience 2023-09, Vol.17, p.1239764
Main Authors: MacCormac, Oscar, Noonan, Philip, Janatka, Mirek, Horgan, Conor C, Bahl, Anisha, Qiu, Jianrong, Elliot, Matthew, Trotouin, Théo, Jacobs, Jaco, Patel, Sabina, Bergholt, Mads S, Ashkan, Keyoumars, Ourselin, Sebastien, Ebner, Michael, Vercauteren, Tom, Shapey, Jonathan
Format: Article
Language:English
Subjects:
Accuracy
Brain cancer
Brain research
Brain tumors
Cerebellum
hyperspectral imaging (HSI)
intra-operative imaging
lightfield camera
Meningioma
neuro-oncology
Neuroimaging
Neuroscience
Neurosurgery
Oncology
Sensors
Spacecraft
Spectrum analysis
Sterility
Surgery
tissue differentiation
Ultrasonic imaging
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Summary:Hyperspectral imaging (HSI) has shown promise in the field of intra-operative imaging and tissue differentiation as it carries the capability to provide real-time information invisible to the naked eye whilst remaining label free. Previous iterations of intra-operative HSI systems have shown limitations, either due to carrying a large footprint limiting ease of use within the confines of a neurosurgical theater environment, having a slow image acquisition time, or by compromising spatial/spectral resolution in favor of improvements to the surgical workflow. Lightfield hyperspectral imaging is a novel technique that has the potential to facilitate video rate image acquisition whilst maintaining a high spectral resolution. Our pre-clinical and first-in-human studies (IDEAL 0 and 1, respectively) demonstrate the necessary steps leading to the first use of a real-time lightfield hyperspectral system in neuro-oncology surgery. A lightfield hyperspectral camera (Cubert Ultris ×50) was integrated in a bespoke imaging system setup so that it could be safely adopted into the open neurosurgical workflow whilst maintaining sterility. Our system allowed the surgeon to capture hyperspectral data (155 bands, 350-1,000 nm) at 1.5 Hz. Following successful implementation in a pre-clinical setup (IDEAL 0), our system was evaluated during brain tumor surgery in a single patient to remove a posterior fossa meningioma (IDEAL 1). Feedback from the theater team was analyzed and incorporated in a follow-up design aimed at implementing an IDEAL 2a study. Focusing on our IDEAL 1 study results, hyperspectral information was acquired from the cerebellum and associated meningioma with minimal disruption to the neurosurgical workflow. To the best of our knowledge, this is the first demonstration of HSI acquisition with 100+ spectral bands at a frame rate over 1Hz in surgery. This work demonstrated that a lightfield hyperspectral imaging system not only meets the design criteria and specifications outlined in an IDEAL-0 (pre-clinical) study, but also that it can translate into clinical practice as illustrated by a successful first in human study (IDEAL 1). This opens doors for further development and optimisation, given the increasing evidence that hyperspectral imaging can provide live, wide-field, and label-free intra-operative imaging and tissue differentiation.
ISSN:1662-4548
1662-453X
1662-453X
DOI:10.3389/fnins.2023.1239764