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7. Imaging Photoplethysmography for Noninvasive Anastomotic Perfusion Assessment in Intestinal Surgery

Author

van der Stel, Stefan D. (author), Lai, Marco (author), Groen, Harald C. (author), Witteveen, Mark (author), Kuhlmann, Koert F.D. (author), Grotenhuis, Brechtje A. (author), Kok, Niels F.M. (author), van Gastel, Mark (author), Hendriks, B.H.W. (author), Ruers, Theo J.M. (author), van der Stel, Stefan D. (author), Lai, Marco (author), Groen, Harald C. (author), Witteveen, Mark (author), Kuhlmann, Koert F.D. (author), Grotenhuis, Brechtje A. (author), Kok, Niels F.M. (author), van Gastel, Mark (author), Hendriks, B.H.W. (author), and Ruers, Theo J.M. (author)

Abstract

Introduction: Anastomotic leakage after gastrointestinal surgery has a high impact on patient's quality of life and its origin is associated with inadequate perfusion. Imaging photoplethysmography (iPPG) is a noninvasive imaging technique that measures blood-volume changes in the microvascular tissue bed and detects changes in tissue perfusion. Materials and methods: Intraoperative iPPG imaging was performed in 29 patients undergoing an open segment resection of the small intestine or colon. During each surgery, imaging was performed on fully perfused (true positives) and ischemic intestines (true negatives) and the anastomosis (unknowns). Imaging consisted of a 30-s video from which perfusion maps were extracted, providing detailed information about blood flow within the intestine microvasculature. To detect the predictive capabilities of iPPG, true positive and true negative perfusion conditions were used to develop two different perfusion classification methods. Results: iPPG-derived perfusion parameters were highly correlated with perfusion—perfused or ischemic—in intestinal tissues. A perfusion confidence map distinguished perfused and ischemic intestinal tissues with 96% sensitivity and 86% specificity. Anastomosis images were scored as adequately perfused in 86% of cases and 14% inconclusive. The cubic-Support Vector Machine achieved 90.9% accuracy and an area under the curve of 96%. No anastomosis-related postoperative complications were encountered in this study. Conclusions: This study shows that noninvasive intraoperative iPPG is suitable for the objective assessment of small intestine and colon anastomotic perfusion. In addition, two perfusion classification methods were developed, providing the first step in an intestinal perfusion prediction model., Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Medical Instruments & Bio-Inspired Technology

Published
2023
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8. Imaging Photoplethysmography for Noninvasive Anastomotic Perfusion Assessment in Intestinal Surgery

Author

van der Stel, Stefan D., Lai, Marco, Groen, Harald C., Witteveen, Mark, Kuhlmann, Koert F.D., Grotenhuis, Brechtje A., Kok, Niels F.M., van Gastel, Mark, Hendriks, Benno H.W., Ruers, Theo J.M., van der Stel, Stefan D., Lai, Marco, Groen, Harald C., Witteveen, Mark, Kuhlmann, Koert F.D., Grotenhuis, Brechtje A., Kok, Niels F.M., van Gastel, Mark, Hendriks, Benno H.W., and Ruers, Theo J.M.

Abstract

Introduction: Anastomotic leakage after gastrointestinal surgery has a high impact on patient's quality of life and its origin is associated with inadequate perfusion. Imaging photoplethysmography (iPPG) is a noninvasive imaging technique that measures blood-volume changes in the microvascular tissue bed and detects changes in tissue perfusion. Materials and methods: Intraoperative iPPG imaging was performed in 29 patients undergoing an open segment resection of the small intestine or colon. During each surgery, imaging was performed on fully perfused (true positives) and ischemic intestines (true negatives) and the anastomosis (unknowns). Imaging consisted of a 30-s video from which perfusion maps were extracted, providing detailed information about blood flow within the intestine microvasculature. To detect the predictive capabilities of iPPG, true positive and true negative perfusion conditions were used to develop two different perfusion classification methods. Results: iPPG-derived perfusion parameters were highly correlated with perfusion—perfused or ischemic—in intestinal tissues. A perfusion confidence map distinguished perfused and ischemic intestinal tissues with 96% sensitivity and 86% specificity. Anastomosis images were scored as adequately perfused in 86% of cases and 14% inconclusive. The cubic-Support Vector Machine achieved 90.9% accuracy and an area under the curve of 96%. No anastomosis-related postoperative complications were encountered in this study. Conclusions: This study shows that noninvasive intraoperative iPPG is suitable for the objective assessment of small intestine and colon anastomotic perfusion. In addition, two perfusion classification methods were developed, providing the first step in an intestinal perfusion prediction model.

Published
2023

10. Multi-modal vision techniques for image-guided surgery

Author

Lai, Marco, de With, Peter H.N., Hendriks, Benno H.W., Shan, Caifeng, Eindhoven MedTech Innovation Center, and Video Coding & Architectures

Subjects
Eindhoven, Netherlands, PPG imaging, Head phantom, Augmented Reality, Minimally invasive surgery, hyperspectral imaging, Intestine surgery, Neurosurgery, Tissue classification, 13.30h, Atlas, room 0.710, TU/e, perfusion monitoring, brain biopsy
Abstract

During minimally-invasive surgery, endoscopes and other surgical tools enter the body of the patient through small openings, allowing the operations to be performed with less post-operative pain and faster recovery for the patient, as well as less wound complications. Although great advantages are achieved from the patient’s point-of-view, several difficulties have still to be handled by the surgeons. First, the limited field of view of the endoscope makes target-area localizations and related identifications complex. Second, surgeons should still match mentally the medical images for the surgical planning with the current patient anatomy. These difficulties can be addressed by using computer vision technologies for guiding surgical procedures. More specifically, this thesis aims at the following three points, the first two for neurosurgery, and the third for perfusion assessment during surgery. The challenges for this dissertation are partitioned in two primary aspects. The first point aims at the fusion of medical images on the endoscopic view, in order to develop an augmented reality system. The second point is based on hyperspectral imaging (HSI), which is compared with diffuse reflectance spectroscopy (DRS), to improve brain tissue classification for neurosurgery. The third point exploits the PPG imaging (iPPG) technique and its potential use is evaluated for peripheral arterial disease (PAD) and organ perfusion assessment during surgery. To address the first point, a new neurosurgical application is implemented on the already existing Philips Augmented Reality (AR) surgical navigation system, designed for spinal surgery. This navigation system incorporates an optical tracking system (OTS) with four video cameras embedded in the flat detector of the motorized C-arm. A hand-eye camera calibration algorithm for the fusion of medical images on the endoscopic view is implemented and integrated into the AR system. This technology is validated for endo-nasal surgery, a neurosurgical procedure for the removal of tumors located at the skull base, such as pituitary tumors. Intra-operative Cone Beam Computed Tomography (CBCT) images are fused with the view of the surgical field obtained by the endoscope camera. The accuracy of CBCT image co-registration is tested, using a custom-made grid with incorporated 3D spheres. The system achieves a sub-millimeter accuracy of image overlay of 0.55 mm, measured as mean target registration error (TRE), with a standard deviation of 0.24 mm. Afterwards, an anatomically realistic head phantom is developed, with materials chosen to achieve both X-ray attenuation and mechanical properties, similar to the real tissue. Using the phantom, a proof of concept of the skull-base surgical simulation is provided, then the accuracy and efficacy of the AR system are evaluated for the insertion of biopsy needles, which is a common neurosurgical procedure that requires high precision. Several 2-mm spherical biopsy targets are inserted inside the brain of the brain phantom. The obtained mean accuracy of the biopsy needle insertions (n=30) is 0.8±0.43 mm, with a mean device insertion time of 155±43 seconds. These experiments demonstrate that a high accuracy is obtained during neurosurgery with the proposed methods and one phantom. For the second point, a near-infrared (NIR) hyperspectral imaging (HSI) sensor is mounted on an endoscope, to explore contactless brain-tissue classification and HSI is compared with diffuse reflectance spectroscopy (DRS), which is an alternative optical technique that requires a probe in contact with the tissue. The classification is performed on ex-vivo porcine brain tissue, which is analyzed and classified in white and gray matter. The HSI reaches a sensitivity of 95% and specificity of 93%, whereas DRS reaches sensitivity and specificity of 96%. The results show that the spectral signature of the tissue in the NIR range contains sufficient information to discriminate brain tissue in white/ gray matter. Further investigation on ex-vivo tumor sample data is required prior to the clinical validation of HSI. The third part concentrates on exploring PPG imaging for extracting perfusion information on tissue. By using an off-the-shelf camera and a light source, the dynamic changes in blood volume are remotely detected beneath the skin and a map is derived correlated to the blood perfusion. After evaluating PPG imaging for local and temporal perfusion-change detections, it is employed for Peripheral Arterial Diseases (PAD) assessment. Reduced blood flow is simulated on 21 volunteers and iPPG is compared with ultrasound and Laser Speckle Contrast Analysis. These experiments show that iPPG can detect reduced perfusion levels and correlates well with the other measurement systems. Finally, this technology is deployed for organ perfusion assessment during intestine surgery. The experiments demonstrate that PPG imaging can be successfully used for extracting perfusion maps from the organ surface, even for detecting perturbations and perfusion changes during several stages of the surgery. The results of this dissertation contribute with novel techniques and approaches to add value to endoscopic and navigation technology systems, as well as to tissue classification and perfusion monitoring, during minimally-invasive surgery. The three main explored research points and their proposed techniques, namely image fusion with the endoscopic view, tissue classification via HSI and PPG imaging for perfusion assessment, can be potentially implemented and combined into a single endoscopic platform, resulting into a new multi-modal endoscopic system. Moreover, the thesis shows that the proposed techniques and algorithms increase the quality of the decision-making process and have the potential to improve the patient surgical outcome.

Published
2022

13. Hyperspectral Imaging for Tissue Classification after Advanced Stage Ovarian Cancer Surgery—A Pilot Study

Author

van Vliet-Pérez, Sharline M., van de Berg, Nick J., Manni, Francesca, Lai, Marco, Rijstenberg, Lucia, Hendriks, Benno H.W., Dankelman, Jenny, Ewing-Graham, Patricia C., Nieuwenhuyzen-de Boer, Gatske M., van Beekhuizen, Heleen J., van Vliet-Pérez, Sharline M., van de Berg, Nick J., Manni, Francesca, Lai, Marco, Rijstenberg, Lucia, Hendriks, Benno H.W., Dankelman, Jenny, Ewing-Graham, Patricia C., Nieuwenhuyzen-de Boer, Gatske M., and van Beekhuizen, Heleen J.

Abstract

The most important prognostic factor for the survival of advanced-stage epithelial ovarian cancer (EOC) is the completeness of cytoreductive surgery (CRS). Therefore, an intraoperative technique to detect microscopic tumors would be of great value. The aim of this pilot study is to assess the feasibility of near-infrared hyperspectral imaging (HSI) for EOC detection in ex vivo tissue samples. Images were collected during CRS in 11 patients in the wavelength range of 665–975 nm, and processed by calibration, normalization, and noise filtering. A linear support vector machine (SVM) was employed to classify healthy and tumorous tissue (defined as >50% tumor cells). Classifier performance was evaluated using leave-one-out cross-validation. Images of 26 tissue samples from 10 patients were included, containing 26,446 data points that were matched to histopathology. Tumorous tissue could be classified with an area under the curve of 0.83, a sensitivity of 0.81, a specificity of 0.70, and Matthew’s correlation coefficient of 0.41. This study paves the way to in vivo and intraoperative use of HSI during CRS. Hyperspectral imaging can scan a whole tissue surface in a fast and non-contact way. Our pilot study demonstrates that HSI and SVM learning can be used to discriminate EOC from surrounding tissue.

Published
2022

14. Imaging PPG for In Vivo Human Tissue Perfusion Assessment during Surgery

Author

Lai, Marco, van der Stel, Stefan D., Groen, Harald C., van Gastel, Mark, Kuhlmann, Koert F.D., Ruers, Theo J.M., Hendriks, Benno H.W., Lai, Marco, van der Stel, Stefan D., Groen, Harald C., van Gastel, Mark, Kuhlmann, Koert F.D., Ruers, Theo J.M., and Hendriks, Benno H.W.

Abstract

Surgical excision is the golden standard for treatment of intestinal tumors. In this surgical procedure, inadequate perfusion of the anastomosis can lead to postoperative complications, such as anastomotic leakages. Imaging photoplethysmography (iPPG) can potentially provide objective and real-time feedback of the perfusion status of tissues. This feasibility study aims to evaluate an iPPG acquisition system during intestinal surgeries to detect the perfusion levels of the microvasculature tissue bed in different perfusion conditions. This feasibility study assesses three patients that underwent resection of a portion of the small intestine. Data was acquired from fully perfused, non-perfused and anastomosis parts of the intestine during different phases of the surgical procedure. Strategies for limiting motion and noise during acquisition were implemented. iPPG perfusion maps were successfully extracted from the intestine microvasculature, demonstrating that iPPG can be successfully used for detecting perturbations and perfusion changes in intestinal tissues during surgery. This study provides proof of concept for iPPG to detect changes in organ perfusion levels.

Published
2022

15. Imaging PPG for In Vivo Human Tissue Perfusion Assessment during Surgery

Author

Lai, Marco (author), van der Stel, Stefan D. (author), Groen, Harald C. (author), van Gastel, Mark (author), Kuhlmann, Koert F.D. (author), Ruers, Theo J.M. (author), Hendriks, B.H.W. (author), Lai, Marco (author), van der Stel, Stefan D. (author), Groen, Harald C. (author), van Gastel, Mark (author), Kuhlmann, Koert F.D. (author), Ruers, Theo J.M. (author), and Hendriks, B.H.W. (author)

Abstract

Surgical excision is the golden standard for treatment of intestinal tumors. In this surgical procedure, inadequate perfusion of the anastomosis can lead to postoperative complications, such as anastomotic leakages. Imaging photoplethysmography (iPPG) can potentially provide objective and real-time feedback of the perfusion status of tissues. This feasibility study aims to evaluate an iPPG acquisition system during intestinal surgeries to detect the perfusion levels of the microvasculature tissue bed in different perfusion conditions. This feasibility study assesses three patients that underwent resection of a portion of the small intestine. Data was acquired from fully perfused, non-perfused and anastomosis parts of the intestine during different phases of the surgical procedure. Strategies for limiting motion and noise during acquisition were implemented. iPPG perfusion maps were successfully extracted from the intestine microvasculature, demonstrating that iPPG can be successfully used for detecting perturbations and perfusion changes in intestinal tissues during surgery. This study provides proof of concept for iPPG to detect changes in organ perfusion levels., Medical Instruments & Bio-Inspired Technology

Published
2022
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16. Tissue-mimicking phantom materials with tunable optical properties suitable for assessment of diffuse reflectance spectroscopy during electrosurgery

Author

Azizian Amiri, S. (author), van Berckel, Pieter (author), Lai, Marco (author), Dankelman, J. (author), Hendriks, B.H.W. (author), Azizian Amiri, S. (author), van Berckel, Pieter (author), Lai, Marco (author), Dankelman, J. (author), and Hendriks, B.H.W. (author)

Abstract

Emerging intraoperative tumor margin assessment techniques require the development of more complex and reliable organ phantoms to assess the performance of the technique before its translation into the clinic. In this work, electrically conductive tissue-mimicking materials (TMMs) based on fat, water and agar/gelatin were produced with tunable optical properties. The composition of the phantoms allowed for the assessment of tumor margins using diffuse reflectance spectroscopy, as the fat/water ratio served as a discriminating factor between the healthy and malignant tissue. Moreover, the possibility of using polyvinyl alcohol (PVA) or transglutaminase in combination with fat, water and gelatin for developing TMMs was studied. The diffuse spectral response of the developed phantom materials had a good match with the spectral response of porcine muscle and adipose tissue, as well as in vitro human breast tissue. Using the developed recipe, anatomically relevant heterogeneous breast phantoms representing the optical properties of different layers of the human breast were fabricated using 3D-printed molds. These TMMs can be used for further development of phantoms applicable for simulating the realistic breast conserving surgery workflow in order to evaluate the intraoperative optical-based tumor margin assessment techniques during electrosurgery., Medical Instruments & Bio-Inspired Technology

Published
2022
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17. Hyperspectral Imaging for Tissue Classification after Advanced Stage Ovarian Cancer Surgery: A Pilot Study

Author

Perez, S.M. (author), van de Berg, N.J. (author), Manni, Francesca (author), Lai, Marco (author), Rijstenberg, Lucia (author), Hendriks, B.H.W. (author), Dankelman, J. (author), Ewing-Graham, Patricia C. (author), Nieuwenhuyzen, G.M. (author), Van Beekhuizen, Heleen J. (author), Perez, S.M. (author), van de Berg, N.J. (author), Manni, Francesca (author), Lai, Marco (author), Rijstenberg, Lucia (author), Hendriks, B.H.W. (author), Dankelman, J. (author), Ewing-Graham, Patricia C. (author), Nieuwenhuyzen, G.M. (author), and Van Beekhuizen, Heleen J. (author)

Abstract

The most important prognostic factor for the survival of advanced-stage epithelial ovarian cancer (EOC) is the completeness of cytoreductive surgery (CRS). Therefore, an intraoperative technique to detect microscopic tumors would be of great value. The aim of this pilot study is to assess the feasibility of near-infrared hyperspectral imaging (HSI) for EOC detection in ex vivo tissue samples. Images were collected during CRS in 11 patients in the wavelength range of 665–975 nm, and processed by calibration, normalization, and noise filtering. A linear support vector machine (SVM) was employed to classify healthy and tumorous tissue (defined as >50% tumor cells). Classifier performance was evaluated using leave-one-out cross-validation. Images of 26 tissue samples from 10 patients were included, containing 26,446 data points that were matched to histopathology. Tumorous tissue could be classified with an area under the curve of 0.83, a sensitivity of 0.81, a specificity of 0.70, and Matthew’s correlation coefficient of 0.41. This study paves the way to in vivo and intraoperative use of HSI during CRS. Hyperspectral imaging can scan a whole tissue surface in a fast and non-contact way. Our pilot study demonstrates that HSI and SVM learning can be used to discriminate EOC from surrounding tissue., Medical Instruments & Bio-Inspired Technology

Published
2022
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18. Diffuse reflectance spectroscopy sensor to differentiate between glial tumor and healthy brain tissue: A proof-of-concept study

Author

Skyrman, Simon, Burström, Gustav, Lai, Marco, Manni, Francesca, Hendriks, Benno H.W., Frostell, Arvid, Edström, Erik, Persson, Oscar, Elmi-Terander, Adrian, Skyrman, Simon, Burström, Gustav, Lai, Marco, Manni, Francesca, Hendriks, Benno H.W., Frostell, Arvid, Edström, Erik, Persson, Oscar, and Elmi-Terander, Adrian

Abstract

Glial tumors grow diffusely in the brain. Survival is correlated to the extent of tumor removal, but tumor borders are often invisible. Resection beyond the borders as defined by conventional methods may further improve prognosis. In this proof-of-concept study, we evaluate diffuse reflectance spectroscopy (DRS) for discrimination between glial tumors and normal brain ex vivo. DRS spectra and histology were acquired from 22 tumor samples and nine brain tissue samples retrieved from 30 patients. The content of biological chromophores and scattering features were estimated by fitting a model derived from diffusion theory to the DRS spectra. DRS parameters differed significantly between tumor and normal brain tissue. Classification using random forest yielded a sensitivity and specificity for the detection of low-grade gliomas of 82.0% and 82.7%, respectively, and the area under curve (AUC) was 0.91. Applied in a hand-held probe or biopsy needle, DRS has the potential to provide intra-operative tissue analysis.

Published
2022

19. Hyperspectral Imaging for Tissue Classification after Advanced Stage Ovarian Cancer Surgery:A Pilot Study

Author

Van Vliet-Perez, Sharline M., van de Berg, Nick J., Manni, Francesca, Lai, Marco, Rijstenberg, Lucia, Hendriks, Benno H. W., Dankelman, Jenny, Ewing-Graham, Patricia C., Nieuwenhuyzen-de Boer, Gatske M., van Beekhuizen, Heleen J., Van Vliet-Perez, Sharline M., van de Berg, Nick J., Manni, Francesca, Lai, Marco, Rijstenberg, Lucia, Hendriks, Benno H. W., Dankelman, Jenny, Ewing-Graham, Patricia C., Nieuwenhuyzen-de Boer, Gatske M., and van Beekhuizen, Heleen J.

Abstract

The most important prognostic factor for the survival of advanced-stage epithelial ovarian cancer (EOC) is the completeness of cytoreductive surgery (CRS). Therefore, an intraoperative technique to detect microscopic tumors would be of great value. The aim of this pilot study is to assess the feasibility of near-infrared hyperspectral imaging (HSI) for EOC detection in ex vivo tissue samples. Images were collected during CRS in 11 patients in the wavelength range of 665–975 nm, and processed by calibration, normalization, and noise filtering. A linear support vector machine (SVM) was employed to classify healthy and tumorous tissue (defined as >50% tumor cells). Classifier performance was evaluated using leave-one-out cross-validation. Images of 26 tissue samples from 10 patients were included, containing 26,446 data points that were matched to histopathology. Tumorous tissue could be classified with an area under the curve of 0.83, a sensitivity of 0.81, a specificity of 0.70, and Matthew’s correlation coefficient of 0.41. This study paves the way to in vivo and intraoperative use of HSI during CRS. Hyperspectral imaging can scan a whole tissue surface in a fast and non-contact way. Our pilot study demonstrates that HSI and SVM learning can be used to discriminate EOC from surrounding tissue.

Published
2022

20. Diffuse reflectance spectroscopy sensor to differentiate between glial tumor and healthy brain tissue: A proof-of-concept study

Author

Skyrman, Simon (author), Burström, Gustav (author), Lai, Marco (author), Manni, Francesca (author), Hendriks, B.H.W. (author), Frostell, Arvid (author), Edström, Erik (author), Persson, Oscar (author), Elmi-Terander, Adrian (author), Skyrman, Simon (author), Burström, Gustav (author), Lai, Marco (author), Manni, Francesca (author), Hendriks, B.H.W. (author), Frostell, Arvid (author), Edström, Erik (author), Persson, Oscar (author), and Elmi-Terander, Adrian (author)

Abstract

Glial tumors grow diffusely in the brain. Survival is correlated to the extent of tumor removal, but tumor borders are often invisible. Resection beyond the borders as defined by conventional methods may further improve prognosis. In this proof-of-concept study, we evaluate diffuse reflectance spectroscopy (DRS) for discrimination between glial tumors and normal brain ex vivo. DRS spectra and histology were acquired from 22 tumor samples and nine brain tissue samples retrieved from 30 patients. The content of biological chromophores and scattering features were estimated by fitting a model derived from diffusion theory to the DRS spectra. DRS parameters differed significantly between tumor and normal brain tissue. Classification using random forest yielded a sensitivity and specificity for the detection of low-grade gliomas of 82.0% and 82.7%, respectively, and the area under curve (AUC) was 0.91. Applied in a hand-held probe or biopsy needle, DRS has the potential to provide intra-operative tissue analysis., Medical Instruments & Bio-Inspired Technology

Published
2022
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21. Development of a CT-Compatible, Anthropomorphic Skull and Brain Phantom for Neurosurgical Planning, Training, and Simulation

Author

Lai, Marco (author), Skyrman, Simon (author), Kor, Flip (author), Homan, Robert (author), El-Hajj, Victor Gabriel (author), Babic, Drazenko (author), Edstrom, Erik (author), Terander, Adrian Elmi (author), Hendriks, B.H.W. (author), De With, Peter H.N. (author), Lai, Marco (author), Skyrman, Simon (author), Kor, Flip (author), Homan, Robert (author), El-Hajj, Victor Gabriel (author), Babic, Drazenko (author), Edstrom, Erik (author), Terander, Adrian Elmi (author), Hendriks, B.H.W. (author), and De With, Peter H.N. (author)

Abstract

Background: Neurosurgical procedures are complex and require years of training and experience. Traditional training on human cadavers is expensive, requires facilities and planning, and raises ethical concerns. Therefore, the use of anthropomorphic phantoms could be an excellent substitute. The aim of the study was to design and develop a patient-specific 3D-skull and brain model with realistic CT-attenuation suitable for conventional and augmented reality (AR)-navigated neurosurgical simulations. Methods: The radiodensity of materials considered for the skull and brain phantoms were investigated using cone beam CT (CBCT) and compared to the radiodensities of the human skull and brain. The mechanical properties of the materials considered were tested in the laboratory and subsequently evaluated by clinically active neurosurgeons. Optimization of the phantom for the intended purposes was performed in a feedback cycle of tests and improvements. Results: The skull, including a complete representation of the nasal cavity and skull base, was 3D printed using polylactic acid with calcium carbonate. The brain was cast using a mixture of water and coolant, with 4 wt% polyvinyl alcohol and 0.1 wt% barium sulfate, in a mold obtained from segmentation of CBCT and T1 weighted MR images from a cadaver. The experiments revealed that the radiodensities of the skull and brain phantoms were 547 and 38 Hounsfield units (HU), as compared to real skull bone and brain tissues with values of around 1300 and 30 HU, respectively. As for the mechanical properties testing, the brain phantom exhibited a similar elasticity to real brain tissue. The phantom was subsequently evaluated by neurosurgeons in simulations of endonasal skull-base surgery, brain biopsies, and external ventricular drain (EVD) placement and found to fulfill the requirements of a surgical phantom. Conclusions: A realistic and CT-compatible anthropomorphic head phantom was designed and successfully used for simulated augmen, Medical Instruments & Bio-Inspired Technology

Published
2022
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24. Hyperspectral Imaging for Tissue Classification after Advanced Stage Ovarian Cancer Surgery—A Pilot Study

Author

van Vliet-Pérez, Sharline M., primary, van de Berg, Nick J., additional, Manni, Francesca, additional, Lai, Marco, additional, Rijstenberg, Lucia, additional, Hendriks, Benno H. W., additional, Dankelman, Jenny, additional, Ewing-Graham, Patricia C., additional, Nieuwenhuyzen-de Boer, Gatske M., additional, and van Beekhuizen, Heleen J., additional

Published
2022
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30. Augmented-reality visualization for improved patient positioning workflow during MR-HIFU therapy

Author

Manni, Francesca, Ferrer, Cyril J., Vincent, Celine E.C., Lai, Marco, Bartels, L.W., Bos, Clemens, van der Sommen, Fons, de With, Peter H.N., Linte, Cristian A., Siewerdsen, Jeffrey H., Center for Care & Cure Technology Eindhoven, Eindhoven MedTech Innovation Center, Video Coding & Architectures, and EAISI Health

Subjects
Image-Guided Therapy, Computer science, Patient Tracking, medicine.medical_treatment, 0206 medical engineering, 02 engineering and technology, Augmented reality, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, MR-HIFU, medicine, Image fusion, Computer vision, Radiation treatment planning, business.industry, 020601 biomedical engineering, Patient tracking, High-intensity focused ultrasound, Visualization, Workflow, Artificial intelligence, business
Abstract

MR-guided high-intensity focused ultrasound (MR-HIFU) is a non-invasive therapeutic technology which has demonstrated clinical potential for tissue ablation. The application of this therapeutic approach facilitated to be a promising option to achieve faster pain palliation in patients with bone metastasis. However, its clinical adoption is still hampered by a lack of workflow integration. Currently, to ensure sufficient positioning, MR images have to be repeatedly acquired in between patient re-positioning tasks, leading to a time-consuming preparation phase of at least 30 minutes, involving extra costs and time to the available treatment time. Augmented reality (AR) is a promising technology that enables the fusion of medical images, such as MRI, with the view of an external camera. AR represents a valid tool for a faster localization and visualization of the lesion during positioning. The aim of this work is the implementation of a novel AR setup for accelerating the patient positioning during MRHIFU treatments by enabling adequate target positioning outside the MRI scanner. A marker-based approach was investigated for fusing the MR data with video data for providing an augmented view. Initial experiments on four volunteers show that MR images were overlaid on the camera views with an average re-projection error of 3.13 mm, which matches the clinical requirements for this specific application. It can be concluded that the implemented system is suitable for MR-HIFU procedures and supports its clinical adoption by improving the patient positioning, thereby offering potential for faster treatment time.

Published
2021

31. Evaluation of a non-contact Photo-Plethysmographic Imaging (iPPG) system for peripheral arterial disease assessment

Author

Lai, Marco, Dicorato, Claudio Spiridione, de Wild, Marco, Verbakel, Frank, Shulepov, Sergei, Groen, Joanneke, Notten, Marc, Lucassen, Gerald, Van Sambeek, Marc R.H.M., Hendriks, B.H.W., de With, Peter H.N., Gimi, Barjor S., Krol, Andrzej, Eindhoven MedTech Innovation Center, Video Coding & Architectures, Photoacoustics & Ultrasound Laboratory Ehv, Cardiovascular Biomechanics, Center for Care & Cure Technology Eindhoven, and EAISI Health

Subjects
iPPG, Blood volume, 02 engineering and technology, 01 natural sciences, perfusion, 010309 optics, Peripheral Arterial Disease, Photoplethysmogram, 0103 physical sciences, Medicine, Plethysmograph, Ankle Brachial Index, non-contact PPG, PPG imaging, business.industry, Ultrasound, Blood flow, perfusion monitoring, 021001 nanoscience & nanotechnology, Peripheral, Percutaneous Transluminal Angioplasty, Circulatory system, ABI, 0210 nano-technology, business, Perfusion, Biomedical engineering
Abstract

Peripheral Artery Diseases (PAD) are caused by the occlusions of arteries in the peripheral locations of the circulatory system. The severity of PAD is usually assessed using the Ankle Brachial Index (ABI) and the Ultrasound Doppler. Non-contact Photoplethysmography (PPG) imaging is a recent emerging technology capable of monitoring skin perfusion. Using an off-The-shelf camera and a light source, is possible to remotely detect the dynamic changes in blood volume in the skin and derive a map correlated to the blood perfusion. The aim of this study is the evaluation of a PPG imaging system (iPPG) for the assessment of Peripheral Arterial Diseases. Reduced blood flow is simulated on 21 volunteers by increasing the pressure in a pressure cuff. For each volunteer, measurements with iPPG, ultrasound, Laser Speckle Contrast Analysis (LASCA) and ABI were acquired. Our experiments show that iPPG can detect reduced perfusion levels, and correlates well with the other measurement systems.

Published
2021

32. Development of a CT-compatible anthropomorphic skull phantom for surgical planning, training, and simulation

Author

Lai, Marco, Skyrman, Simon, Kor, Flip, Homan, Robert, Babic, Drazenko, Edström, Erik, Persson, Oscar, Burström, Gustav, Elmi-Terander, Adrian, Hendriks, B.H.W., De With, Peter H.N., Deserno, Thomas M., Park, Brian J., Eindhoven MedTech Innovation Center, Video Coding & Architectures, Center for Care & Cure Technology Eindhoven, and EAISI Health

Subjects
Human cadaver, 3d printed, medicine.diagnostic_test, Computer science, Brain biopsy, CT compatible phantom, equipment and supplies, Surgical planning, Imaging phantom, Skull, medicine.anatomical_structure, Anthropomorphic phantom, Cadaver, medicine, otorhinolaryngologic diseases, endo-nasal skull-base surgery, brain biopsy, skull phantom, Biomedical engineering, neurosurgical simulation
Abstract

Neurosurgical training is performed on human cadavers and simulation models, such as VR platforms, which have several drawbacks. Head phantoms could solve most of the issues related to these trainings. The aim of this study was to design a realistic and CT-compatible head phantom, with a specific focus on endo-nasal skull-base surgery and brain biopsy. A head phantom was created by segmenting an image dataset from a cadaver. The skull, which includes a complete structure of the nasal cavity and detailed skull-base anatomy, is 3D printed using PLA with calcium, while the brain is produced using a PVA mixture. The radiodensity and mechanical properties of the phantom were tested and adjusted in material choice to mimic real-life conditions. Surgeons find the skull, the structures at the skull-base and the brain realistically reproduced. The head phantom can be employed for neurosurgical education, training and surgical planning, and can be successfully used for simulating surgeries.

Published
2021

33. Development of a CT-compatible anthropomorphic skull phantom for surgical planning, training, and simulation

Author

Lai, Marco (author), Skyrman, Simon (author), Kor, Flip (author), Homan, Robert (author), Babic, Drazenko (author), Edström, Erik (author), Persson, Oscar (author), Burström, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), De With, Peter H.N. (author), Lai, Marco (author), Skyrman, Simon (author), Kor, Flip (author), Homan, Robert (author), Babic, Drazenko (author), Edström, Erik (author), Persson, Oscar (author), Burström, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), and De With, Peter H.N. (author)

Abstract

Neurosurgical training is performed on human cadavers and simulation models, such as VR platforms, which have several drawbacks. Head phantoms could solve most of the issues related to these trainings. The aim of this study was to design a realistic and CT-compatible head phantom, with a specific focus on endo-nasal skull-base surgery and brain biopsy. A head phantom was created by segmenting an image dataset from a cadaver. The skull, which includes a complete structure of the nasal cavity and detailed skull-base anatomy, is 3D printed using PLA with calcium, while the brain is produced using a PVA mixture. The radiodensity and mechanical properties of the phantom were tested and adjusted in material choice to mimic real-life conditions. Surgeons find the skull, the structures at the skull-base and the brain realistically reproduced. The head phantom can be employed for neurosurgical education, training and surgical planning, and can be successfully used for simulating surgeries., Medical Instruments & Bio-Inspired Technology

Published
2021
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34. Evaluation of a non-contact Photo-Plethysmographic Imaging (iPPG) system for peripheral arterial disease assessment

Author

Lai, Marco (author), Dicorato, Claudio Spiridione (author), de Wild, Marco (author), Verbakel, Frank (author), Shulepov, Sergei (author), Groen, Joanneke (author), Notten, Marc (author), Lucassen, Gerald (author), Van Sambeek, Marc R.H.M. (author), Hendriks, B.H.W. (author), de With, Peter H.N. (author), Lai, Marco (author), Dicorato, Claudio Spiridione (author), de Wild, Marco (author), Verbakel, Frank (author), Shulepov, Sergei (author), Groen, Joanneke (author), Notten, Marc (author), Lucassen, Gerald (author), Van Sambeek, Marc R.H.M. (author), Hendriks, B.H.W. (author), and de With, Peter H.N. (author)

Abstract

Peripheral Artery Diseases (PAD) are caused by the occlusions of arteries in the peripheral locations of the circulatory system. The severity of PAD is usually assessed using the Ankle Brachial Index (ABI) and the Ultrasound Doppler. Non-contact Photoplethysmography (PPG) imaging is a recent emerging technology capable of monitoring skin perfusion. Using an off-The-shelf camera and a light source, is possible to remotely detect the dynamic changes in blood volume in the skin and derive a map correlated to the blood perfusion. The aim of this study is the evaluation of a PPG imaging system (iPPG) for the assessment of Peripheral Arterial Diseases. Reduced blood flow is simulated on 21 volunteers by increasing the pressure in a pressure cuff. For each volunteer, measurements with iPPG, ultrasound, Laser Speckle Contrast Analysis (LASCA) and ABI were acquired. Our experiments show that iPPG can detect reduced perfusion levels, and correlates well with the other measurement systems., Medical Instruments & Bio-Inspired Technology

Published
2021
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35. Cutaneous squamous cell carcinoma in patients with chronic lymphocytic leukemia: a systematic review of the literature

Author

Lai, Marco, Pampena, R., Cornacchia, Luigi, Odorici, G., Piccerillo, Alfredo, Pellacani, G., Peris, Ketty, Longo, Carmela, Lai M., Cornacchia L., Piccerillo A., Peris K. (ORCID:0000-0002-5237-0463), Longo C., Lai, Marco, Pampena, R., Cornacchia, Luigi, Odorici, G., Piccerillo, Alfredo, Pellacani, G., Peris, Ketty, Longo, Carmela, Lai M., Cornacchia L., Piccerillo A., Peris K. (ORCID:0000-0002-5237-0463), and Longo C.

Abstract

The continuous improvement of life expectancy of patients with chronic lymphocytic leukemia (CLL) has resulted in increased risk of second primary malignancy that potentially may affect survival and quality of life of CLL patients. We performed a systematic review to assess the risk and the clinical-pathological features and prognosis of cutaneous squamous cell carcinoma (cSCC) in patients with CLL. We searched PubMed, Embase, and Cochrane Central Register of Control Trials databases for articles published from database inception to December 31, 2019. English-language studies reporting original data on patients with a specific diagnosis of CLL and cSCC were included. Data were extracted using a standardized extraction form, and any discordance was resolved by consensus. Descriptive data were generated by pooling patients from eligible studies. Of the 4588 non-duplicate records identified, 55 articles met our inclusion criteria. These studies reported that CLL patients have a 3.2% prevalence of cSCC, with an 11.5% cSCC-related lethality and an overall risk of metastasis of 5.7% (7.3% for regional lymph node involvement and 3.8% for distant metastasis). The quality of evidence was limited by the high heterogeneity in the design, populations, and objectives of the included studies. This systematic review suggests that cSCC in CLL patients tends to behave less aggressively compared with the solid organ transplant recipients but has a higher morbidity and mortality than in the general population. Future prospective studies are needed to increase the quality of evidence and to determine the best treatment modalities and screening intervals for these patients.

Published
2021

36. Automated classification of brain tissue: comparison between hyperspectral imaging and diffuse reflectance spectroscopy

Author

Lai, Marco, Skyrman, Simon, Shan, Caifeng, Paulussen, Elvira, Manni, Francesca, Swamy, A., Babic, Drazenko, Edstrom, Erik, Persson, Oscar, Burstrom, Gustav, Elmi-Terander, Adrian, Hendriks, B.H.W., De With, Peter H.N., Fei, Baowei, Linte, Cristian A., Video Coding & Architectures, Center for Care & Cure Technology Eindhoven, and EAISI Health

Subjects
Spectral signature, Brain surgery, Contextual image classification, Diffuse reflectance infrared fourier transform, Hyperspectral imaging, Computer science, Image classification, 010401 analytical chemistry, Neurosurgery, Tissue classification, 020206 networking & telecommunications, 02 engineering and technology, Brain tissue, 01 natural sciences, 0104 chemical sciences, Support vector machine, Image-guided surgery, Machine learning, 0202 electrical engineering, electronic engineering, information engineering, Diffuse reflectance spectroscopy, Image sensor, Biomedical engineering
Abstract

In neurosurgery, technical solutions for visualizing the border between healthy brain and tumor tissue is of great value, since they enable the surgeon to achieve gross total resection while minimizing the risk of damage to eloquent areas. By using real-time non-ionizing imaging techniques, such as hyperspectral imaging (HSI), the spectral signature of the tissue is analyzed allowing tissue classification, thereby improving tumor boundary discrimination during surgery. More particularly, since infrared penetrates deeper in the tissue than visible light, the use of an imaging sensor sensitive to the near-infrared wavelength range would also allow the visualization of structures slightly beneath the tissue surface. This enables the visualization of tumors and vessel boundaries prior to surgery, thereby preventing the damaging of tissue structures. In this study, we investigate the use of Diffuse Reflectance Spectroscopy (DRS) and HSI for brain tissue classification, by extracting spectral features from the near infra-red range. The applied method for classification is the linear Support Vector Machine (SVM). The study is conducted on ex-vivo porcine brain tissue, which is analyzed and classified as either white or gray matter. The DRS combined with the proposed classification reaches a sensitivity and specificity of 96%, while HSI reaches a sensitivity of 95% and specificity of 93%. This feasibility study shows the potential of DRS and HSI for automated tissue classification, and serves as a fjrst step towards clinical use for tumor detection deeper inside the tissue.

Published
2020

37. Fusion of augmented reality imaging with the endoscopic view for endonasal skull base surgery: a novel application for surgical navigation based on intraoperative cone beam computed tomography and optical tracking

Author

Lai, Marco, Skyrman, Simon, Shan, Caifeng, Babic, Drazenko, Homan, Robert, Edström, Erik, Persson, Oscar, Burström, Gustav, Elmi-Terander, Adrian, Hendriks, B.H.W., and de With, Peter H.N.

Abstract

OBJECTIVE: Surgical navigation is a well-established tool in endoscopic skull base surgery. However, navigational and endoscopic views are usually displayed on separate monitors, forcing the surgeon to focus on one or the other. Aiming to provide real-time integration of endoscopic and diagnostic imaging information, we present a new navigation technique based on augmented reality with fusion of intraoperative cone beam computed tomography (CBCT) on the endoscopic view. The aim of this study was to evaluate the accuracy of the method. MATERIAL AND METHODS: An augmented reality surgical navigation system (ARSN) with 3D CBCT capability was used. The navigation system incorporates an optical tracking system (OTS) with four video cameras embedded in the flat detector of the motorized C-arm. Intra-operative CBCT images were fused with the view of the surgical field obtained by the endoscope's camera. Accuracy of CBCT image co-registration was tested using a custom-made grid with incorporated 3D spheres. RESULTS: Co-registration of the CBCT image on the endoscopic view was performed. Accuracy of the overlay, measured as mean target registration error (TRE), was 0.55 mm with a standard deviation of 0.24 mm and with a median value of 0.51mm and interquartile range of 0.39--0.68 mm. CONCLUSION: We present a novel augmented reality surgical navigation system, with fusion of intraoperative CBCT on the endoscopic view. The system shows sub-millimeter accuracy.

Published
2020

38. Automated classification of brain tissue: Comparison between hyperspectral imaging and diffuse reflectance spectroscopy

Author

Lai, Marco (author), Skyrman, Simon (author), Shan, Caifeng (author), Paulussen, Elvira (author), Manni, Francesca (author), Swamy, A. (author), Babic, Drazenko (author), Edstrom, Erik (author), Persson, Oscar (author), Burstrom, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), De With, Peter H.N. (author), Lai, Marco (author), Skyrman, Simon (author), Shan, Caifeng (author), Paulussen, Elvira (author), Manni, Francesca (author), Swamy, A. (author), Babic, Drazenko (author), Edstrom, Erik (author), Persson, Oscar (author), Burstrom, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), and De With, Peter H.N. (author)

Abstract

In neurosurgery, technical solutions for visualizing the border between healthy brain and tumor tissue is of great value, since they enable the surgeon to achieve gross total resection while minimizing the risk of damage to eloquent areas. By using real-time non-ionizing imaging techniques, such as hyperspectral imaging (HSI), the spectral signature of the tissue is analyzed allowing tissue classification, thereby improving tumor boundary discrimination during surgery. More particularly, since infrared penetrates deeper in the tissue than visible light, the use of an imaging sensor sensitive to the near-infrared wavelength range would also allow the visualization of structures slightly beneath the tissue surface. This enables the visualization of tumors and vessel boundaries prior to surgery, thereby preventing the damaging of tissue structures. In this study, we investigate the use of Diffuse Reflectance Spectroscopy (DRS) and HSI for brain tissue classification, by extracting spectral features from the near infra-red range. The applied method for classification is the linear Support Vector Machine (SVM). The study is conducted on ex-vivo porcine brain tissue, which is analyzed and classified as either white or gray matter. The DRS combined with the proposed classification reaches a sensitivity and specificity of 96%, while HSI reaches a sensitivity of 95% and specificity of 93%. This feasibility study shows the potential of DRS and HSI for automated tissue classification, and serves as a fjrst step towards clinical use for tumor detection deeper inside the tissue., Medical Instruments & Bio-Inspired Technology

Published
2020
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39. Fusion of augmented reality imaging with the endoscopic view for endonasal skull base surgery: a novel application for surgical navigation based on intraoperative cone beam computed tomography and optical tracking

Author

Lai, Marco (author), Skyrman, Simon (author), Shan, Caifeng (author), Babic, Drazenko (author), Homan, Robert (author), Edström, Erik (author), Persson, Oscar (author), Burström, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), de With, Peter H.N. (author), Lai, Marco (author), Skyrman, Simon (author), Shan, Caifeng (author), Babic, Drazenko (author), Homan, Robert (author), Edström, Erik (author), Persson, Oscar (author), Burström, Gustav (author), Elmi-Terander, Adrian (author), Hendriks, B.H.W. (author), and de With, Peter H.N. (author)

Abstract

OBJECTIVE: Surgical navigation is a well-established tool in endoscopic skull base surgery. However, navigational and endoscopic views are usually displayed on separate monitors, forcing the surgeon to focus on one or the other. Aiming to provide real-time integration of endoscopic and diagnostic imaging information, we present a new navigation technique based on augmented reality with fusion of intraoperative cone beam computed tomography (CBCT) on the endoscopic view. The aim of this study was to evaluate the accuracy of the method. MATERIAL AND METHODS: An augmented reality surgical navigation system (ARSN) with 3D CBCT capability was used. The navigation system incorporates an optical tracking system (OTS) with four video cameras embedded in the flat detector of the motorized C-arm. Intra-operative CBCT images were fused with the view of the surgical field obtained by the endoscope's camera. Accuracy of CBCT image co-registration was tested using a custom-made grid with incorporated 3D spheres. RESULTS: Co-registration of the CBCT image on the endoscopic view was performed. Accuracy of the overlay, measured as mean target registration error (TRE), was 0.55 mm with a standard deviation of 0.24 mm and with a median value of 0.51mm and interquartile range of 0.39--0.68 mm. CONCLUSION: We present a novel augmented reality surgical navigation system, with fusion of intraoperative CBCT on the endoscopic view. The system shows sub-millimeter accuracy., Correction: https://doi.org/10.1371/journal.pone.0229454, Medical Instruments & Bio-Inspired Technology

Published
2020
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40. Evaluation of a non-contact Photo-Plethysmographic Imaging (iPPG) system for peripheral arterial disease assessment

Author

Lai, Marco, primary, Dicorato, Claudio Spiridione, additional, de Wild, Marco, additional, Verbakel, Frank, additional, Shulepov, Sergei, additional, Groen, Joanneke, additional, Notten, Marc, additional, Lucassen, Gerald, additional, van Sambeek, Marc R. H. M., additional, Hendriks, Benno H. W., additional, and de With, Peter H. N., additional

Published
2021
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44. Automated classification of brain tissue: comparison between hyperspectral imaging and diffuse reflectance spectroscopy

Author

Lai, Marco, primary, Skyrman, Simon, additional, Shan, Caifeng, additional, Paulussen, Elvira, additional, Manni, Francesca, additional, Swamy, Akash, additional, Babic, Drazenko, additional, Edström, Erik, additional, Persson, Oscar, additional, Burström, Gustav, additional, Elmi Terander, Adrian, additional, Hendriks, Benno H. W., additional, and de With, Peter H. N., additional

Published
2020
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46. Correction: Fusion of augmented reality imaging with the endoscopic view for endonasal skull base surgery; a novel application for surgical navigation based on intraoperative cone beam computed tomography and optical tracking

Author

Lai, Marco, primary, Skyrman, Simon, additional, Shan, Caifeng, additional, Babic, Drazenko, additional, Homan, Robert, additional, Edström, Erik, additional, Persson, Oscar, additional, Burström, Gustav, additional, Elmi-Terander, Adrian, additional, Hendriks, Benno H. W., additional, and de With, Peter H. N., additional

Published
2020
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49. Image fusion on the endoscopic view for endo-nasal skull-base surgery

Author

Lai, Marco, Shan, Caifeng, Babic, Drazenko, Homan, Robert, Terander, Adrian Elmi, Edstrom, Erik, Persson, Oscar, Burstrom, Gustav, de With, Peter H.N., Fei, Baowei, Linte, Cristian A., and Video Coding & Architectures

Subjects
Cone beam computed tomography, Endoscope, Computer science, Augmented reality, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, minimally-invasive neurosurgery, medicine, Image fusion, Image-guided surgery, Computer vision, Endoscopic camera, 030223 otorhinolaryngology, business.industry, Navigation system, Skull, skull-base surgery, medicine.anatomical_structure, Surgical navigation system, Artificial intelligence, business
Abstract

The use of pre-operative CT and MR images for navigation during endo-nasal skull-base endoscopic surgery is a well-established procedure in clinical practice. Fusion of CT and MR images on the endoscopic view can offer an additional advantage by directly overlaying surgical-planning information in the surgical view. Fusion of intraoperative images, such as cone beam computed tomography (CBCT), represents a step forward since these images can also account for intra-operative anatomical changes. In this work, we present a method for intra-operative CBCT image fusion on the endoscopic view for endo-nasal skull-base surgery, implemented on the Philips surgical navigation system. This is the first study which utilizes an optical tracking system (OTS) embedded in the flat-panel detector of the C-arm for endoscopic-image augmentation. In our method the OTS, co-registered in the same CBCT coordinate system, is used for tracking the endoscope. Accuracy in CBCT image registration in the endoscopic view is studied using a calibration board. Image fusion is tested in a realistic surgical scenario by using a skull phantom and inserts that mimic critical structures at the skull base. Overall performances tested on the skull phantom show a high accuracy in tracking the endoscope and registration of CBCT on endoscopic view. It can be concluded that the implemented system show potential for usage in endo-nasal skull-base surgery.

Published
2019
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