Matthew Tucker1, Guangshen Ma1, Weston Ross2, Daniel M Buckland1,3, Patrick J Codd1,3. 1. Department of Mechanical Engineering and Materials ScienceDuke University Durham NC 27708 USA. 2. Department of NeurosurgeryDuke University Durham NC 27708 USA. 3. Division of Emergency MedicineDuke University Durham NC 27708 USA.
Abstract
OBJECTIVE: Create a device that improves the identification and extent of resection at the interface between healthy and tumor tissue; ultimately, using this device would improve surgical outcomes for patients and increase survival. METHODS: We have created a contactless tumor removal system that utilizes endogenous fluorescence feedback to inform a laser ablation system to execute autonomous removal of phantom tumor tissue. RESULTS: This completely non-contact surgical system is capable of resecting the tumor boundary of a tissue phantom with an average root mean square error (RMSE) of approximately 1.55 mm and an average max error of approximately 2.15 mm. There is no difference in the performance of the system when changing the size of the internal tumor from 7.5-12.5 mm in diameter. DISCUSSION: Future research steps include creating a more intelligent spectral search strategy to increase the density of points around the resection boundary, and to develop a more sophisticated classifier to predict pathologic diagnosis and tissue subtypes located regionally around the tumor boundaries. We envision this device being used to resect the boundaries of tumors identified by exogenously delivered tumor-labeling fluorophores, such as fluorescein or 5-ALA, in addition to approaches relying on autofluorescence of endogenous fluorophores.
OBJECTIVE: Create a device that improves the identification and extent of resection at the interface between healthy and tumor tissue; ultimately, using this device would improve surgical outcomes for patients and increase survival. METHODS: We have created a contactless tumor removal system that utilizes endogenous fluorescence feedback to inform a laser ablation system to execute autonomous removal of phantom tumor tissue. RESULTS: This completely non-contact surgical system is capable of resecting the tumor boundary of a tissue phantom with an average root mean square error (RMSE) of approximately 1.55 mm and an average max error of approximately 2.15 mm. There is no difference in the performance of the system when changing the size of the internal tumor from 7.5-12.5 mm in diameter. DISCUSSION: Future research steps include creating a more intelligent spectral search strategy to increase the density of points around the resection boundary, and to develop a more sophisticated classifier to predict pathologic diagnosis and tissue subtypes located regionally around the tumor boundaries. We envision this device being used to resect the boundaries of tumors identified by exogenously delivered tumor-labeling fluorophores, such as fluorescein or 5-ALA, in addition to approaches relying on autofluorescence of endogenous fluorophores.
Entities:
Keywords:
Automated surgery; cancer detection; surgical sensor fusion; tumor ablation
Authors: Hsiu-Yin Chiang; Aparna S Kamath; Jean M Pottinger; Jeremy D W Greenlee; Matthew A Howard; Joseph E Cavanaugh; Loreen A Herwaldt Journal: J Neurosurg Date: 2013-11-08 Impact factor: 5.115
Authors: Julie Hanson Ostrander; Christine M McMahon; Siya Lem; Stacy R Millon; J Quincy Brown; Victoria L Seewaldt; Nimmi Ramanujam Journal: Cancer Res Date: 2010-05-11 Impact factor: 12.701