A coaxial excitation, dual-red-green-blue/near-infrared paired imaging system toward computer-aided detection of parathyroid glands in situ and ex vivo

Yoseph Kim; Hun Chan Lee; Jongchan Kim; Eugene Oh; Jennifer Yoo; Bo Ning; Seung Yup Lee; Khalid Mohamed Ali; Ralph P. Tufano; Jonathon O. Russell; Jaepyeong Cha

doi:10.1002/jbio.202200008

A coaxial excitation, dual-red-green-blue/near-infrared paired imaging system toward computer-aided detection of parathyroid glands in situ and ex vivo

Yoseph Kim, Hun Chan Lee, Jongchan Kim, Eugene Oh, Jennifer Yoo, Bo Ning, Seung Yup Lee, Khalid Mohamed Ali, Ralph P. Tufano, Jonathon O. Russell, Jaepyeong Cha

School of Medicine

Research output: Contribution to journal › Article › peer-review

Abstract

Early and precise detection of parathyroid glands (PGs) is a challenging problem in thyroidectomy due to their small size and similar appearance to surrounding tissues. Near-infrared autofluorescence (NIRAF) has stimulated interest as a method to localize PGs. However, high incidence of false positives for PGs has been reported with this technique. We introduce a prototype equipped with a coaxial excitation light (785 nm) and a dual-sensor to address the issue of false positives with the NIRAF technique. We test the clinical feasibility of our prototype in situ and ex vivo using sterile drapes on 10 human subjects. Video data (1287 images) of detected PGs were collected to train, validate and compare the performance for PG detection. We achieved a mean average precision of 94.7% and a 19.5-millisecond processing time/detection. This feasibility study supports the effectiveness of the optical design and may open new doors for a deep learning-based PG detection method.

Original language	English (US)
Article number	e202200008
Journal	Journal of biophotonics
Volume	15
Issue number	8
DOIs	https://doi.org/10.1002/jbio.202200008
State	Published - Aug 2022

Keywords

deep learning
hypocalcemia
near-infrared autofluorescence
parathyroid glands
thyroid surgery

ASJC Scopus subject areas

General Engineering
General Physics and Astronomy
General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Materials Science

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10.1002/jbio.202200008

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Kim, Y., Lee, H. C., Kim, J., Oh, E., Yoo, J., Ning, B., Lee, S. Y., Ali, K. M., Tufano, R. P., Russell, J. O., & Cha, J. (2022). A coaxial excitation, dual-red-green-blue/near-infrared paired imaging system toward computer-aided detection of parathyroid glands in situ and ex vivo. Journal of biophotonics, 15(8), Article e202200008. https://doi.org/10.1002/jbio.202200008

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title = "A coaxial excitation, dual-red-green-blue/near-infrared paired imaging system toward computer-aided detection of parathyroid glands in situ and ex vivo",

abstract = "Early and precise detection of parathyroid glands (PGs) is a challenging problem in thyroidectomy due to their small size and similar appearance to surrounding tissues. Near-infrared autofluorescence (NIRAF) has stimulated interest as a method to localize PGs. However, high incidence of false positives for PGs has been reported with this technique. We introduce a prototype equipped with a coaxial excitation light (785 nm) and a dual-sensor to address the issue of false positives with the NIRAF technique. We test the clinical feasibility of our prototype in situ and ex vivo using sterile drapes on 10 human subjects. Video data (1287 images) of detected PGs were collected to train, validate and compare the performance for PG detection. We achieved a mean average precision of 94.7% and a 19.5-millisecond processing time/detection. This feasibility study supports the effectiveness of the optical design and may open new doors for a deep learning-based PG detection method.",

keywords = "deep learning, hypocalcemia, near-infrared autofluorescence, parathyroid glands, thyroid surgery",

author = "Yoseph Kim and Lee, {Hun Chan} and Jongchan Kim and Eugene Oh and Jennifer Yoo and Bo Ning and Lee, {Seung Yup} and Ali, {Khalid Mohamed} and Tufano, {Ralph P.} and Russell, {Jonathon O.} and Jaepyeong Cha",

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month = aug,

doi = "10.1002/jbio.202200008",

language = "English (US)",

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AU - Kim, Jongchan

AU - Oh, Eugene

AU - Yoo, Jennifer

AU - Ning, Bo

AU - Lee, Seung Yup

AU - Ali, Khalid Mohamed

AU - Tufano, Ralph P.

AU - Russell, Jonathon O.

AU - Cha, Jaepyeong

PY - 2022/8

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N2 - Early and precise detection of parathyroid glands (PGs) is a challenging problem in thyroidectomy due to their small size and similar appearance to surrounding tissues. Near-infrared autofluorescence (NIRAF) has stimulated interest as a method to localize PGs. However, high incidence of false positives for PGs has been reported with this technique. We introduce a prototype equipped with a coaxial excitation light (785 nm) and a dual-sensor to address the issue of false positives with the NIRAF technique. We test the clinical feasibility of our prototype in situ and ex vivo using sterile drapes on 10 human subjects. Video data (1287 images) of detected PGs were collected to train, validate and compare the performance for PG detection. We achieved a mean average precision of 94.7% and a 19.5-millisecond processing time/detection. This feasibility study supports the effectiveness of the optical design and may open new doors for a deep learning-based PG detection method.

AB - Early and precise detection of parathyroid glands (PGs) is a challenging problem in thyroidectomy due to their small size and similar appearance to surrounding tissues. Near-infrared autofluorescence (NIRAF) has stimulated interest as a method to localize PGs. However, high incidence of false positives for PGs has been reported with this technique. We introduce a prototype equipped with a coaxial excitation light (785 nm) and a dual-sensor to address the issue of false positives with the NIRAF technique. We test the clinical feasibility of our prototype in situ and ex vivo using sterile drapes on 10 human subjects. Video data (1287 images) of detected PGs were collected to train, validate and compare the performance for PG detection. We achieved a mean average precision of 94.7% and a 19.5-millisecond processing time/detection. This feasibility study supports the effectiveness of the optical design and may open new doors for a deep learning-based PG detection method.

KW - deep learning

KW - hypocalcemia

KW - near-infrared autofluorescence

KW - parathyroid glands

KW - thyroid surgery

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A coaxial excitation, dual-red-green-blue/near-infrared paired imaging system toward computer-aided detection of parathyroid glands in situ and ex vivo

Abstract

Keywords

ASJC Scopus subject areas

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