Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help?

Raphael Bechtold; Niki Tselepidakis; Benjamin Garlow; Sean Glaister; William Zhu; Renee Liu; Alexandra Szewc; Arushi Tandon; Zachary Buono; James Pitingolo; Cristina Madalo; Isabella Ferrara; Collin Shale; Thomas Benassi; Micah Belzberg; Noah Gorelick; Brian Hwang; Camilo A. Molina; George Coles; Betty Tyler; Ian Suk; Judy Huang; Henry Brem; Amir Manbachi

doi:10.1117/12.2548847

Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help?

Raphael Bechtold, Niki Tselepidakis, Benjamin Garlow, Sean Glaister, William Zhu, Renee Liu, Alexandra Szewc, Arushi Tandon, Zachary Buono, James Pitingolo, Cristina Madalo, Isabella Ferrara, Collin Shale, Thomas Benassi, Micah Belzberg, Noah Gorelick, Brian Hwang, Camilo A. Molina, George Coles, Betty TylerIan Suk, Judy Huang, Henry Brem, Amir Manbachi

School of Medicine

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Cotton balls are used in neurosurgical procedures to assist with hemostasis and improve vision within the operative field. Although the surgeon can reshape pieces of cotton for multiple intraoperative uses, this customizability and scale also places them at perpetual risk of being lost, as blood-soaked cotton balls are visually similar to raw brain tissue. Retained surgical cotton can induce potentially life-threatening immunologic responses, impair postoperative imaging, lead to a textiloma or misdiagnosis, and/or require reoperation. This study investigated three imaging modalities (optical, acoustic, and radiographic) to find the most effective method of identifying foreign bodies during neurosurgery. First, we examined the use of dyes to increase contrast between cotton and surrounding parenchyma (optical approach). Second, we explored the ability to distinguish surgical cotton on or below the tissue surface from brain parenchyma using ultrasound imaging (acoustic approach). Lastly, we analyzed the ability of radiography to differentiate between brain parenchyma and cotton. Our preliminary testing demonstrated that dark-colored cotton is significantly more identifiable than white cotton on the surface level. Additional testing revealed that cotton has noticeable different acoustic characteristics (eg, speed of sound, absorption) from neural tissue, allowing for enhanced contrast in applied ultrasound imaging. Radiography, however, did not present sufficient contrast, demanding further examination. These solutions have the potential to significantly reduce the possibility of intraoperative cotton retention both on and below the surface of the brain, while still providing surgeons with traditional cotton material properties without affecting the surgical workflow.

Original language	English (US)
Title of host publication	Medical Imaging 2020
Subtitle of host publication	Biomedical Applications in Molecular, Structural, and Functional Imaging
Editors	Andrzej Krol, Barjor S. Gimi
Publisher	SPIE
ISBN (Electronic)	9781510634015
DOIs	https://doi.org/10.1117/12.2548847
State	Published - 2020
Event	Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging - Houston, United States Duration: Feb 18 2020 → Feb 20 2020

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volume	11317
ISSN (Print)	1605-7422

Conference

Conference	Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging
Country/Territory	United States
City	Houston
Period	2/18/20 → 2/20/20

Keywords

Brain surgery
Contrast
Cotton balls
Detectability
Gossypiboma
Medical imaging
Optics
Retained foreign object
Textiloma
Ultrasound
X-ray

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Biomaterials
Radiology Nuclear Medicine and imaging

Access to Document

10.1117/12.2548847

Cite this

Bechtold, R., Tselepidakis, N., Garlow, B., Glaister, S., Zhu, W., Liu, R., Szewc, A., Tandon, A., Buono, Z., Pitingolo, J., Madalo, C., Ferrara, I., Shale, C., Benassi, T., Belzberg, M., Gorelick, N., Hwang, B., Molina, C. A., Coles, G., ... Manbachi, A. (2020). Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help? In A. Krol, & B. S. Gimi (Eds.), Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging Article 1131704 (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 11317). SPIE. https://doi.org/10.1117/12.2548847

Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help? / Bechtold, Raphael; Tselepidakis, Niki; Garlow, Benjamin et al.
Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging. ed. / Andrzej Krol; Barjor S. Gimi. SPIE, 2020. 1131704 (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 11317).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Bechtold, R, Tselepidakis, N, Garlow, B, Glaister, S, Zhu, W, Liu, R, Szewc, A, Tandon, A, Buono, Z, Pitingolo, J, Madalo, C, Ferrara, I, Shale, C, Benassi, T, Belzberg, M, Gorelick, N, Hwang, B, Molina, CA, Coles, G, Tyler, B , Suk, I , Huang, J , Brem, H & Manbachi, A 2020, Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help? in A Krol & BS Gimi (eds), Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging., 1131704, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 11317, SPIE, Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging, Houston, United States, 2/18/20. https://doi.org/10.1117/12.2548847

Bechtold R, Tselepidakis N, Garlow B, Glaister S, Zhu W, Liu R et al. Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help? In Krol A, Gimi BS, editors, Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging. SPIE. 2020. 1131704. (Progress in Biomedical Optics and Imaging - Proceedings of SPIE). doi: 10.1117/12.2548847

Bechtold, Raphael ; Tselepidakis, Niki ; Garlow, Benjamin et al. / Minimizing cotton retention in neurosurgical procedures : Which imaging modality can help?. Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging. editor / Andrzej Krol ; Barjor S. Gimi. SPIE, 2020. (Progress in Biomedical Optics and Imaging - Proceedings of SPIE).

@inproceedings{d5d3e595c6ad4d77af058e517959177a,

title = "Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help?",

abstract = "Cotton balls are used in neurosurgical procedures to assist with hemostasis and improve vision within the operative field. Although the surgeon can reshape pieces of cotton for multiple intraoperative uses, this customizability and scale also places them at perpetual risk of being lost, as blood-soaked cotton balls are visually similar to raw brain tissue. Retained surgical cotton can induce potentially life-threatening immunologic responses, impair postoperative imaging, lead to a textiloma or misdiagnosis, and/or require reoperation. This study investigated three imaging modalities (optical, acoustic, and radiographic) to find the most effective method of identifying foreign bodies during neurosurgery. First, we examined the use of dyes to increase contrast between cotton and surrounding parenchyma (optical approach). Second, we explored the ability to distinguish surgical cotton on or below the tissue surface from brain parenchyma using ultrasound imaging (acoustic approach). Lastly, we analyzed the ability of radiography to differentiate between brain parenchyma and cotton. Our preliminary testing demonstrated that dark-colored cotton is significantly more identifiable than white cotton on the surface level. Additional testing revealed that cotton has noticeable different acoustic characteristics (eg, speed of sound, absorption) from neural tissue, allowing for enhanced contrast in applied ultrasound imaging. Radiography, however, did not present sufficient contrast, demanding further examination. These solutions have the potential to significantly reduce the possibility of intraoperative cotton retention both on and below the surface of the brain, while still providing surgeons with traditional cotton material properties without affecting the surgical workflow.",

keywords = "Brain surgery, Contrast, Cotton balls, Detectability, Gossypiboma, Medical imaging, Optics, Retained foreign object, Textiloma, Ultrasound, X-ray",

author = "Raphael Bechtold and Niki Tselepidakis and Benjamin Garlow and Sean Glaister and William Zhu and Renee Liu and Alexandra Szewc and Arushi Tandon and Zachary Buono and James Pitingolo and Cristina Madalo and Isabella Ferrara and Collin Shale and Thomas Benassi and Micah Belzberg and Noah Gorelick and Brian Hwang and Molina, {Camilo A.} and George Coles and Betty Tyler and Ian Suk and Judy Huang and Henry Brem and Amir Manbachi",

note = "Funding Information: Tom Benassi and Dr. Jennifer Elisseeff (Johns Hopkins University, Biomedical Engineering), Dr. Camilo Molina (Johns Hopkins University, Neurosurgery), Dr. Anping Xie (Armstrong Institute for Patient Safety), Jason Ortman (Johns Hopkins Hospital, Imaging), and Jeannie Lee (Johns Hopkins Hospital, Nursing) Publisher Copyright: {\textcopyright} 2020 SPIE; Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging ; Conference date: 18-02-2020 Through 20-02-2020",

year = "2020",

doi = "10.1117/12.2548847",

language = "English (US)",

series = "Progress in Biomedical Optics and Imaging - Proceedings of SPIE",

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editor = "Andrzej Krol and Gimi, {Barjor S.}",

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AU - Bechtold, Raphael

AU - Tselepidakis, Niki

AU - Garlow, Benjamin

AU - Glaister, Sean

AU - Zhu, William

AU - Liu, Renee

AU - Szewc, Alexandra

AU - Tandon, Arushi

AU - Buono, Zachary

AU - Pitingolo, James

AU - Madalo, Cristina

AU - Ferrara, Isabella

AU - Shale, Collin

AU - Benassi, Thomas

AU - Belzberg, Micah

AU - Gorelick, Noah

AU - Hwang, Brian

AU - Molina, Camilo A.

AU - Coles, George

AU - Tyler, Betty

AU - Suk, Ian

AU - Huang, Judy

AU - Brem, Henry

AU - Manbachi, Amir

N1 - Funding Information: Tom Benassi and Dr. Jennifer Elisseeff (Johns Hopkins University, Biomedical Engineering), Dr. Camilo Molina (Johns Hopkins University, Neurosurgery), Dr. Anping Xie (Armstrong Institute for Patient Safety), Jason Ortman (Johns Hopkins Hospital, Imaging), and Jeannie Lee (Johns Hopkins Hospital, Nursing) Publisher Copyright: © 2020 SPIE

PY - 2020

Y1 - 2020

N2 - Cotton balls are used in neurosurgical procedures to assist with hemostasis and improve vision within the operative field. Although the surgeon can reshape pieces of cotton for multiple intraoperative uses, this customizability and scale also places them at perpetual risk of being lost, as blood-soaked cotton balls are visually similar to raw brain tissue. Retained surgical cotton can induce potentially life-threatening immunologic responses, impair postoperative imaging, lead to a textiloma or misdiagnosis, and/or require reoperation. This study investigated three imaging modalities (optical, acoustic, and radiographic) to find the most effective method of identifying foreign bodies during neurosurgery. First, we examined the use of dyes to increase contrast between cotton and surrounding parenchyma (optical approach). Second, we explored the ability to distinguish surgical cotton on or below the tissue surface from brain parenchyma using ultrasound imaging (acoustic approach). Lastly, we analyzed the ability of radiography to differentiate between brain parenchyma and cotton. Our preliminary testing demonstrated that dark-colored cotton is significantly more identifiable than white cotton on the surface level. Additional testing revealed that cotton has noticeable different acoustic characteristics (eg, speed of sound, absorption) from neural tissue, allowing for enhanced contrast in applied ultrasound imaging. Radiography, however, did not present sufficient contrast, demanding further examination. These solutions have the potential to significantly reduce the possibility of intraoperative cotton retention both on and below the surface of the brain, while still providing surgeons with traditional cotton material properties without affecting the surgical workflow.

AB - Cotton balls are used in neurosurgical procedures to assist with hemostasis and improve vision within the operative field. Although the surgeon can reshape pieces of cotton for multiple intraoperative uses, this customizability and scale also places them at perpetual risk of being lost, as blood-soaked cotton balls are visually similar to raw brain tissue. Retained surgical cotton can induce potentially life-threatening immunologic responses, impair postoperative imaging, lead to a textiloma or misdiagnosis, and/or require reoperation. This study investigated three imaging modalities (optical, acoustic, and radiographic) to find the most effective method of identifying foreign bodies during neurosurgery. First, we examined the use of dyes to increase contrast between cotton and surrounding parenchyma (optical approach). Second, we explored the ability to distinguish surgical cotton on or below the tissue surface from brain parenchyma using ultrasound imaging (acoustic approach). Lastly, we analyzed the ability of radiography to differentiate between brain parenchyma and cotton. Our preliminary testing demonstrated that dark-colored cotton is significantly more identifiable than white cotton on the surface level. Additional testing revealed that cotton has noticeable different acoustic characteristics (eg, speed of sound, absorption) from neural tissue, allowing for enhanced contrast in applied ultrasound imaging. Radiography, however, did not present sufficient contrast, demanding further examination. These solutions have the potential to significantly reduce the possibility of intraoperative cotton retention both on and below the surface of the brain, while still providing surgeons with traditional cotton material properties without affecting the surgical workflow.

KW - Brain surgery

KW - Contrast

KW - Cotton balls

KW - Detectability

KW - Gossypiboma

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KW - Optics

KW - Retained foreign object

KW - Textiloma

KW - Ultrasound

KW - X-ray

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BT - Medical Imaging 2020

A2 - Krol, Andrzej

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PB - SPIE

Y2 - 18 February 2020 through 20 February 2020

ER -

Minimizing cotton retention in neurosurgical procedures: Which imaging modality can help?

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Access to Document

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