Intraoperative image guidance in transoral robotic surgery ... · Intraoperative image guidance in...
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OR I G I N A L A R T I C L E
Intraoperative image guidance in transoral robotic surgery:A pilot study
Andrew K. Ma, MD1 | Michael Daly, PhD2 | Jimmy Qiu, MASc2 |
Harley H. L. Chan, PhD2 | David P. Goldstein, MD, MSc, FRCSC1 |
Jonathan C. Irish, MD, MSc, FRCSC1,2 | John R. de Almeida, MD, MSc, FRCSC1
1Department of Otolaryngology – Head and
Neck Surgery/Surgical Oncology, University
of Toronto, Toronto, Ontario, Canada
2Guided Therapeutics (GTx) Program,
Techna Institute, University Health Network,
Toronto, Ontario, Canada
Correspondence
John R. de Almeida, Princess Margaret
Cancer Centre, 610 University Avenue,
3-955, Toronto, Ontario, Canada M5G
2M9.
Email: [email protected]
Funding information
This project was made possible through
funding provided by the Harry Barberian
Scholarship, Department of Otolaryngology,
University of Toronto, Toronto, Ontario,
Canada.
Abstract
Background: Intraoperative image guidance during transoral robotic surgery (TORS) is hampered
by imaging-friendly instrumentation and intraoperative positioning. The purpose of this study was
to develop and validate an accurate image-guidance system for TORS.
Methods: A custom radiolucent mouth retractor was fabricated from biocompatible material
(Med-610; Stratasys, Minneapolis, MN). Teflon beads were placed in the oropharynx and carotid
arteries of 3 cadavers. CT scans were obtained in the preoperative and intraoperative positions.
Displacement of targets between preoperative and intraoperative scans was measured. Surgical
navigation was based on the open-source Image-Guided Surgery Toolkit. Target registration error
(TRE) was determined by measuring the distance between the tracker and bead registered to pre-
operative versus intraoperative scans.
Results: The inferior oropharyngeal targets demonstrated the greatest displacement between
positions. A significant reduction in TRE was observed when registering the tracker to the intrao-
perative compared to the preoperative scan.
Conclusion: This study describes an accurate intraoperative image-guidance system for TORS.
K E YWORD S
cadaver study, head and neck cancer, image guidance, intraoperative CT, transoral robotic surgery
(TORS)
1 | INTRODUCTION
Transoral robotic surgery (TORS) has several applications in the surgical
management of oropharyngeal cancers and in selected laryngeal, hypo-
pharyngeal, parapharyngeal, and nasopharyngeal lesions.1 TORS obvi-
ates the need for transmandibular approaches to provide access for
tumor resection. Several studies have demonstrated the efficacy of
TORS in treatment of early-stage oropharyngeal cancers (T1-T2), with
locoregional control rates similar to that of traditional chemoradiation
while avoiding its late toxicities.2–4 In addition to functional and onco-
logic benefits of this approach, TORS provides a high resolution magni-
fied endoscopic view, the use of angled endoscopes to navigate
around corners, the ability to maintain maximal degrees of freedom
within a narrow space, and the elimination of surgeon hand tremor.3,5
However, the transoral robotic approach is limited in several ways.
First, proximity of tumors to critical vascular structures, such as the
internal carotid artery in the parapharyngeal space, may compromise
adequate oncologic resection. Furthermore, the lymphoid appearance
of the tongue base can obscure proper identification of deep, submu-
cosal tumors that may ordinarily be identified by manual palpation.
TORS lacks the haptic feedback that a surgeon relies on in standard
approaches for proper surgical resection. These limitations may result
in inadequate resections or possibly even catastrophic bleeding.
Image guidance, typically used for endoscopic sinus surgery or
skull base surgery, can provide improved surgeon comfort with vascular
anatomy and real-time imaging corroboration of endoscopic visualiza-
tion with direct anatomic localization on triplanar imaging views with
the use of a tracking device. Applying these systems is relatively
1976 | VC 2017Wiley Periodicals, Inc. wileyonlinelibrary.com/journal/hed Head Neck. 2017;39:1976–1983.
Received: 9 August 2016 | Revised: 25 January 2017 | Accepted: 28 February 2017
DOI: 10.1002/hed.24805
straightforward and predictable when registering to static bony land-
marks. However, the jaw, lips, and tongue must be retracted in a trans-
oral approach in order to access the tumor. Deformation of soft tissue
anatomy with intraoperative jaw positioning compromises accuracy of
registration to the preoperative imaging study. Because of these posi-
tional changes, an image-guidance system and tracking device cannot
be registered to preoperative scans that are obtained with the mouth
closed. This study validates the proof of principle in the developed
instrumentation, in addition to the accuracy of the image-guidance
system for use with TORS.
2 | MATERIALS AND METHODS
2.1 | ETHICS APPROVAL
Research ethics board approval was obtained for cadaveric studies.
2.2 | Cadaveric specimens and internal targets
Three cadaveric head specimens were obtained through the University
of Toronto Surgical Skills Centre (Mount Sinai Hospital, Toronto, Can-
ada). These specimens were preserved in a fresh-frozen preparation to
most accurately represent natural soft tissue movement in a live
patient; as formalin preserved specimens demonstrate significant soft
tissue rigidity.
Specimens were selected based on the following criteria: (1)
adequate mouth opening to accommodate the radiolucent mouth
retractor; (2) no evidence of oral cavity or oropharyngeal masses; and
(3) no evidence of oral cavity or oropharyngeal instrumentation or sur-
gery. In some specimens, dental extraction was performed on the ante-
rior maxillary and mandibular dentition to obtain more interincisal
distance to accommodate the radiolucent mouth retractor. Figures 1
and 2 demonstrate positioning of the cadaveric specimen.
Four-millimeter diameter Teflon beads were selected as targets for
the study (see Figure 3). This material demonstrates bright enhance-
ment distinct from soft tissue on noncontrast CT and presents minimal
streak artifact. The Teflon beads were drilled and mounted onto
0.01600 diameter stainless steel posts. The stainless steel posts were
tested through the CT scanner and also demonstrated minimal streak
artifacts. The targets were then tacked onto a variety of oropharyngeal
subsites and demonstrated stable seating on repeated mouth opening
and closing.
Oropharyngeal subsites were as follows: (a) uvula (31); (b) superior
tonsillar fossa (32); (c) inferior tonsillar fossa (32); (d) posterolateral
oropharyngeal wall (32); (e) base of tongue (32); and (f) epiglottis (31).
Three targets were also placed into each internal carotid artery. A
vertical incision was made on each side of the neck over the trajectory
of the common carotid artery. This was dissected until the common
carotid artery, carotid body, and internal and external branches were
exposed. The internal carotid artery was identified. Three Teflon beads
were placed into each carotid system, from the level of the hyoid infe-
riorly and up to the internal carotid artery in the parapharyngeal space
deep to the mandible.
2.3 | Image-guided surgery system
The image-guidance system includes a mobile C-arm for intraoperative
cone-beam CT, real-time optical tracking, and custom 3D visualization
software (see Figure 4). The flat-panel cone-beam CT prototype system
was developed in collaboration with Siemens Healthcare (Erlangen,
Germany) to enable 3D volumetric imaging in a single half-rotation
(approximately 1808) without translation of the patient. A recent pro-
spective clinical study in head and neck surgery demonstrates that
intraoperative cone-beam CT provides high-quality 3D imaging during
bone ablation and reconstruction tasks with acceptable workflow inter-
ruptions.6 For the current study, intraoperative acquisition consisted of
200 X-ray projections at 100 kVp obtained in approximately 60 sec-
onds, resulting in volumetric images encompassing approximately 20 3
20 3 15 cm3 with isotropic voxels (0.8 mm3). Radiation doses for
cone-beam CT-guided head and neck surgery have been reported pre-
viously at levels sufficiently low (ie, approximately one-fifth of a typical
2-5 mSv diagnostic head CT) to permit repeat intraoperative imaging.7
Navigation of surgical instruments (eg, pointers, endoscopes, and drills)
is performed using an infrared stereoscopic camera (Polaris Spectra;
NDI, Waterloo, Canada) and corresponding retroreflective spheres. The
in-house navigation software (“GTx-Eyes”), based on the open-source
image-guided surgery toolkit8,9 provides a variety of 3D visualization
capabilities, including standard triplanar views (axial/sagittal/coronal),
semitransparent surface renderings, 3D point localization, and image
fusion.
FIGURE 1 Cadaveric specimen in the preoperative (mouth closed)position [Color figure can be viewed at wileyonlinelibrary.com]
MA ET AL. | 1977
2.4 | Radiolucent mouth retractor
A radiolucent mouth retractor was fabricated through the Princess
Margaret Hospital Machine Shop (Toronto, Canada). The design was
based on the existing Feyh-Kastenbauer retractor. The retractor was
built using a proprietary radiolucent material, Med-610 (Stratasys, Eden
Prairie, MN), which is biocompatible and autoclavable.
2.5 | Imaging procedure
Surface fiducials were used to register specimens to CT scans of the
cadaveric head specimens obtained in either the mouth closed (preop-
erative) or mouth open (intraoperative) positions. Surface fiducials
were placed in the preauricular, zygomatic, infraorbital, and nasion
positions (see Figure 1). Alignment errors of <1 mm were achieved.
Cone-beam CT scans (noncontrast) of the cadaveric head speci-
mens with oropharyngeal targets were obtained in 2 positions: (1)
mouth closed (see Figure 1); and (2) mouth open with radiolucent
retractor in place (see Figure 2). The first position represents preopera-
tive CT scanning, whereas the second position represents intraopera-
tive positioning for TORS with the mouth opened and the retractor in
position. Surface fiducials were placed in the preauricular, zygoma,
infraorbital, and nasion positions, and used for image registration, as
described below. The experimental setup is shown in Figure 4.
2.6 | Anatomic tissue displacement
The amount of anatomic tissue displacement was determined by
comparing the mouth closed versus the mouth open position CT
scans, after obtaining correct alignment through paired-point
registration of surface fiducials. The centroid of the oropharyngeal
and internal carotid artery targets were marked in the axial, coronal,
and sagittal CT cuts using GTx-Eyes software. The center position
was confirmed visually with magnified cross-sectional imaging.
In this fashion, the targets were marked in order for both the
preoperative and intraoperative positions. Using MATLAB (R2014;
MathWorks, Natick, MA), the 3D displacement of each target was
calculated. Selection, labeling, and verification of all targets were
done by one author (A.M.).
2.7 | Tracking system accuracy
The target registration error (TRE) at each of the oropharyngeal targets
was determined by using a bayonet tracking instrument registered to
the preoperative and intraoperative CT scans via surface fiducials. The
instrument was then used to physically contact a Teflon target in
the intraoperative position under direct visualization while recording
the position of the instrument. Each target was contacted 5 times by
the tracking instrument and recorded. The 3D distance between the
recorded position of the tracked instrument at each specific target
and the corresponding position of the target according to CT was
determined. In this fashion, the 3D distance between the tracker and
targets was used to determine TRE when registered separately to the
preoperative and intraoperative positions.
FIGURE 2 Cadaveric specimen in the intraoperative (mouthretracted) position [Color figure can be viewed atwileyonlinelibrary.com]
FIGURE 3 Teflon beads inset as oropharyngeal targets [Colorfigure can be viewed at wileyonlinelibrary.com]
1978 | MA ET AL.
FIGURE 4 Experimental set up with C-arm cone-beam CT scanner and cadaveric specimen with radiolucent mouth retractor in position[Color figure can be viewed at wileyonlinelibrary.com]
FIGURE 5 Comparison of a metal Feyh-Kastenbauer retractor versus a modified radiolucent retractor. A, Positioning of the metal Feyh-Kastenbauer retractor in the phantom skull model. B, CT scan of the metal Feyh-Kastenbauer retractor demonstrating considerable streakartifact. C, Positioning of the radiolucent retractor in the cadaveric model. D, CT scan of the radiolucent retractor demonstrates no artifacts[Color figure can be viewed at wileyonlinelibrary.com]
MA ET AL. | 1979
3 | RESULTS
3.1 | Radiolucent mouth retractor
Figure 5 demonstrates the radiolucent properties of the modified radio-
lucent mouth retractor and standard Feyh-Kastenbauer retractor. There
is an appreciable qualitative difference in the visible scatter artifacts.
3.2 | Anatomic tissue displacement
Chart 1 demonstrates the 3D displacement of each oropharyngeal
target as determined between CT scans of the cadaveric heads in the
preoperative versus intraoperative positions. The greatest amount of
displacement was observed in the inferior oropharyngeal targets — the
inferior tonsillar fossa, tongue base, and epiglottis. The highest degree
of displacement was observed in the tongue base (mean 13.77 mm;
range 11.00-16.66 mm), followed by the epiglottis (mean 13.69 mm;
range 10.02-15.75 mm), and the inferior tonsillar fossa (mean 5.53 mm;
range 2.26-9.81 mm). Carotid displacement is also shown in Chart 1
(mean 2.47 mm; range 1.06-5.34 mm).
Figure 6 demonstrates a 3D reconstruction of the oropharynx in the
intraoperative position. The red spheres represent the position of targets
in the preoperative position registered to the intraoperative scan, whereas
the green spheres represent the position of targets in the intraoperative
position. The greatest amount of translation is seen in the inferior oropha-
ryngeal targets— the epiglottis, tongue base, and inferior tonsillar pillar.
3.3 | Tracking system accuracy
Chart 2 demonstrates the TRE of each oropharyngeal target with the
tracking system registered to the preoperative versus the intraoperative
position. A statistically significant reduction in TRE was observed when
registering the tracked pointer to the intraoperative (mouth open) scan
compared with the registration to preoperative imaging. The average
TRE, when registered to the preoperative scan, was 7.63 mm (95% CI
6.79-8.47 mm), whereas registration to the intraoperative scan was
2.49 mm (95% CI 1.95-3.03 mm; P < .05). The greatest TRE was seen
similarly in the inferior oropharyngeal targets (R inferior tonsillar fossa
3.03 vs 6.8 mm; L inferior tonsillar fossa 3.42 vs 6.03 mm; R tongue
base 2.78 vs 14.91 mm; and L tongue base 2.35 vs 13.37; P< .05).
Figure 7 demonstrates a 3D reconstruction of the oropharynx show-
ing tracker accuracy when registered to the intraoperative CT scan.
4 | DISCUSSION
In the present study, we observed that operative positioning for TORS
cases is associated with considerable retraction of the tongue, leading
to significant soft tissue deformation that renders registration to the
preoperative imaging unreliable. In particular, the change in soft
tissue is most pronounced in the inferior aspect of the oropharynx.
Tongue base resections can be especially challenging for a variety
of reasons. The normal lymphoid appearance of the tongue base
mucosa can obscure visualization of tumor extension, whereas a
lack of tactile feedback makes palpating submucosal infiltrating lesions
impossible, and the proximity of the lingual arteries present a real
risk of massive hemorrhage. This is further complicated by the defor-
mation that results from intraoperative positioning, as illustrated in this
study.
TORS has recently been reportedly used for resection of paraphar-
yngeal space masses.10 Many neurovascular structures traverse this
CHART 1 Three-dimensional displacement of each oropharyngeal target between preoperative and intraoperative positioning, in mm. Errorbars represent SD [Color figure can be viewed at wileyonlinelibrary.com]
1980 | MA ET AL.
potential space and can pose considerable risk of hemorrhage. Major
vessel hemorrhage encountered in the robotic setting could be cata-
strophic and difficult to control, given limitations in exposure and
inability to deploy multiple instruments/assistants rapidly. In a case
series by Boyce et al,10 17 patients had parapharyngeal tumors extir-
pated via TORS. The authors report 1 patient with a hematoma requir-
ing reexploration in the operating room for hemostasis. No airway
complications or major hemorrhage were reported. In a cadaveric study
by Wang et al,11 8% of cadaveric specimens demonstrated an abnormal
bulging of the external carotid artery medially toward the superior
pharyngeal constrictor. Although thorough knowledge of the paraphar-
yngeal space is mandatory to perform TORS, advance knowledge of
vascular anatomic variants via intraoperative image guidance can help
surgeons avoid any catastrophic encounters.
One challenge with image-guidance systems is the deformation
that occurs with soft tissue. Although one may achieve good accuracy
when registering to the intraoperative cone-beam CT, these images
remain static with live image guidance in contrast to soft tissue that
gets retracted and manipulated during surgery. In this way, no image-
guidance system is presently able to replicate soft tissue distortion in
CHART 2 Target registration error of each oropharyngeal target with the tracking system registered to the preoperative (mouth closed)versus intraoperative (mouth open) position, in mm. Error bars represent 95% confidence interval [Color figure can be viewed atwileyonlinelibrary.com]
FIGURE 6 Three-dimensional reconstruction of the oropharynx in the intraoperative position. The red spheres represent position oftargets in the preoperative position registered to the intraoperative scan, whereas the green spheres represent position of targets in theintraoperative position [Color figure can be viewed at wileyonlinelibrary.com]
MA ET AL. | 1981
real time via traditional imaging platforms, such as CT or MRI scans. In
contrast, image-guidance systems applied in endoscopic sinus or skull
base surgery are predictable as bony anatomy does not appreciably
deform intraoperatively. Liu et al12,13 and Reaungamornrat et al14 have
published on their image-guidance system using a deformable registra-
tion to link the preoperative and intraoperative images. An intraopera-
tive endoscopic overlay using video augmentation that had been
deformably registered to the preoperative imaging allowed the robotic
surgeon to implant beads into a defined target with increasing accuracy
and reduction in TRE of 5.4 mm.13 Review of the literature reveals a
current paucity of studies in image-guidance in TORS.
There were some limitations to this study. First, we demonstrated
significant reduction in TRE when registered to an intraoperative scan.
However, this may be difficult in many institutions to obtain given the
relative scarcity of intraoperative imaging systems. Conceivably, CT
scans may be obtained with the mouth in an open position, but this
would still not optimally replicate operative positioning and may still be
associated with registration error. Second, the findings of this study are
based on a small series of cadaveric dissections. Last, our custom-
designed radiolucent mouth retractor successfully positions the cadav-
eric specimen to generate an intraoperative cone-beam CT scan with-
out any scatter artifact. However, the tensile strength of the
radiolucent material is far less than the original metal version of the
Feyh-Kastenbauer retractor, requiring larger structural framework of
the mouth retractor components that may be cumbersome for use and
interfere with surgical manipulation. This resulted in a reduction in the
cross-sectional area of transoral access. Nonetheless, to the best of our
knowledge, the radiolucent mouth retractor represents the first retrac-
tor of its kind designed for intraoperative use with image-guidance.
This study demonstrates the quantitative deformation of soft tis-
sue during positioning for TORS and that registration to intraoperative
cone-beam CT imaging significantly reduces TRE. Future work could
look at the application of such a system in a cadaveric tumor model to
evaluate the accuracy and logistical feasibility of image-guidance in
TORS. Similarly, use of injected cadavers could be used to evaluate the
accuracy of navigation around critical vascular structures. At the pres-
ent state, further research is required before an image-guidance system
is ready for clinical use.
As we move into an era of molecular-guided and image-guided sur-
gery, it will be increasingly important to create surgical systems that con-
tinue to use robotic tools in parallel with newly developed imaging and
visualization systems. This article has proven the principle of using radio-
lucent systems with intraoperative near-real time on-the-table imaging,
which has the ability to further enable robotic surgery applications.
CONCLUSION
Considerable tissue translation occurs when a patient undergoing
TORS is imaged in the preoperative position compared to the intrao-
perative position. This image guidance pilot study demonstrates accu-
racy of registration using intraoperative cone-beam CT imaging.
Further work is needed to apply this system in the clinical setting.
ACKNOWLEDGMENTS
The authors would like to thank the Princess Margaret Machine
Shop and Surgical Skills Center at Mount Sinai Hospital, Toronto,
Ontario, Canada. This project was made possible through funding
provided by the Harry Barberian Scholarship, Department of Otolar-
yngology, University of Toronto.
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How to cite this article: Ma AK, Daly M, Qiu J, et al. Intraopera-
tive image guidance in transoral robotic surgery: A pilot study.
Head & Neck. 2017;39:1976–1983. https://doi.org/10.1002/
hed.24805
MA ET AL. | 1983