Radial Endobronchial Ultrasound and Electromagnetic Navigation Bronchoscopy with Fluoroscopy for the Diagnosis of Peripheral Lung Lesions

Summary

Diagnosing small lung tumors is quite difficult using a bronchoscope alone. Electromagnetic navigation bronchoscopy is used to locate the lesion, similar to the Global Positioning System. Radial endobronchial ultrasound and fluoroscopy confirm the correct location and monitor the sampling.

Abstract

Diagnosing lung cancer using a flexible bronchoscope is a safe procedure with a very low risk of complications. Bronchoscopy has high diagnostic accuracy for endobronchial lesions, but it falls short when sampling peripheral lesions. Therefore, several modalities have been invented to guide the bronchoscope to the lesion and confirm the location of the tumor before tissue sampling.

Fluoroscopy is used during bronchoscopy to provide a 2D X-ray image of the thorax during the procedure. The bronchoscope and tools will be visible, as well as lesions if larger than 2.0-2.5 cm. Radial endobronchial ultrasound (rEBUS) consists of an ultrasound probe, small enough to be inserted into the working channel of the bronchoscope. The ultrasound probe is used to differentiate between consolidated tissue, such as tumor tissue, and normal air-filled lung parenchyma. Electromagnetic navigation bronchoscopy (ENB) creates a 3D model of the bronchial tree from computed tomography (CT) scans of the patient. Prior to the bronchoscopy, a route from the trachea to the lesion is planned, to create real-time guidance of the bronchoscope to the lesion during the procedure, similar to the Global Positioning System. The aim of this article is to describe a stepwise approach to performing bronchoscopy with rEBUS and fluoroscopy, bronchoscopy with ENB, rEBUS, and fluoroscopy. In the discussion section, the pros and cons of each modality will be discussed.

Introduction

Lung cancer is one of the most common cancer types worldwide and the leading cause of cancer-related deaths¹. Screening for lung cancer with low-dose computed tomography (CT) has therefore been suggested to diagnose patients before symptoms occur². Low stages are often detected as small lung lesions or nodules. From one of the largest screening studies conducted in the Netherlands, we know that these lesions are often located in the outer 2/3 of the lung parenchyma and are thereby defined as peripheral lung cancers^3,4. To determine whether a lesion is malignant, a tissue sample is required. This can be obtained in several different ways such as surgical excision biopsy, trans-thoracic needle biopsy, or endoscopic with a bronchoscope^5,6, the latter having a lower risk of complications compared to surgery and the trans-thoracic approach and a preferable method for diagnosing an increasing elderly population with considerable comorbidities. The diagnostic yield, however, is still lower than the other modalities⁵.

The bronchoscope allows for visual inspection of the trachea and the main bronchi, but when the bronchi branch into segments and subsegments, locating one small lesion is comparable to finding a needle in a haystack. Therefore, several additional modalities have been developed to guide the bronchoscope to the lesion and confirm the location of a tumor before tissue sampling⁷. The purpose of these modalities is to increase the diagnostic yield of endoscopic tissue sampling and expand the reach of the bronchoscope towards the pleura, where trans-thoracic needle biopsies are otherwise performed^8,9.

Fluoroscopy using a C-arm provides a 2D X-ray image of the thorax during bronchoscopy. It can be used to visualize the position of the bronchoscope and the forceps for trans-bronchial biopsies (TBB) to avoid sampling the pleura and the vascular structures of the intermediate 1/3 of the lung parenchyma when performing random TBBs. When diagnosing lung cancer, fluoroscopy can be used to guide the scope to an "approximate" location of the lesion. Lesions are usually visible on fluoroscopy when the diameter is around 2-2.5 cm or above¹⁰. The drawback of fluoroscopy is the 2D image properties, which makes it impossible to know whether the scope is in front, behind, or the center of the lesion¹¹. However, fluoroscopy is also used to confirm that the biopsy tools are in the desired location during sampling if the presence of a tumor has been confirmed with radial endobronchial ultrasound (rEBUS)¹².

rEBUS was first described in 1992 by Hürter et al. and is increasingly used in diagnostic workup of peripheral lung lesions¹³. This modality utilizes the fact that the air-filled lung tissue does not conduct ultrasound waves, whereas denser tissue will appear as a consolidation when scanned using an ultrasound probe. rEBUS is comprised of a circular and rotating ultrasound probe, an ultrasound driving unit, and a guide sheath used to protect the probe while ensuring the correct position of the biopsy tools¹⁴. rEBUS can be used on its own or together with other modalities such as electromagnetic navigation bronchoscopy (ENB)^15,16,17.

ENB is used to locate a peripheral lung lesion¹⁸. The system uses a software program and a CT scan from the patient. A virtual model of the patient´s airways is generated from the CT scan and the operator designs a route from the trachea to the lesion. An electromagnetic field is then created around the patient´s chest and the software synchronizes this field with the virtual field generated from the CT scan, thus assisting the operator to follow the preplanned route during the bronchoscopy, similar to Global Positioning System technology. ENB does not provide real-time confirmation of tumor location. ENB can be combined with fluoroscopy and rEBUS^19,20. Virtual Navigation Bronchoscopy (VBN) is the predecessor to ENB and consists of software for creating the virtual model of the bronchial tree along with a route to the lesion. The system does not include real-time navigation, but the route can be displayed during the bronchoscopy^21,22. New systems incorporate VBN with fluoroscopy but the use of VBN will not be described in the following protocol²³.

ENB systems
Currently, two companies produce systems for ENB, the SPiN system from Olympus and the superDimension system and the ILLUMISITE both sold by Medtronic. The protocol will describe a procedure using the superDimension system, which currently has the most publications. However many steps of the procedure are interchangeable.

The following protocol will describe how to perform rEBUS under fluoroscopy and ENB + rEBUS under fluoroscopy in a clinical setting. The procedures can easily be performed under conscious sedation and general anesthesia. The protocol will not describe any methods for sedation. In the discussion section, the pros and cons of each procedure will be presented.

Protocol

The protocol in this article describes standard clinical practice. No permission from the ethical committee was needed. Images in the protocol contain no information which can be used to indentify patients.

1. Radial endobronchial ultrasound

1. Preparing for the procedure
   1. Examine the CT scan to check for bronchus signs and the location of the lesion before the procedure.
   2. Calibrate the ultrasound probe, guide sheath, and biopsy tools of choice prior to the examination, ensuring that the tool will reach the same position as the ultrasound probe when inserted into the guide sheath.
2. Perform a systematic examination of the bronchial tree and segments as described in "Systematic bronchoscopy: The 4 landmark approach"²⁴.
   1. Place the C-arm over the patient and adjust until the lesion is visible in the image.
   2. Insert the tip of the bronchoscope in the segment or subsegment where the lesion is most likely present.
   3. Advance the guide sheath and probe under fluoroscopy guidance until the metallic guide sheet tip is adjacent to or in the lesion.
   4. Advance and activate the probe. Now an ultrasound image will appear on the monitor.
      1. If the probe is surrounded by a tumor or dense tissue, a concentric consolidation will appear (see Figure 1A). Look for grey and homogeneous consolidation with a hyperechoic border toward the normal lung tissue.
      2. If the probe is placed adjacent to the lesion, the image will be eccentric (see Figure 1B).
      3. If the probe is placed in normal lung tissue, only a scattered image of air will appear (see Figure 1C).
      4. With lesser dense lesions such as ground glass lesions, inflammatory tissue, or atelectasis, a more heterogeneous and less defined image will be presented (see Figure 1D). This is caused by air (hyperechoic) or fluid (hypoechoic) trapped in the bronchi.
      5. If a consolidation matching the lesion on the CT scan does not appear, adjust the guide sheath and probe until the correct placement is achieved.
   5. Save the fluoroscopy image of the position where the ultrasound probe provides the best consolidation (will be used in step 1.3.2).

Figure 1: Radial EBUS ultrasound images. (A) Concentric consolidation, (B) Eccentric consolidation, (C) Air-scattered ultrasound image, (D) Irregular consolidation. Abbreviation: EBUS = endobronchial ultrasound. Please click here to view a larger version of this figure.

3. Tissue sampling
   1. Remove the ultrasound probe from the guide sheath and insert forceps or other sampling tool of choice.
   2. Compare the placement of the forceps to the placement of the ultrasound probe on the C-arm screen, ensuring the sampling is performed in the correct location (see Figure 2). Verify the placement of the forceps, especially if the patient is coughing. Collect a minimum of 10-15 samples using forceps and confirm the correct location by removing the forceps and inserting the ultrasound probe every four to five samples.

Figure 2: Fluoroscopy-guided sampling. (A) Placement of the forceps during sampling; (B) Placement of the rEBUS probe. Abbreviation: rEBUS = radial endobronchial ultrasound. Please click here to view a larger version of this figure.

2. Electromagnetic navigation bronchoscopy

NOTE: The following procedure is based on the superDimension system by Medtronic.

1. The planning phase
   1. Before the procedure, evaluate the CT images. Ensure that the image is of high quality, preferably with slices no thicker than 1.5 mm, and recorded during inspiration to fully expand the airways revealing bronchi leading to the lesion²⁵.
   2. Use the software to create a 3D model of the bronchial tree, where the route to the lesion is planned, starting at the lesion and moving toward the trachea.
      NOTE: If a pathway to the lesion cannot be established based on the scans, ENB is not the correct modality for the patient.
2. Registration
   1. Place the patient on a board. Place the three sensors on the thorax to compensate for movements during respiration.
   2. Begin the procedure with a systematic bronchoscopy²⁴.
   3. Insert the extended working channel (EWC) and locatable guide into the working channel of the bronchoscope until the tip of the locatable guide is visible.
   4. Lock the locatable guide.
   5. Press Start registration on the machine or use the foot pedal.
   6. Insert the bronchoscope stepwise in each lobar bronchus, starting contralaterally and ending in the lobe with the lesion. The position and movements are registered by the system, and the information is used to match the registration of the patient´s airways to the 3D model of the bronchial tree created based on the CT scan. Start the registration on the opposite side from the lesion and finish closest to the target.
   7. When the system shows that all lobes are registered, press Review registration to see if the registration points match the virtual 3D model. If there is a mismatch, repeat steps 2.2.5-2.2.7 (see Figure 3D).
3. Navigation
   1. Press the foot pedal to begin the navigation. The software will demonstrate a route to the target. Use the central navigation in the larger airways, displaying the video image from the camera along an image of the route in the 3D model of the airways (see Figure 3A).
   2. Follow the preplanned route until the scope cannot be advanced further.
   3. Unlock the EWC and locatable guide.
   4. Switch from central navigation to peripheral navigation by pressing the foot pedal.
      NOTE: Peripheral navigation is used when advancing the EWC. During this part, the 3D model of the airways is visible alongside the CT images from the scan. The target is marked with a green ball and a reticle, which provides direction and distance from the target (see Figure 3B).
   5. Keep the target on the right side while ensuring that the route is illuminated ("right and bright"). Advance the EWC, ensuring the route to the bronchi appears open on the CT images.
      NOTE: The EWC is maneuverable and can be turned in the desired direction (X, Y, and Z axes) to reach the target.
   6. Once the target is in the center of the reticle, with a distance of 0.4-0.9 mm from the target, the navigation is complete.
      NOTE: It is recommended that the locatable guide is not 0.0 mm from the distance, since this can cause the biopsy tool to extend beyond the target.
   7. Lock the EWC in position and retract the locatable guide from the scope.

Figure 3: Electromagnetic navigation bronchoscopic navigation. (A) Central navigation, (B) Peripheral navigation, (C) Review registration with good alignment, (D) CT to body divergence. Abbreviation: CT = computed tomography. Please click here to view a larger version of this figure.

3. Fluoroscopy, rEBUS, and tissue sampling

NOTE: Once the locatable guide is retracted, fluoroscopy can be used without disturbing the electromagnetic field.

1. Place the C-arm over the patient and adjust until the lesion is visible in the image.
2. Confirm the correct position of the EWC using fluoroscopy and by inserting the rEBUS probe as described in step 1.2.5. If the EWC is not in the lesion under fluoroscopy or a consolidation does not appear using rEBUS, the position must be adjusted as described in steps 1.2.4-1.2.6.
   NOTE: CT-to-body divergence occurs when the alignment between the constructed 3D model and the real-time registration points is skewed; the marked target will not be at the location of the lesion.
3. When the correct location is reached and confirmed, perform tissue sampling as described in steps 1.3.1-1.3.2.

Results

The described technique facilitates the sampling of peripheral lung lesions. Radial EBUS and fluoroscopy will aid the bronchoscopist in confirming the presence of a lesion before sampling the tumor (see Figure 1 and Figure 2). By adding ENB, the bronchoscopist is guided to the correct spot instead of searching for the lesion. The planning phase provides the bronchoscopist with a route to the lesion, real-time guidance to the lesion with the navigation system, co...

Discussion

This article presents a practical approach for performing rEBUS and ENB with fluoroscopy. The following discussion is the opinion of the authors and is based on practical clinical experience from two centers.

Tips and tricks
rEBUS
Before the procedures the Chest CT sectional walker app can be used to check in which segment the lesion is located¹⁴. However, since the anatomy of patients differs, the lesion may be located in a...

Materials

Name	Company	Catalog Number	Comments
Bronchoschope	Olympus
Edge Extended working channel	Medtronic
Edge locatable guide	Medtronic
Guide sheath kit	Olympus
OEC fluorostar	GE healthcare		C-arm for fluoroscopy
Probe Driving Unit	Olympus
Radial EBUS probes	Olympus
superDimension	Medtronic		Navigation system