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Pictorial essay


Computed Tomography-guided Pulmonary Nodule Microcoil Localization Technique, Misplacement Errors, and Complications: A Pictorial Essay.

Sultan R Alharbi
Department of Radiology and Medical Imaging, College of Medicine, King Saud University, P.O. Box 7805, Riyadh 11472, Kingdom of Saudi Arabia
Date of Submission: 06-Nov-2017, Date of Acceptance: 10-Jan-2018, Date of Web Publication: 09-Mar-2018.
Corresponding Author:
Corresponding Author

Sultan R Alharbi

Department of Radiology and Medical Imaging, College of Medicine, King Saud University, P.O. Box 7805, Riyadh 11472, Kingdom of Saudi Arabia.
E-mail: drsultan000@gmail.com

Corresponding Author:
Corresponding Author

Sultan R Alharbi

Department of Radiology and Medical Imaging, College of Medicine, King Saud University, P.O. Box 7805, Riyadh 11472, Kingdom of Saudi Arabia.
E-mail: drsultan000@gmail.com

DOI: 10.4103/jcis.JCIS_86_17 Facebook Twitter Google Linkedin

ABSTRACT


Computed tomography-guided pulmonary nodule microcoil localization is done preoperatively to fluoroscopic-guided video-assisted thoracoscopic surgical resection. This pictorial essay explains and illustrates the microcoil localization technique, various microcoil placement errors, intraoperative fluoroscopy-guided resection, and postmicrocoil localization complications.
Keywords: Computed tomography-guided microcoil localization, pulmonary nodule, video-assisted thoracoscopic lung resection

INTRODUCTION


Recently, video-assisted thoracoscopic surgery (VATS) has become the choice in the workup of small pulmonary nodules. VATS can be diagnostic and therapeutic, and it can prevent the potential sampling error inherent with a fine-needle aspiration.[1] However, VATS is limited because the surgeon is unable to palpate the lung tissue during operation, which may render the intraoperative identification of small pulmonary nodules difficult.[2] Thus, failure to visualize or palpate small pulmonary nodules has resulted in conversion thoracotomy rates of up to 54%.[3]

Pulmonary nodule localization techniques have been previously described and can be classified into three major types: image-guided surgery, injection of liquid materials through fine needles, and placement of percutaneous wires.[4] Microcoil localization technique to fluoroscopically guided VATS excision of small lung nodules increased the success rate of VATS excision to 97% compared with the reported 54% success rate with the nonguided approach.[5]

MICROCOIL PLACEMENT


A 10-cm-long 21G Chiba needle is loaded with a 7-cm-long, 0.018-inch-diameter fiber-coated platinum microcoil by a microcoil pusher. Using a sterile surgical marker pen, two measurements are marked on the same needle stylet [Figure 1]. Under computed tomography (CT) guidance, the loaded Chiba needle is pushed through and just deeper to the nodule. The premeasured needle stylet is advanced into the Chiba needle deploying about 3 cm of the microcoil into the lung parenchyma just deeper to the nodule [Figure 2]. A second localizer CT scan is obtained to confirm the microcoil deployment and measure the distance necessary to withdraw the tip of the Chiba needle back to the pleural space. After that, the Chiba needle is pulled back to the pleural surface while the needle stylet is held against the end of the microcoil. Then, the needle stylet is advanced completely deploying the remaining microcoil at the visceral pleural surface. After deployment, the Chiba needle is removed from the chest wall [Figure 3].

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Figure 1: Diagrammatic scheme of predeployment measurement: After loading the 7-cm microcoil into 10-cm 21G Chiba needle by microcoil pusher, two marks were put by a sterile surgical marker pen on the needle stylet. Mark A: The length enough to push the microcoil to the tip of the needle. Mark B: The length enough to eject 30 mm of the microcoil.

Figure-1.jpg

Figure 1: Diagrammatic scheme of predeployment measurement: After loading the 7-cm microcoil into 10-cm 21G Chiba needle by microcoil pusher, two marks were put by a sterile surgical marker pen on the needle stylet. Mark A: The length enough to push the microcoil to the tip of the needle. Mark B: The length enough to eject 30 mm of the microcoil.

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Figure-2.jpg

Figure 2: Diagrammatic scheme of deployment location A, a microcoil-loaded Chiba needle was pushed through and just beneath the pulmonary nodule. Location B: The deeper microcoil end tightly coiled deep to the nodule while the superficial end loosely coiled on the visceral pleural surface.

Figure-2.jpg

Figure 2: Diagrammatic scheme of deployment location A, a microcoil-loaded Chiba needle was pushed through and just beneath the pulmonary nodule. Location B: The deeper microcoil end tightly coiled deep to the nodule while the superficial end loosely coiled on the visceral pleural surface.

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Figure-3.jpg

Figure 3: (a) Preprocedural computed tomography with skin localization showing pulmonary nodule. (b) A loaded Chiba needle passed through the pulmonary nodule. (c) The microcoil pushed out and tightly coiled deep to the nodule. (d) The Chiba needle was removed and the proximal microcoil end coiled on the visceral pleural surface.

Figure-3.jpg

Figure 3: (a) Preprocedural computed tomography with skin localization showing pulmonary nodule. (b) A loaded Chiba needle passed through the pulmonary nodule. (c) The microcoil pushed out and tightly coiled deep to the nodule. (d) The Chiba needle was removed and the proximal microcoil end coiled on the visceral pleural surface.

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INTRAOPERATIVE FLUOROSCOPIC GUIDANCE


Under general anesthesia, a double-lumen endotracheal tube is inserted and the involved lung is deflated. Three thoracoscopic ports are made. Wedge resection of the lung nodule and microcoil is done using grasping instrument and stapling device. Fluoroscopy is used to aid and confirm microcoil and complete resection of the nodule. The resected specimen is sent for frozen section [Figures 4 and 5].[6,7] A 24G chest tube is insertwed at the end of the procedure [Figure 6].[8]

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Figure 4: Fluoroscopic image during the video-assisted thoracoscopic lung resection, showing the microcoil within the lung parenchyma. A thoracoscopic port, grasping instrument, and linear stapling devices are noted.

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Figure 4: Fluoroscopic image during the video-assisted thoracoscopic lung resection, showing the microcoil within the lung parenchyma. A thoracoscopic port, grasping instrument, and linear stapling devices are noted.

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Figure-5.jpg

Figure 5: Surgically resected wedge of the lung containing the microcoil.

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Figure 5: Surgically resected wedge of the lung containing the microcoil.

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Figure 6: Postoperative chest image showing left-sided chest tube.

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Figure 6: Postoperative chest image showing left-sided chest tube.

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MICROCOIL MISPLACEMENT


Ideal microcoil placement requires proper predeployment measurements and frequent CT scanning for needle placement and withdrawal guidance. There are two crucial steps to avoid microcoil misplacement: first, good deep anchoring of distal microcoil end to avoid dislodgment and second, CT scan guidance for needle withdrawal to deploy proximal microcoil end on the pleural surface and to avoid chest wall or lung parenchymal misplacement. Although the microcoil is ideally placed through the nodule, it can be placed close to the nodule since the surgeon can see the relationship between the coil and the nodule on postlocalization CT scan [Figures 7 and 8]. Insufficient distal anchoring may allow the microcoil to be displaced into the chest wall or reformed in the pleural space [Figures 9 and 10]. Placement of the proximal end of microcoil on the pleural surface is done under CT guidance. Therefore, the microcoil can be misplaced in the chest wall or completely placed in the lung parenchyma [Figures 11 and 12].[5,6] Subpleural nodules are often pushed away rather than transgressing by needle. Thus, if microcoil is deployed, it will retract on the plural surface after needle withdrawal [Figure 13].[9]

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Figure 7: Microcoil placed just adjacent to the pulmonary nodule.

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Figure 7: Microcoil placed just adjacent to the pulmonary nodule.

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Figure 8: Microcoil placed about 1 cm beside the pulmonary nodule.

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Figure 8: Microcoil placed about 1 cm beside the pulmonary nodule.

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Figure-9.jpg

Figure 9: Microcoil misplaced completely within the chest wall. Moderate amount of pneumothorax is noted.

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Figure 9: Microcoil misplaced completely within the chest wall. Moderate amount of pneumothorax is noted.

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Figure 10: Lateral chest X-ray showing the microcoil fallen into the pleural space at the posterior costophrenic angle.

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Figure 10: Lateral chest X-ray showing the microcoil fallen into the pleural space at the posterior costophrenic angle.

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Figure-11.jpg

Figure 11: Proximal microcoil end misplaced into the chest wall.

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Figure 11: Proximal microcoil end misplaced into the chest wall.

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Figure 12: Microcoil misplaced completely within the lung parenchyma.

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Figure 12: Microcoil misplaced completely within the lung parenchyma.

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Figure-13.jpg

Figure 13: Chiba needle tip pushed the pulmonary nodule. After deploying the microcoil and withdrawing the needle, it retracted into the pleural surface and fell in the pleural cavity laterally.

Figure-13.jpg

Figure 13: Chiba needle tip pushed the pulmonary nodule. After deploying the microcoil and withdrawing the needle, it retracted into the pleural surface and fell in the pleural cavity laterally.

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In case of misplacement, surgeons could adjust the thoracoscopic surgery by knowing the relationship of the microcoil location to the nodule on postplacement CT scan. Surgeons can also adjust by removing the misplaced proximal end from the chest wall before deflating the lung or using the fluoroscopy for misplaced microcoil placed completely inside the lung parenchyma. In case of complete dislodgment, another microcoil could be placed properly. Misplaced microcoil in the chest wall, plural space, or lung parenchyma could be removed during surgery or kept in place and is associated with little damage.[5,6]

MICROCOIL PLACEMENT COMPLICATIONS


CT-guided microcoil localization results in a similar complication profile and rate as has been reported for CT-guided, fine-needle aspiration biopsy, mainly pneumothorax and hemorrhage. Emphysema is a well-known risk factor of increased risk for pneumothorax during percutaneous lung microcoil placement, and CT-guided, fine-needle aspiration biopsy that if symptomatic may necessitate insertion of a chest tube [Figure 14].[6,9,10,11] Postprocedural hemorrhage is manifested by new airspace consolidation [Figure 15]. Wires in the chest wall are not associated with increased patient discomfort or pain.[5]

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Figure 14: Postlocalization computed tomography image demonstrates moderate amount of pneumothorax.

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Figure 14: Postlocalization computed tomography image demonstrates moderate amount of pneumothorax.

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Figure-15.jpg

Figure 15: Postlocalization computed tomography image demonstrates mild parenchymal lung hemorrhage in the tract of microcoil localization needle.

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Figure 15: Postlocalization computed tomography image demonstrates mild parenchymal lung hemorrhage in the tract of microcoil localization needle.

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CONCLUSION


VATS is diagnostic and therapeutic of small pulmonary nodules. Preoperative pulmonary nodule localization is required to decrease the rate of conversion to thoracotomy. Various localization techniques were described in the literature. Microcoil localization to fluoroscopically guided VATS excision of small lung nodules increased its success rate of excision.

Financial support and sponsorship

Nil.

Conflicts of interest

There are no conflicts of interest.

REFERENCES


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How to cite this article:

Alharbi SR. Computed Tomography-guided Pulmonary Nodule Microcoil Localization Technique, Misplacement Errors, and Complications: A Pictorial Essay.. J Clin Imaging Sci 2018;8(8):1-5.



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