Methylene blue-stained autologous blood for needle localization and thoracoscopic resection of deep pulmonary nodules

Current Surgical Approach to Pulmonary Metastasectomy

The lung is a common site of metastases for children and adolescents with a wide variety of solid tumors. The role for pulmonary metastasectomy is dictated by tumor histology and can serve either therapeutic or diagnostic purposes. Careful surgical planning is required to determine the optimal surgical approach and to ensure successful nodule localization. While high level data are limited, in appropriate situations pulmonary metastasectomy can confirm staging, guide therapy, improve survival, and reduce the need for other therapy escalations.

Stability and safety of transbronchial dye mixture for preoperative localization in a porcine model

OBJECTIVE

For thoracoscopy, the usefulness of a dye mixture of indigo carmine and Lipiodol for localizing lung lesions has been reported. However, little is known about the stability and safety of this dye mixture injected on the visceral pleura through a bronchoscope.

METHODS

Porcine models were divided into three groups according to the detection time of the dye mixture: group A with a detection time of 4 h; group B, 8 h; and group C, 24 h. A dye mixture of indigo carmine and Lipiodol (0.5 mL each) was sprayed onto the visceral pleura both in the ventral and dorsal regions via a spray catheter.

RESULTS

Twelve markings were created on the visceral pleura of the porcine lung (six ventral and six dorsal) in the six porcine models. At predetermined detection times, all 12 dye markings (100%) were visible on the visceral pleura. The mean longest diameter of the dye marking in the ventral and dorsal regions was 18.8 mm and 24.3 mm, respectively. In groups B and C, pathological changes in the lymphatic system, such as lymphatic dilatations, were found; minimal changes were found in group B, however, these changes with oval-shaped lymphatic cysts and Lipiodol accumulation, were more evident in group C.

CONCLUSIONS

The dye mixture of indigo carmine and Lipiodol had reliable stability and visibility. In terms of safety, it may be necessary to check the dye mixture on the lung surface within 8 h.

Using the robotic platform in the therapy of multifocal ground glass opacities

Due to their association with invasive adenocarcinoma, ground glass opacities that reach 3 cm in size, develop a solid component ≥2 mm on mediastinal windows, or exhibit ≥25% annual growth warrant operative resection. Minimally invasive techniques are preferred given that approximately one third of patients will present with multifocal focal disease and may require additional operations. A robotic-assisted thoracoscopic surgical approach can be used with percutaneous or bronchoscopic localization techniques and are compatible with developing intraoperative molecular targeting techniques.

Evaluation of the radiofrequency identification lung marking system: a multicenter study in Japan

BACKGROUND

The radiofrequency identification (RFID) lung marking system is a novel technique using near-field radio-communication technology. The purpose of this study was to investigate the utility and feasibility of this system in the resection of small pulmonary nodules.

METHODS

We retrospectively reviewed clinical records of 182 patients who underwent sublobar resection with the RFID marking system between March 2020 and November 2021 in six tertial hospitals in Japan. Target markings were bronchoscopically made within 3 days before surgery. The contribution of the procedure to the surgery and safety was evaluated.

RESULTS

Target nodule average diameter and depth from the lung surface were 10.9 ± 5.4 mm and 14.6 ± 9.9 mm, respectively. Radiologically, one third of nodules appeared as pure ground-glass nodules (GGNs) on CT. The average distance from target nodule to RFID tag was 8.9 ± 7.1 mm. All surgical procedures were completed by video-assisted thoracoscopic surgery. Planned resection was achieved in all cases without any complications. The surgeons evaluated this system as helpful in 93% (necessary: 67%, useful; 26%) of cases. Nodule radiological features (p < 0.001) and type of surgery (p = 0.0013) were associated with the degree of contribution. In most cases, identification of the RFID tag was required within 1 min despite adhesion (p = 0.27).

CONCLUSION

The RFID lung marking system was found to be safe and effective during successful sublobar resection. Patients with pure GGNs are the best candidates for the system.

Computed tomography-guided localization of pulmonary nodules prior to thoracoscopic surgery

With the increasing awareness of physical examination, the detection rate of pulmonary nodules is gradually increasing. For pulmonary nodules recommended for management by video-assisted thoracic surgery (VATS), preoperative localization of the nodule is required if its location is difficult to determine intraoperatively by palpation. The computed tomography (CT)-guided preoperative localization technique is the most widely used method with low operational difficulty and high efficiency, which can include hook wire, microcoil, medical dye, medical surgical adhesive, combined application, and emerging localization techniques according to the material classification. Each method has its corresponding advantages and disadvantages, but there is still a lack of unified guidelines or standards for the selection of CT-guided preoperative localization methods in clinical practice. This review summarizes the operation precautions, advantages, and shortcomings of the above localization techniques in order to provide references for clinical application.

CT guided autologous blood localization of pulmonary ground glass nodules for video assisted thoracoscopic surgery compared to micro-coil localization

OBJECTIVES

To investigate feasibility and safety of autologous blood in preoperative computed tomography (CT)-guided localization of pulmonary ground-glass nodules (GGNs) by comparing to mico-coil prior to video-assisted thoracoscopic surgery.

METHODS

Clinical data of patients with GGNs who underwent video-assisted thoracoscopic surgery followed by preoperative CT-guided autologous blood or micro-coil localization was retrospectively reviewed in our department between September 2019 and November 2021. The localization duration, localization success rate, localization-related complication, localization cost, operation time, and conversion rate were compared between the 2 localization groups.

RESULTS

Totally 65 patients with 65 GGNs were included in our study, with 34 patients in autologous blood group (group B) and 31 patients in micro-coil group (group M). There is no conversion to thoracotomy. The age, sex, nodule location, diameter of nodule and distance from the pleura between the 2 groups were statistically comparable. Compared with group M, group B had similar localization success rate (94.1% vs 83.9%, P = 0.183) but shorter localization time (14.50 ± 2.61 min vs 16.35 ± 2.30 min, P = 0.004), lower cost ($92.4 ± 3.2 vs $475.6 ± 8.5, P = 0.001), and lower incidence of puncture complications (3.0% vs 19.3%, P = 0.042).

CONCLUSIONS

The autologous blood localization is an effective and more economical method for preoperative GGNs localization, and is associated with fewer complications compared to micro-coil localization.

Interhospital variability in localization techniques for small pulmonary nodules in children: A pediatric surgical oncology research collaborative study

BACKGROUND

Pulmonary nodules that are deep within lung parenchyma and/or small in size can be challenging to localize for biopsy. This study describes current trends in performance of image-guided localization techniques for pulmonary nodules in pediatric patients.

METHODS

A retrospective review was performed on patients < 21 years of age undergoing localization of pulmonary nodules at 15 institutions. Localization and resection success, time in interventional radiology (IR), operating room (OR) and total anesthesia time, complications, and technical problems were compared between techniques.

RESULTS

225 patients were included with an average of 1.3 lesions (range 1-5). Median nodule size and depth were 4 mm (range 0-30) and 5.4 mm (0-61), respectively. The most common localization techniques were: wire + methylene blue dye (MBD) (28%), MBD only (25%), wire only (14%), technetium-99 only (11%), coil + MBD (7%) and coil only (5%). Localization technique was associated with institution (p < 0.01); technique and institution were significantly associated with mean IR, OR, and anesthesia time (all p < 0.05). Comparing techniques, there was no difference in successful IR localization (range 92-100%, p = 0.75), successful resection (94-100%, p = 0.98), IR technical problems (p = 0.22), or operative complications (p = 0.16).

CONCLUSIONS

Many IR localization techniques for small pulmonary nodules in children can be successful, but there is wide variability in application by institution and in procedure time.

LEVEL OF EVIDENCE

Retrospective review, Level 3.

Augmented reality-assisted localization of solitary pulmonary nodules for precise sublobar lung resection: a preliminary study using an animal model

Background

Accurate localization of early lung cancer, manifested as solitary pulmonary nodules (SPNs) on computed tomography (CT), is critical in sublobar lung resection. The AR-assisted localization of SPNs was evaluated using a pig animal model.

Methods

A Microsoft HoloLens AR system was used. First, a plastic thoracic model was used for the pilot study. Three female 12 months 45 kg Danish Landrace Pigs were then used for the animal study. Thirty natural pulmonary structures, such as lymphonodus and bifurcated bronchioles or bronchial vessels, were chosen as simulated SPNs. The average angle between the actual puncturing needle and the expected path, the average distance between the puncture point and the plan point, and the difference between the actual puncturing depth and expected depth were recorded, and the accuracy rate was calculated.

Results

The point selected in the plastic thoracic model could be hit accurately with the assistance from the AR system in the pilot study. Moreover, the average angle between the actual puncturing needle and the expected path was 14.52°±6.04°. Meanwhile, the average distance between the puncture point and the expected point was 8.74±5.07 mm, and the difference between the actual and expected depths was 9.42±7.95 mm. Puncturing within a 1 cm³ area around the SPN using a hook-wire was considered a successful hit. The puncture accuracy was calculated. The average hit rate within a spherical area with a diameter of 1 cm range was 76.67%, and within a diameter of 2 cm range was 100%.

Conclusions

The HoloLens AR-assisted localization of SPNs may become a promising technique to improve the surgical treatment of early-stage lung cancer. Here, we evaluated its feasibility in an animal model. Nevertheless, its safety and effectiveness require further investigation in clinical trials.

The role of thoracoscopic lung biopsy in the management of children with solid organ malignancies and suspected lung metastases in a developing country

Background

Accurate diagnosis of lung lesions appearing on computed tomographic (CT) imaging in children with solid organ malignancies can be difficult. Therefore, this study aimed to determine, in a developing country setting, (1) the utility of thoracoscopic lung biopsy for assessment of suspected lung metastases in solid organ malignancies, and (2) the pathology of biopsied lesions suspected to be malignancies. The electronic records of all patients with solid organ malignancies who underwent thoracoscopic lung biopsies for suspected metastases at a tertiary hospital in South Africa between January 2012 and December 2017 were analysed retrospectively.

Results

A total of 29 thoracoscopic biopsies were taken from 25 patients. In eight biopsies (27.6%), viable metastatic tumour was identified; in one, a completely necrotic tumour was found. Seven patients (28.0%) were found to have infective aetiologies which required alternative therapies: of these, three patients had tuberculosis; three had bronchopneumonia and one had a fungal lung infection. Other findings included haemorrhagic infarction (n = 1); non-specific fibrosis (n = 1) and reactive lymph node (n = 1). In ten biopsies (34.5%), no lesion was found on thoracoscopy.

Conclusions

Thoracoscopy was found to improve the management of children with solid organ malignancies and suspected metastases. Thoracoscopy enabled many patients to avoid additional chemotherapy and radiotherapy and its negative consequences and enabled therapy for specific benign pathologies including infections.

Computed tomography-guided marking using a dye-staining method for preoperative localization of tiny pulmonary lesions in children

PURPOSE

It is important to confirm the existence of pulmonary metastases in pediatric patients with malignancies. Therefore, we aimed to investigate if computed tomography CT-guided marking is a feasible and safe method for the identification and resection of tiny pulmonary lesions in pediatric cancer patients.

METHODS

We retrospectively reviewed the medical records of pediatric cancer patients who underwent CT-guided marking procedures in our institutions between Jan 2011 and Apr 2020. After 2015, these procedures were combined with an indocyanine green (ICG) navigation-guided surgery for hepatoblastoma cases.

RESULTS

We targeted a total of 22 nodules in 12 patients. Of these, marking was successful in 18 (81.8%) nodules, 10 of which contained viable malignant cells. Complications caused by the marking procedures included mild pneumothorax and mild atelectasis in two patients, respectively. Of the eight resected nodules in patients with hepatoblastoma, four were ICG-positive and contained viable malignant cells. Two additional ICG-positive nodules, which were unidentified before surgery, were observed intraoperatively.

CONCLUSION

CT-guided marking is a feasible and safe method that can be used to identify and resect tiny pulmonary lesions in pediatric cancer patients. An ICG navigation-guided surgery is useful when combined with CT-guided marking, particularly in hepatoblastoma cases.

Microcoil localization as an effective adjunct to thoracoscopic resection of pulmonary nodules in children

BACKGROUND/PURPOSE

Thoracoscopic excision of pulmonary nodules is often required for diagnostic or therapeutic purposes, however subpleural and sub-centimeter nodules can be difficult to visualize. Various CT-guided localization techniques have been described, though there is minimal published pediatric data regarding the use of microcoils. We hypothesize that microcoil localization facilitates thoracoscopic resection of pulmonary nodules in children.

METHODS

A multi-institutional retrospective review of children who underwent preoperative CT-guided localization of lung nodules was conducted from 2012 to 2019. A combination of methylene blue dye (MBD), wires, and microcoils were utilized for CT-guided localization. When microcoils were utilized, fluoroscopy assisted in lesion identification and resection.

RESULTS

Eighteen patients (mean age 13 years, range 2-21 years) underwent thoracoscopic resection of 24 preoperatively localized pulmonary nodules. Mean size and depth of the lesions were 5.5 mm and 10 mm, respectively. Microcoil placement was successful 95% of the time and assisted in lesion localization in 88% of cases. Wire localization was not a durable technique, as 3 of 5 wires became dislodged upon lung  isolation.

CONCLUSIONS

Preoperative CT-guided localization with microcoils can assist in fluoroscopic-guided resection of pulmonary nodules in children. This technique avoids the pitfall of wire dislodgement, and provides surgeons an additional technique to localize sub-centimeter, subpleural nodules.

TYPE OF STUDY

Retrospective Review.

LEVEL OF EVIDENCE

Level III.

Evaluation of factors affecting the visualization of dye after transbronchial dye injection: an animal experiment

Background

Since peripheral lung lesions can be frequently visualized on computed tomography (CT), various methods of localization for thoracoscopic surgery have been developed. In the case of transbronchial dye injection (TDI), there can be difficulties with dye visualization through the thoracoscope depending on early disappearance of the dye due to diffusion before field exposure. Herein, we performed an animal experiment to determine the appropriate dye amount and the duration of visualization.

Methods

Twelve pigs were experimented as following four groups (n=3): group 1 received 0.6 mL of dye; group 2 as 0.8 mL; and group 3 as 1.0 mL, all followed by 2.0 mL of air injection and group 4, with 1.0 mL of dye followed no air injection to evaluate the utility of air injection. The detection, the peak time, the wash-out time were measured.

Results

The mean detection times, the peak time, and the mean wash-out times for 0.6, 0.8, and 1.0 mL of dye were not significantly different (P=0.195, 0.092, 0.06). However, regardless of the injected amount, it usually lasts in 2 hours. Comparing with non-air injection group, the peak time and wash-out time were statistically significantly different in injected group; P=0.07 and 0.001.

Conclusions

The marking could be identified clearly at about 2 hours after TDI regardless of the amount of indigo carmine injected. However, in cases with longer duration to exposure, especially in cases with severe adhesions, it might be necessary to discover the mixture of dye which will last longer for visualization of lung nodules.

A Surgeon's Guide for Various Lung Nodule Localization Techniques and the Newest Technologies

Preoperative image-guided localization of lung nodules is necessary for successful intraoperative localization and resection. However, current localization techniques carry significant intraoperative disadvantages for surgeons. Articles were selected through multiple search engines using key search terms and reviewed to compare results, outcomes, advantages, limitations, and complications of various localization methods. Current methods utilize microcoils, hookwires, contrast media, dyes, cyanoacrylate, radiotracers, or fluorescence tracers, which are associated with many intraoperative disadvantages even when paired with other imaging modalities including computed tomography and bronchoscopy techniques. Novel technologies including robotic bronchoscopy, 4-hook anchor, SPiN Thoracic Navigation System, superDimension, Ion Endoluminal System, and the SCOUT system are reviewed including their advantages, which may change the future direction of minimal thoracoscopic surgery with potential to improve intraoperative accuracy and efficiency.

CT-guided blood tattoo for thoracoscopic excision of lung lesions in pediatric patients

Background

To describe a single-institutional experience with an innovative technique using CT-guided injection of autologous blood for localization of nonpleural-based pulmonary nodules prior to thoracoscopic excisional biopsy in pediatric patients.

Methods

A retrospective review of all patients under the age of 18 with lung lesions suspected to be malignant that were not pleural-based lesions and were not of adequate size to visualize at thoracoscopy, who underwent CT-guided blood tattoo (CGBT) localization between 2006-2019. CGBT was performed under general anesthesia by injecting 0.5-10 mL of autologous blood into the area of the lesions. The patients were then immediately transferred from interventional radiology to the operating room for thoracoscopic excision of the lesion. Demographics, location of lesions, indication for biopsy, and pathology were reviewed.

Results

In eleven pediatric patients (ages ranging from 4-18 years), preoperative CGBT localization of pulmonary nodules resulted in successful thoracoscopic excisional biopsy. All resections were diagnostic and 82% (9/11 cases) represented a metastatic malignancy as confirmed by pathology. Malignant nodules ranged from 2 to 14 mm in size, while a 13 mm nodule in a patient with history of AML was determined to be an organizing pneumonia and a 12 mm nodule in a second patient revealed a caseating granuloma consistent with Crohn's disease. One patient with a failed attempt at excisional biopsy without preoperative localization then underwent CGBT one week later with successful thoracoscopic excision of the nodule.

Conclusions

CT-guided blood tattoo is a safe option for localization of nonpleural-based lung nodules prior to thoracoscopic excision in pediatric patients.

Intraoperative Detection and Assessment of Lung Nodules

Lung cancer is the most frequent cause of cancer-related death worldwide. Despite advances in systemic therapy, the 5-year survival remains humbling at 4% to 17%. For those diagnosed early, surgical therapy can yield potentially curative results. Surgical resection remains a cornerstone of medical care. Success hinges on sound oncologic resection principles. Various techniques can be used to identify pulmonary nodules. A challenge is intraoperative assessment of the surgical specimen to confirm disease localization and ensure an R0 resection. The primary tool is frozen section. Understanding the options available enhances the arsenal of thoracic surgeons and leads to better patient care.

Planting Seeds into the Lung: Image-Guided Percutaneous Localization to Guide Minimally Invasive Thoracic Surgery

Image-guided localization materials are constantly evolving, providing options for the localization of small pulmonary nodules to guide minimally invasive thoracic surgery. Several preoperative methods have been developed to localize small pulmonary lesions prior to video-assisted thoracic surgery. These localization techniques can be categorized into 4 groups according to the materials used: localization with metallic materials (hook-wire, microcoil, or spiral coil), localization with dye (methylene blue or indigo carmine), localization with contrast agents (lipiodol, barium, or iodine contrast agents), and radiotracers (technetium-99m). However, the optimal localization method has not yet been established. In this review article, we discuss the various localization techniques and the advantages and disadvantages of localization techniques as well as the available safety and efficacy data on these techniques.

Preoperative Computed Tomography-Guided Localization for Pulmonary Nodules with Glue and Dye

BACKGROUND

This study was aimed to describe a new localization technique developed using medical glue and methylene blue dye, and characterized the localization results and postoperative outcome to evaluate its safety and usefulness.

METHODS

This retrospective study was conducted at our center from January 2016 to April 2018. Totally 346 consecutive patients with 383 nodules who underwent preoperative computed tomography (CT)-guided medical glue and methylene blue dye localization, followed by lung resection, were enrolled in this study.

RESULTS

Mean nodule size was 7.7 ± 3.7 mm (range: 2-30 mm), with a mean depth from pleura or fissure of 9.4 ± 9.3 mm (range: 0-60 mm). The success rate of CT-guided localization for pulmonary nodules was 99.5% (381/383) of the nodules. Localization-related complications included mild pneumothorax in 16 (4.6%) patients, mild hemothorax in 7 (2.0%) patients, and hemoptysis in 1 (0.3%) patient. Pleural reaction occurred in 7 (2.0%) and pain in 25 (7.2%) patients. All 383 nodules were resected successfully, with conversion to thoracotomy only required in two patients for adhesion and calcification of lymph nodes. All patients recovered well postoperatively, with a short postoperative hospital stay (3.7 ± 2.0 days) and a low complication rate (2.6%, 9/346).

CONCLUSION

CT-guided medical glue and methylene blue dye localization prior to video-assisted thoracoscopic surgery (VATS) lung resection was a novel, safe, and technically feasible method, with a high-technical success rate and a low-complication rate. It allowed surgeons to easily locate and detect the nodules and estimate the surgical margin.

Preresection Stained Glue Injection to Localize Pulmonary Small Nodules and Ground-glass Opacities

Objective:

We sought to introduce a localization procedure (methylene blue-stained N-butyl cyanoacrylate and N-octyl cyanoacrylate glue) in localizing pulmonary small nodules and ground-glass opacities before thoracoscopic resection, and to evaluate its efficacy.

Methods:

A total of 20 patients with pulmonary small nodules and/or ground-glass opacities, who underwent video-assisted thoracoscopic surgery from August 1, 2017 to March 1 2018, were included in the study.

Results:

A total of 24 lesions in 20 patients underwent blue-stained glue localization. The success rate of localization was 100%, with a mean dose of 0.04±0.01 mL blue dye and 1 mL glue used for each lesion. The average time for the whole localization procedure was 15.4±6.3 minutes. All lesions were intraoperatively localized by visual inspection in combination with palpation. The complications related to the localization procedure included mild pneumothorax occurring in 9 patients and minor pulmonary hematoma in 4 patients. No pain or distress was reported.

Conclusions:

Blue-stained glue injection is technically feasible and safe to localize pulmonary small nodules and ground-glass opacities before thoracoscopic resection.

Video-assisted thoracoscopic resection of lung nodules localized with a hydrogel plug

OBJECTIVES

Computed tomography (CT)-guided hydrogel plug deployment was recently proposed for lung nodule preoperative localization and simultaneous prevention of pneumothorax. We analysed our initial experience with CT-guided hydrogel plug localization of lung nodules in patients undergoing video-assisted thoracoscopic (VATS) resection.

METHODS

We retrospectively evaluated the medical notes from 27 consecutive patients (mean age 68 ± 11 SD years; men 74%) undergoing VATS lung wedge resection for biopsy or definitive treatment of 28 small pulmonary nodules (malignant 82%) at a single institution between October 2017 and July 2018. Difficult intraoperative nodule localization was anticipated with a lesion <10 mm, a depth from pleura:size ratio >1, ground-glass opacity or the judgement of the operating surgeon. All lesions were preoperatively marked by deployment of a CT-guided hydrogel plug. Study end points were frequency of postlocalization pneumothorax; feasibility of delayed surgery; rate of localization of intraoperative nodule and rate of successful VATS resection.

RESULTS

The mean sizes of the solid nodules (n = 24) and of the ground-glass opacities (n = 4) were, respectively, 10.4 ± 3.4 mm and 16.0 ± 6.2 mm. One (4%) hydrogel plug marking procedure caused a clinically relevant pneumothorax. Nodule resection was scheduled flexibly as required by patient management/operating room scheduling: same day (11 nodules) or delayed [median 6 days (range 1-60 days)]; (17 nodules). All nodules were localized intraoperatively: 25 (89%) by hydrogel plug; 3 (11%) by palpation and pleural puncture hole visible after plug displacement. All nodules were completely excised by VATS, without complications.

CONCLUSIONS

CT-guided hydrogel plug marking was valuable for VATS localization and resection of challenging lung nodules. The plug minimized clinically relevant pneumothoraxes and allowed flexible surgical schedules.

Computed tomography-guided preoperative semi-rigid hook-wire localization of small pulmonary nodules: 74 cases report

OBJECTIVES

The study aimed to retrospectively evaluate the success rate, utility, practicality and results of pre-operative CT (computed tomography)-guided semi-rigid single hook-wire placement and the pathology results of small pulmonary nodules (SPN).

MATERIALS AND METHODS

Seventy-four patients with 81 small pulmonary nodules underwent CT-guided semi-rigid single hook wire localization consecutively between 2016 and 2017 were reviewed. VATS (video-assisted thoracoscopic surgery) resection of lung tissue containing each pulmonary nodule and were performed in the direction of hook wire. The success rate and utility of the localization, hook wire related complications, the histopathology of SPN are analyzed.

RESULTS

The semi-rigid hook wire was performed successfully in all 81 small pulmonary nodules within mean time of 10 min (8-13 min, SD: 1.58 min). Compared with solid nodules, GGOs (ground-glass opacity) were more frequently malignant (p < 0.05), with an OR (odds ratio) 8.59 (95%CI, 0.967, 412.845). Of the pure GGOs, 9 (25%) nodules were classified as AIS, 10 (27.8%) nodules were classified as MIA and 22 (57.9%) of the mGGOs were lung cancer. According to multivariate analysis, the malignant hazard was as high as 6.533-fold higher in nodules with a size larger than 10 mm compared with those smaller than 10 mm. GGOs with tiny blood vessels showed a statistically significant correlation with malignancy. Surprisingly, no statistically significant difference in the incidence of lung cancer in age. No major complication occurred.

CONCLUSIONS

Preoperative localization of small pulmonary nodules using semi-rigid single hook wire was found to be practical and safe, which allows for proper diagnosis. Incidental small pulmonary nodule, especially GGO larger than 10 mm needs to be taken seriously.

Placement of markers to assist minimally invasive resection of peripheral lung lesions

With development of lung cancer screening programs and increased utilization of radiographic imaging there is significantly higher detection of smaller lung nodules and subsolid lesions. These nodules could be malignant and pose a diagnostic challenge. Video-assisted thoracoscopic surgery and robotic-assisted thoracoscopic surgery (RATS) represent minimally invasive methods for tissue sampling. Intraoperative identification of these lesions maybe difficult, requiring marking prior to surgery. We review different techniques for the placement of markers to assist in the resection of peripheral lung lesions (PLL).

A simple and efficient method to perform preoperative pulmonary nodule localization: CT-guided patent blue dye injection

OBJECTIVE

To assess the efficacy of computed tomography (CT)-guided localization with the injection of a low dose of patent blue dye (PBD) for the thoracoscopic resection of pulmonary nodules.

MATERIALS AND METHODS

Overall, 125 consecutive patients underwent CT-guided localization with injection of a lower dose of PBD between June 2015 and June 2016. The total injection dose relative to the distance between nodules and the visceral pleura was recorded. The clinical and radiological characteristics, technical details, pathological results and procedure-related complications were reviewed.

RESULTS

A total of 137 indeterminate pulmonary nodules were identified. The mean nodule size was 9.5 (3.0-22.0) mm. The mean injection dose of PBD relative to the distance between nodules and the visceral pleura was classified as follows: 0.07 ml: <1 cm, 0.1 ml: 1-2 cm and 0.18 ml: >2 cm. The mean time of CT-guided localization was 16.5 (10-50) min. The mean time interval from localization to surgery was 188 (24-1440) min. Pneumothorax developed in 50 patients (40%), and focal parenchymal hemorrhage occurred in 16 patients (12.8%) after localization. No patient required chest tube placement or emergent resuscitation. The success rate of dye marking was 98.5% (135/137). Malignancies, including 82 lung cancers, were diagnosed in 97 nodules (70.8%).

CONCLUSION

The injection of a lower dose PBD based on the distance to the visceral pleura can be successful with nodular localization and may facilitate thoracoscopic surgery, even in cases with a long interval from localization to surgery.

Electromagnetic Transthoracic Nodule Localization for Minimally Invasive Pulmonary Resection

BACKGROUND

Increased use of chest computed tomography and the institution of lung cancer screening have increased the detection of ground-glass and small pulmonary nodules. Intraoperative localization of these lesions via a minimally invasive thoracoscopic approach can be challenging. We present the feasibility of perioperative transthoracic percutaneous nodule localization using a novel electromagnetic navigation platform.

METHODS

This is a multicenter retrospective analysis of a prospectively collected database of patients who underwent perioperative electromagnetic transthoracic nodule localization before attempted minimally invasive resection between July 2016 and March 2018. Localization was performed using methylene blue or a mixture of methylene blue and the patient's blood (1:1 ratio). Patient, nodule, and procedure characteristics were collected and reported.

RESULTS

Thirty-one nodules were resected from 30 patients. Twenty-nine of 31 nodules (94%) were successfully localized. Minimally invasive resection was successful in 93% of patients (28/30); 7% (2/30) required conversion to thoracotomy. The median nodule size was 13 mm (interquartile range 25%-75%, 9.5-15.5), and the median depth from the surface of the visceral pleura to the nodule was 10 mm (interquartile range 25%-75%, 5.0-15.9). Seventy-one percent (22/31) of nodules were malignant. No complications associated with nodule localization were reported.

CONCLUSIONS

The use of intraoperative electromagnetic transthoracic nodule localization before thoracoscopic resection of small and/or difficult to palpate lung nodules is safe and effective, potentially eliminating the need for direct nodule palpation. Use of this technique aids in minimally invasive localization and resection of small, deep, and/or ground-glass lung nodules.

[A Preliminary Study to Evaluate the Efficacy and Safety of A Optimized Computed Tomography-guided Pulmonary Nodule Microcoil Localization Technique]

背景与目的

肺内小结节微弹簧圈穿刺定位是微创手术切除肺内小结节常用的术前定位方法，然而该方法仍有操作复杂、轻微并发症多等不足之处，我们将原有方法进行了优化。本研究旨在探讨优化后的预充式计算机断层扫描（computed tomography, CT）引导下肺内小结节微弹簧圈穿刺定位法在临床中的应用价值。

方法

对2018年9月-2019年1月间31例患者的35枚肺结节，于术前采用预充式CT引导下肺内小结节微弹簧圈穿刺定位，然后施行胸腔镜下（video-assisted thoracoscopic surgery, VATS）手术。统计分析定位操作相关数据、成功率、并发症、病理结果等。

结果

定位成功率97.1%，VATS切除成功率100%。CT定位时间平均10.1 min（5 min-31 min），微创切除病灶所需时间平均38.2 min（10 min-100 min）。术中发现微弹簧圈脱位回缩至胸壁内1例，通过充气膨肺状态下自胸壁穿刺点刺入穿刺针，成功定位肺内结节并予以切除。3例患者定位后发生微量气胸，但无需闭式引流处理。3例患者出现肺内血肿。35枚肺结节术后病理结果为：高分化腺癌15例，原位癌7例，微浸润腺癌5例，非典型腺瘤样增生4例，肺内淋巴结增生、炎性结节各2例。

结论

采用预充式微弹簧圈定位肺内小结节简便、安全、有效，值得推广。

Computed tomography-guided dye localization for deeply situated pulmonary nodules in thoracoscopic surgery

Background

Increased lung cancer screening of asymptomatic adults using low-dose computed tomography (CT) with high-resolution imaging modalities has increased the identification of small and deeply situated pulmonary nodules. This study aimed to evaluate the role of preoperative patient blue vital (PBV) dye localization for an undiagnosed nodule deeply situated in the lung parenchyma followed by minimally invasive lung resection.

Methods

From July 2013 to December 2016, 27 consecutive patients (16 women, median age: 62 years) with small undiagnosed pulmonary nodules at a depth of more than 30 mm underwent preoperative CT-guided PBV dye localization followed by thoracoscopic diagnostic resection of the nodule at National Taiwan University Hospital. The clinical characteristics were collected retrospectively to evaluate the efficacy and safety of the procedure.

Results

The median size of pulmonary nodule in preoperative CT images was 11 mm with a median depth of 31.6 mm (range, 30.0-48.6 mm). Of the 27 nodules, 8 were pure ground-glass nodules, 3 were pure solid nodules, and 16 were partially solid nodules. The diagnostic yield of CT-guided dye localization following diagnostic wedge resection was 100%. The final pathological diagnoses were: primary adenocarcinoma of the lung (n=20), adenocarcinoma in situ (n=1), and benign nodules (n=6). Only asymptomatic complications were noted after localization, and the median hospital stay was 3 days [interquartile range (IQR), 3-4 days]. All of 21 patients were cancer-free after a median follow-up of 39.0 months (IQR, 29.5-50.0 months).

Conclusions

This study indicated that preoperative, percutaneous CT-guided PBV dye localization for undiagnosed nodules at a depth of more than 30 mm could be a safe and feasible procedure. Furthermore, it was considerably advantageous for preserving the lung parenchyma, especially for benign nodules.

Intraoperative fluorescence imaging in thoracic surgery

Intraoperative fluorescence imaging (IFI) can improve real-time identification of cancer cells during an operation. Phase I clinical trials in thoracic surgery have demonstrated that IFI with second window indocyanine green (TumorGlow^® ) can identify subcentimeter pulmonary nodules, anterior mediastinal masses, and mesothelioma, while the use of a folate receptor-targeted near-infrared agent, OTL38, can improve the specificity for diagnosing tumors with folate receptor expression. Here, we review the existing preclinical and clinical data on IFI in thoracic surgery.

Use of radiotracer labeling of pulmonary nodules to facilitate excisional biopsy and metastasectomy in children with solid tumors

PURPOSE

Excision of suspected pulmonary metastases in children is challenging in the setting of multiple nodules or nodules that are small, deep, or soft. This study describes preoperative technetium macro-aggregated albumin (Tc 99m MAA) localization of pulmonary lesions to aid in intraoperative identification and resection.

METHODS

Patients with past or present pediatric solid tumors who underwent resection of pulmonary nodules following CT-guided Tc 99m MAA labeling were identified. The primary outcomes were successful preoperative localization and subsequent resection.

RESULTS

Metastasectomy following Tc 99m MAA localization was performed 15 times in 11 patients from 2014 to 2016. Mean age was 13years; the most common diagnosis was osteosarcoma (33%). Tc 99m MAA labeling was attempted in 24 nodules with mean nodule diameter 6±5mm and mean depth from the pleural surface of 12±17mm; localization was successful in 23 nodules (96%). Subsequent resection was performed by thoracotomy in 12 cases and thoracoscopy in 3. All labeled nodules were identified intraoperatively; two were not resected and 17 of the 21 nodules resected demonstrated metastatic disease on pathology.

CONCLUSION

Tc 99m MAA labeling of pulmonary nodules in children is effective in facilitating resection of sub-centimeter intraparenchymal metastases identified on preoperative imaging. Furthermore, this technique allows for thoracoscopic metastasectomy in select patients.

TYPE OF STUDY/LEVEL OF EVIDENCE

Case Series/Level IV.

CT-guided localization of pulmonary nodules in children prior to video-assisted thoracoscopic surgical resection utilizing a combination of two previously described techniques

BACKGROUND

Pulmonary nodules in pediatric oncology patients can present a diagnostic and treatment dilemma. Imaging findings are often nonspecific and tissue diagnosis may be required for appropriate treatment. The smaller subpleural nodules may not be visualized and cannot be palpated during video-assisted thoracoscopic surgical (VATS) resection. Preoperative localization has been beneficial in obtaining an adequate pathological specimen.

OBJECTIVE

This study presents experience in a large pediatric hospital using CT-guided preoperative localization of pulmonary nodules combining two previously utilized techniques, hook wire and methylene blue blood patch localization.

MATERIALS AND METHODS

A search of the electronic medical record utilizing a medical record search application was performed to identify all patients who underwent preoperative lung nodule localization during a 12.5-year period (July 1999 through January 2012). A retrospective chart review of these patients was then performed. Pre- and postoperative imaging, interventional radiology procedural images and reports, surgical reports, and pathology reports were obtained and evaluated.

RESULTS

Thirty-five patients, with 40 nodules, who underwent preoperative CT-guided lung nodule localization were identified. Patients ranged in age from 8 months to 21 years. The pulmonary nodules ranged in size from 1.4 mm to 18 mm. Twelve nodules were localized using a Kopans breast lesion localization needle with hook wire, 4 were localized using a methylene blue blood patch, and 24 were localized using the combination of these two techniques. The technical success rate of all procedures was 100%. A pathological diagnosis was determined in 39 patients (97.5%). There were 6 (15.0%) minor complications and no major complications.

CONCLUSION

CT-guided lung nodule localization using the combined techniques of methylene blue blood patch and hook wire is safe, technically feasible and successful in children. Using this combination of techniques will consistently yield a pathological diagnosis, is currently the preferred technique at our tertiary pediatric hospital and could be considered the new best practice.

The feasibility of electromagnetic navigational bronchoscopic localization with fluorescence and radiocontrast dyes for video-assisted thoracoscopic surgery resection

Recently, some groups have reported the utilization of electromagnetic navigational bronchoscopy (ENB) for localization of pulmonary lesion. Its application for intraoperative visual localization with dyes to determine the target area has been increasing. In this paper, we reviewed the feasibility of ENB utilization for video-assisted thoracoscopic surgery (VATS) or robotic sublobar resection as a localization tool, and its future application in minimally invasive thoracic surgery.

Pleural Dye Marking Using Radial Endobronchial Ultrasound and Virtual Bronchoscopy before Sublobar Pulmonary Resection for Small Peripheral Nodules

BACKGROUND

Minimally invasive surgery of pulmonary nodules allows suboptimal palpation of the lung compared to open thoracotomy.

OBJECTIVE

The objective of this study was to assess endoscopic pleural dye marking using radial endobronchial ultrasound (r-EBUS) and virtual bronchoscopy to localize small peripheral lung nodules immediately before minimally invasive resection.

METHODS

The endoscopic procedure was performed without fluoroscopy, under general anesthesia in the operating room immediately before minimally invasive surgery. Then, 1 mL of methylene blue (0.5%) was instilled into the guide sheath, wedged in the subpleural space. Wedge resection or segmentectomy were guided by visualization of the dye on the pleural surface. Contribution of dye marking to the surgical procedure was rated by the surgeon.

RESULTS

Twenty-five nodules, including 6 ground glass opacities, were resected in 22 patients by video-assisted thoracoscopic wedge resection (n = 11) or robotic-assisted thoracoscopic surgery (10 segmentectomies and 1 wedge resection). The median greatest diameter of nodules was 8 mm. No conversion to open thoracotomy was needed. The endoscopic procedure added an average 10 min to surgical resection. The dye was visible on the pleural surface in 24 cases. Histological diagnosis and free margin resection were obtained in all cases. Median skin-to-skin operating time was 90 min for robotic segmentectomy and 40 min for video-assisted wedge resection. The same operative precision was considered impossible by the surgeon without dye marking in 21 cases.

CONCLUSIONS

Dye marking using r-EBUS and virtual bronchoscopy can be easily and safely performed to localize small pulmonary nodules immediately before minimally invasive resection.

Image-guided surgery and therapy for lung cancer: a critical review

Of the many imaging technologies, some have the potential to be used in image-guided surgery and therapy (IGS/IGT). This review of relevant papers on IGS/IGT for lung cancer indicates effective localization and IGS/IGT in early endobronchial lesions by fluorescence bronchoscopic technique. Visualization of early peripheral (nodular) tumors at operation can be achieved by a variety of imaging methods and devices which allow identification, localization and provision of intraoperative real-time images. Recent developments employing fluorescence contrasts and near infra-red light have shown encouraging feasibility and outcome in providing reliable methods for the IGS of cancer generally and lung cancer more specifically with provision of real time intraoperative imaging. The concept of the hybrid operating theater is touched upon.

Imaging-guided thoracoscopic resection of a ground-glass opacity lesion in a hybrid operating room equipped with a robotic C-arm CT system

The intraoperative identification of small pulmonary nodules through video-assisted thoracoscopic surgery remains challenging. Although preoperative CT-guided nodule localization is commonly used to detect tumors during video-assisted thoracoscopic surgery (VATS), this approach carries inherent risks. We report the case of a patient with stage I lung cancer presenting as an area of ground-glass opacity (GGO) in the right upper pulmonary lobe. He successfully underwent a single-stage, CT-guided localization and removal of the pulmonary nodule within a hybrid operating room (OR) equipped with a robotic C-arm.

A novel hybrid technique for localization of subcentimeter lung nodules

BACKGROUND

It is technically challenging to locate non-visible, non-palpable subcentimeter ground-glass nodules (GGNs) of lung during video-assisted thoracic surgery (VATS). Computed tomography (CT)-guided marking of small pulmonary nodules using microcoils has been reported to be a practical method of preoperative localization, whereas dislodgement of microcoils remains to be a bothersome complication. The objective of this study was to assess the viability and effectiveness of a newly developed hybrid technique, which combines induced controllable pneumothorax and CT-guided microcoil marking procedure to reduce the risk of microcoil dislodgement.

METHODS

After induced minor pneumothorax, 35 patients with subcentimeter GGNs underwent CT-guided marking with microcoils prior to VATS sublobar resection or lobectomy. Histopathological analysis was performed after surgeries.

RESULTS

All of 37 nodules were successfully marked before VATS. Segmentectomy was performed in 8 cases, wedge resection in 19 cases and lobectomy in 8 cases. All nodules were completely removed with marking microcoils. Dislodgement of microcoils was not observed in all cases and mild pulmonary hemorrhage occurred in one case. No other complications occurred.

CONCLUSIONS

The newly developed hybrid technique which combines induced controllable pneumothorax and CT-guided marking using microcoils was feasible and reliable for VATS resection of subcentimeter GGNs, meanwhile significantly lowered the risk of microcoil dislocation.

Image-guided techniques for localizing pulmonary nodules in thoracoscopic surgery

Low-dose computed tomography (LDCT) screening has increased the detection rate for small pulmonary nodules with ground-glass opacity (GGO) in the peripheral lung parenchyma. Minimally invasive thoracoscopic surgery for these lung nodules is challenging for thoracic surgeons, and image-guided preoperative localization is mandatory for their successful resection. Image-guided localization methods primarily include two imaging tools: computed tomography (CT) and bronchoscopy. These different methods may use different localized materials, including hookwires, dyes, microcoils, fiducial markers, contrast media, and radiotracers. Ultrasonography and near-infrared imaging are also used for intraoperative localization of lung lesions. In this article, we review different localization techniques and discuss their indications and limitations.

Image-guided thoracoscopic surgery with dye localization in a hybrid operating room

BACKGROUND

The rate of detection of small pulmonary nodules (SPNs) has increased. Thoracoscopic resection following image-guided localization had been a reliable alternative in their treatment. We present our experience with image-guided dye localization using robotic C-arm computed tomography (CT) followed by immediate video-assisted thoracoscopic surgery (VATS) for SPNs in a hybrid operating room (OR).

METHODS

From July 2015 to July 2016, 25 consecutive patients with SPNs smaller than 2 cm underwent robotic C-arm CT-guided blue dye tattooing followed by immediate VATS in a hybrid OR. Their medical records were retrospectively reviewed to evaluate the feasibility and safety of this novel procedure.

RESULTS

Robotic C-arm CT-guided dye localization was successfully performed in 23 patients (92%). Wound extension was required for nodule identification in the remaining two patients. The median size of the nodules was 1.0 cm (range, 0.6-2.0 cm). The median needle localization time and surgery time were 46 and 109 min, respectively. All 25 patients had successful resection of their lesions. The pathological diagnoses were primary lung adenocarcinoma in 18 (72%), benign tumors in 5 (20%), and metastatic lesions in 2 (8%). There was no operative mortality. The median length of the postoperative stay was 3 days (range, 2-8 days). Complications were noted in two patients (8%). One patient had a penetrating injury of the diaphragm during needle localization. The other had pneumonia postoperatively. Both patients were managed conservatively.

CONCLUSIONS

Our experience showed that robotic C-arm CT-guided dye localization followed by immediate thoracoscopic surgery in a hybrid OR is safe and feasible. It may become an effective and attractive alternative in managing SPNs.

CT-guided microcoil VATS resection of lung nodules: a single-centre experience and review of the literature

BACKGROUND

Video-assisted thoracoscopic surgery (VATS) is standard of care for small lung resections at many centres. Computed tomography (CT)-guided insertion of microcoils can aid surgeons in performing VATS resections for non-palpable lung nodules deep to the lung surface.

METHODS

Retrospective analysis of CT-guided microcoil insertions prior to VATS lung resection at a single institution from October 2008 to January 2014.

RESULTS

A total of 63 patients were included (37% male, mean age 61.6±11.4 years). Forty-two patients (67%) had a history of smoking, with 10 current smokers. Sixty one (97%) patients underwent wedge resection and 3 (5%) patients had segmentectomy. Three (5%) patients required intra-operative staple line re-resection for positive or close margins. Eleven (17%) patients had a completion lobectomy, 5 of which were during the same anaesthetic. The average time between the CT-guided insertion and start of operation was 136.6±89.0 min, and average operative time was 84.0±53.3 min. The intra-operative complication rate was 5% (n=3), including 1 episode of hemoptysis, and 2 conversions to thoracotomy. The post-operative complication rate was 8% (5 patients), and included 2 air leaks, 1 hemothorax (drop in hemoglobin), 1 post chest tube removal pneumothorax, and one venous infarction of the lingula after lingula-sparing lobectomy requiring completion lobectomy. . Average post-operative length of stay was 2.2 days. A diagnosis was made for all patients.

CONCLUSIONS

CT-guided microcoil insertion followed by VATS lobectomy is safe, with short operative times, short length of stay and 100% diagnosis of small pulmonary nodules. This technique will become more important in the future with increasing numbers of small nodules detected on CT as part of lung cancer screening programs.

Novel Methods of Intraoperative Localization and Margin Assessment of Pulmonary Nodules

Lung cancer screening has lead to frequent diagnosis of solitary pulmonary nodules, many of which require surgical biopsy for diagnosis and intervention. Subcentimeter and central nodules are particularly difficult to visualize or palpate during surgery, thus nodule localization can be a difficult problem for the thoracic surgeon. Although minimally invasive techniques including transthoracic computed tomography and bronchoscopic-guided biopsy may establish a diagnosis, these methods do not help locate nodules during surgery and can lead to inadequate tissue sampling. Therefore, surgical biopsy is often required for diagnosis and management of solitary pulmonary nodules. Additionally, after an excision, intraoperative margin assessment is important to prevent local recurrence. This is important for bronchial margins following lobectomy or parenchymal margins following sublobar resection. First, we examine methods of preoperative lesion marking, including wire placement, dye marking, ultrasound, fluoroscopy, and molecular imaging. Second, we describe the current state of the art in intraoperative margin assessment techniques.

A Simple and Safe Technique for CT Guided Lung Nodule Marking prior to Video Assisted Thoracoscopic Surgical Resection Revisited

Aim. We describe our experience of a simple, safe, and reproducible technique for lung nodule marking prethoracoscopic metastasectomy. Thoracoscopic lung nodule resection reduces patient discomfort, complications, higher level of care, hospital stay, and cost; however, small deeply placed lung nodules are difficult to locate and resect thoracoscopically. Materials and Methods. We describe and review the success of our novel technique, where nodules are identified on a low dose CT and marked with methylene blue using CT fluoroscopy guidance immediately prior to surgery. Results. 30 nodules were marked with a mean size of 8 mm (4-18 mm) located at a mean depth of 17 mm, distributed through both lungs. Dye was detected at the pleural surface in 97% of the patients and at the nodule in 93%. There were no major complications. Thoracoscopic resection was possible in 90%. Conclusion. This is a simple and safe method of lung nodule marking to facilitate thoracoscopic resection in cases where this may not be technically possible due to nodule location.

Preoperative computed tomography-guided percutaneous localization of ground glass pulmonary opacity with polylactic acid injection

Localization of a ground glass nodule is a difficult challenge for thoracic surgeons, especially for ground glass opacities (GGOs) less than 10 mm in diameter. In this study we implement a new method for preoperative localization of pulmonary (GGOs). From October 2013 to December 2014, computed tomography-guided percutaneous polylactic acid injection localizations were performed for five pulmonary nodules in five patients (2 men and 3 women; mean age, 59.8 years; range, 54–65 years). The injection was feasible in all patients and the localization effect was excellent. The total procedure duration was 12.6 minutes (range; 10–15) and the volume of polylactic acid injected was 0.38 mL. The wedge resections were easily and successfully performed in all five cases. The cutting margin was no less than 2 cm from the lesion. This technique is promising for the determination of GGO location in thoracoscopic surgery for wedge resection.

Localization of nonpalpable pulmonary nodules using CT-guided needle puncture

Background

Surgical resection of small pulmonary nodule is challenging via thoracoscopic procedure. We describe our experience of computed tomography (CT)-guided needle puncture localization of indeterminate pulmonary nodules prior to video-assisted thoracoscopic surgery (VATS).

Methods

From January 2011 to July 2014, 78 consecutive patients underwent CT-guided marking for the localization of 91 small pulmonary nodules. We retrospectively reviewed the clinical data, technical details, surgical findings and pathologic results, and complications associated with CT-guided localization.

Results

Seventy-eight consecutive patients (36 men and 42 women) underwent CT-guided marking localization of 91 indeterminate pulmonary nodules (62 pure ground-glass opacity nodules, 27 part-solid nodules, and 2 solid nodules). The mean size of the nodules was 8.6 mm (3.0–23.0 mm). The mean pleural distance between the nodule and lung surface was 11.5 mm (3.0–31.3 mm). The mean procedure time of CT-guided localization was 15.2 min (8–42 min). All patients stood the procedures well without requiring conversion to open thoracotomy. Twenty-four patients (30.77 %) developed pneumothorax after the procedures. Only one patient required retention of the puncture needle introducer for air drainage. The mean visual assessment pain score was 1.7 (0–3). Fifty-seven nodules (62.63 %) were confirmed as malignances, including 45 primary lung cancer, and 34 nodules (37.37 %) were confirmed as benign lesions.

Conclusions

CT-guided needle puncture can be an effective and safe procedure prior to VATS, enabling accurate resection and diagnosis of small pulmonary nodules.