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Radiofrequency Ablation of 40 Lung Neoplasms: Preliminary Results

¹ Unità Operativa di Radiologia Interventistica, Istituto di Ricovero e Cura a Carattere Scientifico (IRCCS) Oncologico, Via Amendola 209, Bari 70126, Italy.
² Dipartimento di Area Critica e Quartiere Operatorio, IRCCS Oncologico, Bari 70126, Italy.
³ Dipartimento di Oncologia, IRCCS Oncologico, Bari 70126, Italy.
⁴ Unità Operativa di Radiologia, IRCCS Oncologico, Bari 70126, Italy.
⁵ Unità Operativa di Radioterapia, IRCCS Oncologico, Bari 70126, Italy.
⁶ Unità Operativa di Oncologia, Ospedale Generale S. Giuseppe, Via Paladini 40, 50053 Empoli (Firenze), Italy.
⁷ Direzione Scientifica, IRCCS Oncologico, Bari 70126, Italy.

Received September 18, 2003; accepted after revision February 13, 2004.

 
Presented at 2003 meeting of the American Roentgen Ray Society, San Diego, CA.

Address correspondence to C. Gadaleta.

Abstract

Top Abstract Introduction Subjects and Methods Results Discussion References

 
OBJECTIVE. Radiofrequency thermal ablation is a minimally invasive treatment widely used for treatment of liver neoplasms and has also been tested on other types of tumor. Few studies have been published regarding the use of radiofrequency thermal ablation in the treatment of lung neoplasms. This study was performed to evaluate the technical feasibility, the safety, and the efficacy of lung radiofrequency thermal ablation.

SUBJECTS AND METHODS. Between February 2002 and March 2003, 18 subjects with unresectable lung neoplasms, four of whom had primary neoplasms and 14 of whom had metastatic neoplasms, underwent lung radiofrequency ablation. The technique was performed percutaneously using a monopolar cooled-tip electrode needle under CT guidance with the patient under general anesthesia. Patients had no more than three nodules with a total diameter of 10 cm and no evidence of extrathoracic disease. A total of 40 nodules were treated in 24 therapeutic sessions. After treatment, patients underwent follow-up every 3 months by CT and nuclear MRI with gadolinium for a median time of 8 months (range, 2–14 months).

RESULTS. No evidence of local relapse was discovered in 94.4% of subjects. The treatment was safe and well tolerated. Complications encountered included massive pneumothorax, which occurred in one subject, requiring pleural drainage. Other complications were moderate pneumothorax (also requiring pleural drainage), cough, fever, slight dyspnea, and pain, but these complications were short in duration and successfully treated.

CONCLUSION. Radiofrequency thermal ablation is a promising technique in the treatment of patients with lung neoplasms and has been found to be both safe and technically feasible.

Introduction

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Radiofrequency thermal ablation is a new imaging-guided technique offered as a minimally invasive treatment that is most commonly used for treatment of patients with liver tumors [1–11]; however, this treatment has also been recently tested in patients with various other neoplasms such as kidney [12], spleen [13], prostate [14], breast [15], and lung cancer [16–18]. The procedure is safe, technically feasible, and suitable for use with imaging guidance technologies.

The predominant mechanism of action of radiofrequency ablation is thermal injury. A high-frequency alternating current emitted from the exposed noninsulated portion of the electrode generates frictional heat, agitating ions in the tissue surrounding the tip of the needle. The heat causes coagulative necrosis, driving extracellular and intracellular water out of the tissue, thereby denaturing proteins [19–21]. These effects are achieved in a predictable manner at predictable temperatures and in a relatively predictable volume [22]. Histopathologic findings have been evaluated both in animal models [23] and in human specimens [24] and reveal well-defined areas of tumor necrosis. Lung tumors seem well suited to radiofrequency ablation because the surrounding air in adjacent normal lung parenchyma provides an insulating effect that seems to concentrate radiofrequency energy [25]. Moreover, CT allows accurate localization of the electrode needle, facilitating optimal treatment of the neoplasm. Other advantages of using radiofrequency ablation include the ability to administer treatment percutaneously as well as a short hospital stay for the patient, which tends to have a favorable impact on the patient's quality of life.

The aim of this study was to assess the safety and technical feasibility of lung radiofrequency ablation in patients with primary and secondary unresectable lung tumors. A secondary objective was to determine the efficacy of treatment.

Subjects and Methods

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Subjects
This study was performed at the Istituto di Ricovero e Cura a Carattere Scientifico in Bari, Italy, with approval from its institutional ethics committee. Written informed consent was obtained from all subjects. Eligibility criteria were unresectable primary non–small cell lung cancer or lung metastases from various solid tumors (subjects with mediastinal nodal involvement were scheduled for subsequent radiotherapy); an age of between 18 and 80 years; a performance status score, according to the Eastern Cooperative Oncology Group, of 0–1; histopathologic proof of malignancy; American Society of Anesthesiology classification between I and III; normal coagulation test results; a platelet count of not less than 50 x 10³/mm³; and no more than three lesions with a total diameter of 10 cm or less (with the exception of the first subject who had an 11-cm lesion). The decision to limit tumor size to 10 cm was reached after treating the first patient. Exclusion criteria were as follows: disease infiltrating the wall of the bronchi, major vessels, or mediastinal interstitial tissue; neoplastic or massive or moderate pleural effusion; the presence of extrathoracic neoplastic disease; and suppurative neoplasms. Patients were considered ineligible for surgery because of technical considerations, comorbidity, poor cardiorespiratory reserve, and refusal.

Between February 2002 and March 2003, 18 consecutive patients (11 men and seven women) were enrolled in this study, and a total of 40 lung neoplastic lesions were treated with percutaneous radiofrequency thermal ablation. The median age was 69 years (range, 26–80 years). Four subjects were treated for primary neoplasms, and 14 subjects were treated for metastatic lesions. Ten subjects had single nodules. Eight subjects had multiple nodules; however, one of these eight subjects was treated for a single nodule and the other nodules had previously received another form of treatment. The median number of treated lesions per patient was one (range, 1–7). The median nodule size was 3 cm, with a range of 0.6 to 11 cm. All subjects received prior systemic chemotherapy. In addition, three subjects were previously treated with surgical pulmonary resection. Four subjects underwent two radiofrequency ablation sessions, and one subject underwent three radiofrequency ablation sessions after having developed subsequent nodules.

Two subjects with non–small cell lung cancer were ineligible for the study because they refused surgery, and another two were ineligible because of comorbidity. Fourteen subjects with metastatic lung disease were considered ineligible for surgery: 11 refused surgery, and the other three were ineligible because of technical, anatomic, or functional contraindicating conditions. In total, 13 patients had potentially resectable neoplasms, but they refused to undergo surgery and five patients did not undergo surgery because of technical, anatomic, or functional contraindications.

The diagnostic workup before the treatment included CT scans of the brain, thorax, and abdomen; skeletal radiographs (including skull, vertebral column, pelvis, femur, and humerus); and anesthesiology examination. Lesions were subclassified by site. Paramediastinal lesions were those in contact with mediastinal structures (without infiltration) or those that were less than 1 cm from mediastinal structures, including fibrous pericardium, major vessels, cardiac pedicle, trachea, and bronchi. Central parenchymal lesions were those that were fully surrounded by pulmonary parenchyma (aerated) or those that were more than 1 cm from the mediastinal structures and visceral pleura. Lesions considered to be subpleural were those in direct contact with the pleura (without infiltration) or those that were less than 1 cm from the pleura.

Radiofrequency Ablation Technique
After CT scan centering, radiofrequency ablation was performed percutaneously using a 17-gauge monopolar cooled electrode needle (Cooled-tip RF system, Radionics), with lengths ranging between 10 and 15 cm, depending on the depth of the lesion to be treated. The exposed part of the needle (i.e., the noninsulated portion) was between 1 and 3 cm. Selection of the exposed tip length of the needle was based on the diameter of the lesion—that is, the needle size was always greater than the area to be treated (e.g., a 7.0-mm lesion would require a 1-cm needle). The wattage–current setting is selected automatically by the system and is based on the amount of water in any specific tissue (i.e., the amount of free ions present). The system adjusts itself according to the level of resistance and impedance. A maximum treatment time of 12 min has been found to ensure complete necrotic coagulation of the tumor volume according to the corresponding diameter of the exposed part of the needle. The system alternates between "on" (active) and "off" (inactive) modes. Long periods (30–40 sec) of inactivity by the machine and short periods (5–7 sec) of activity (i.e., with readings by the system of > 100 ) indicate that the scheduled volume of the nodule has been ablated. Larger lesions (> 3 cm) are divided into sectors, and each sector is treated as if it were a 2-cm lesion, with the exposed part of the needle being 3 cm. The sectors overlap to ensure full ablation of the entire nodule. All lesions are treated in one session in the manner described. Both multiple lesions and large lesions can result during long treatment sessions however, and in both instances are treated in a single session. Grounding pads (22 x 19 cm) were placed in the lumbar or gluteal region, according to the position of the nodule to be treated. Nodules close to the apex of the lung required pads to be placed in the lumbar region, and nodules close to the base of the lung required pad placement in the gluteal region.

A single insertion was used for lesions with a diameter less than or equal to 2.8 cm, and treatment sessions lasted 12 min. All subjects were treated under general anesthesia. Premedication was administered using fentanyl, midazolam, and atropine. Propophol and succinylcholine were used to induce anesthesia, while fentanyl, propophol 20%, and cisatracurium besylate were used to maintain anesthesia. All subjects were intubated with a double-lumen tube and monitored with mechanical ventilation using fraction of inspired O₂ of 0.35–0.40. Continuous monitoring of heart rate, blood pressure (measured noninvasively with cuff), ECG, blood oxygen levels, blood carbon dioxide levels, saturated blood oxygen levels, and diuresis was performed during the procedure. A hemogasometric check was made before, during, and after treatment. Subjects were maintained in the prone position if the lesion was dorsal. If the lesion was anterior or lateral, the subject was maintained in the supine or lateral position, respectively.

A CT scan with contrast medium was obtained 48 hr before treatment to evaluate baseline enhancement of the tumor. Immediately before treatment, a thoracic CT scan without contrast medium was obtained with a collimation of 5 mm to select the optimal percutaneous access of the needle. A CT scan without contrast medium was also obtained every 3 min during treatment. Obtaining CT scans was considered necessary to detect possible acute complications, such as massive pneumothorax and hemorrhage, in a timely manner. Because a CT scan is not a real-time technology, we believe the 3-min intervals to be sufficient to detect and manage complications. CT scans also allowed monitoring of structural changes induced by treatment. In addition, because making small corrections in the position of the needle during this procedure is often necessary as a result of the morphology and volume of the lesion, CT provides the ability to monitor even the smallest repositioning of the needle.

Immediately after the removal of the endotracheal tube, an additional unenhanced CT scan was obtained of all subjects while in the supine position. Chest radiographs to detect and monitor pneumothorax and other complications were obtained 2 hr after treatment and daily until discharge of the subject from the hospital. All subjects received antibiotic prophylaxis with parenteral cephalosporin immediately before the procedure and for 6 days thereafter.

Assessment of Treatment Efficacy
All subjects underwent CT with contrast medium 48 hr after treatment, followed by CT 30 days later. In addition, eight (44.4%) of 18 subjects were also administered gadolinium for MRI. CT and MRI were performed on average every 3 months after treatment.

The efficacy of treatment was assessed according to the presence or absence of enhancement. The presence of cavitation may be used as an additional marker of treatment efficacy.

Results

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Radiofrequency Ablation Technique
A total of 24 radiofrequency ablation sessions were carried out, and 40 neoplasms were treated with a total of 65 insertions.

Impedance values ranged between 75 and 140 ; values in the range of 100–140 were found in five cases in which the electrode needle was partially outside the lesion and inside the aerated parenchyma. The internal temperature, close to the electrode needle, ranged between 45°C and 75°C. Temperatures not greater than 58°C were sometimes recorded during successive insertions of the electrode needle into large lesions, which are treated in partially overlapping sectors to allow complete ablation of the full volume of the tumor. Nevertheless, in all cases the temperature was never less than 45°C. The power generated during the procedure was between 85 and 140 W. Values between 85 and 90 W were observed in six instances while treating nodules smaller than 3 cm, during which times the electrode needle was partially outside the lesion. These instances seemed to be inversely correlated to impedance.

Subjects
The median hospitalization time after treatment was 6 days (range, 3–13 days), whereas median follow-up time was 8 months (range, 2–14 months). Relapsed disease in the treated area was observed in one case (5.6%) and was seen in six subjects (33.3%) at distant sites. Seventeen (94.4%) of 18 patients are alive, 12 of them without evidence of disease.

The side effects for 24 sessions of treatment are summarized in Table 1. Moderate-grade fever (< 38.5°C), requiring antipyretic medication, occurred during 11 sessions of treatment and usually resolved within a few days. Cough with rust-colored spitting occurred in seven sessions, lasting 48–72 hr. In nine sessions, patients complained of slight thoracic pain and were treated with nonsteroidal antiinflammatory medication. Minimal pleural asymptomatic effusion occurred in seven sessions; it resolved spontaneously. Slight and transient dyspnea was observed in three sessions.

Pneumothorax requiring pleural drainage occurred in three sessions, involving more than 30% of the ventilated volume of the treated lung in one case and more than 10% but less than 30% in the other two cases. After the first insertion of the electrode needle, (Cooled-tip RF system), two subjects—those with monolateral pneumothorax involving ventilation volumes of greater than 10% but less than 30%—required pleural drainage. The chest tube was removed without further complication after 5 and 7 days, respectively, when the pneumothorax was corrected. In the third patient with a reduction of ventilation volume greater than 30%, pneumothorax was observed 48 hr after the procedure. The subject became symptomatic with mild subcutaneous interstitial emphysema 72 hr later and required pleural drainage for 10 days. Two months later, this subject exhibited disease progression with extensive pleural infiltration that was not previously visible on CT, leading to an unfavorable outcome, accompanied by cachexia and diminished respiratory function. No other complications, such as hemorrhages, bronchopulmonary fistulas, arteriovenous fistulas, or lung abscesses were observed, nor were there any treatment-related deaths, and no subjects suffered neurologic sequelae after the radiofrequency ablation procedure.

Radiologic Imaging
Figure 1A shows a primary lung carcinoma before radiofrequency thermal ablation.

View larger version (101K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1A. —79-year-old man with primary lung carcinoma. CT scan obtained immediately before radiofrequency ablation shows neoplasm (white arrows) with diameter of 3 cm that is located in posterior segment of superior right pulmonary lobe at subapical site. Black arrow indicates tip of electrode needle inserted into dorsal chest wall, immediately before crossing parietal pleura.

Between the first 3 and 12 min of treatment, the appearance of the lesions on CT was as follows: wrinkling of the edges; partial emptying, likely due to vaporization of tissue; and unchanged diameter (Fig. 1B). Multiple concentric rings with varying densitometric characteristics appeared in the pulmonary parenchyma around the lesion immediately after treatment. These concentric rings resembled a cockade, which is a particular sort of bow made from ribbon, historically worn on berets (Figs. 1C and 1D). We have thus coined the term "cockade phenomenon." In all cases, the cockade phenomenon was most evident 48–72 hr after treatment.

View larger version (101K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1B. —79-year-old man with primary lung carcinoma. CT scan obtained during radiofrequency ablation shows wrinkling of edges of lesion; partial emptying, which is likely due to vaporization of tissue; and unchanged diameter.

View larger version (112K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1C. —79-year-old man with primary lung carcinoma. CT scans obtained without contrast enhancement immediately after procedure using parenchymal (C) and mediastinal (D) window settings show thermalablated lesion (single arrow). Double arrows indicate parenchymal tissue around nodule, which is slightly hyperdense with granular appearance; triple arrows indicate vascular hyperdense parenchymal tissue forming envelope around previously described areas.

View larger version (109K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1D. —79-year-old man with primary lung carcinoma. CT scans obtained without contrast enhancement immediately after procedure using parenchymal (C) and mediastinal (D) window settings show thermalablated lesion (single arrow). Double arrows indicate parenchymal tissue around nodule, which is slightly hyperdense with granular appearance; triple arrows indicate vascular hyperdense parenchymal tissue forming envelope around previously described areas.

Additional effects of treatment included a clear sectorial hyperemia surrounding the lesion, conical with the apex at the hilus. This effect lasted 24–72 hr (Fig. 1E). Pleural effusion reached a maximum level between 24 and 48 hr after radiofrequency ablation and resolved itself in a few days.

View larger version (100K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1E. —79-year-old man with primary lung carcinoma. CT scan obtained at end of thermal ablation procedure shows electrode needle (black arrow). White arrows indicate sectorial hyperemia surrounding lesion, conical in shape with apex at hilus.

CT scans obtained before radiofrequency ablation revealed a typical contrast-enhanced image of a malignant neoplasm (Fig. 2A). Immediately after radiofrequency ablation, CT scans showed the following peculiar aspects: persistent cockade phenomenon, clearly visible (Fig. 2B); persistent coneshaped sectorial hyperemia; and moderate pleural effusion.

View larger version (119K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2A. —74-year-old woman with lung metastases from colorectal carcinoma. High-resolution CT scan obtained before radiofrequency ablation shows neoplasm (arrow) with diameter of 1.8 cm located medially in posterior segment of right superior pulmonary lobe.

View larger version (147K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2B. —74-year-old woman with lung metastases from colorectal carcinoma. CT scan obtained 30 min after radiofrequency ablation shows metastatic lung lesions with clear "cockade phenomenon." Thin single arrow indicates treated nodule; double arrows indicate perilesional parenchymal tissue; triple arrows indicate inflamed, hyperemic, hyperdense parenchymal ring; thick arrow indicates minimal pneumothorax. We regard these radiologic finds to be in accordance with histologic descriptions reported by Miao et al. [29].

CT scans obtained after 30 days and all successive CT scans revealed progressively less and less definition, fading over time, of the lesion, and ultimately a core of hyperdense scar tissue surrounded by a thin hyperdense ring with a distance from the nucleus that was inversely correlated to the size of the nodule. The treated nodules appeared enlarged, most likely because of central necrosis and cavitation surrounded by reparative fibrosis, without contrast enhancement (Figs. 2C and 2D).

View larger version (112K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2C. —74-year-old woman with lung metastases from colorectal carcinoma. CT scan shows needle inside tumor during radiofrequency ablation. Neoplasm is located laterally to posterior venous branches (arrows) of posterior segment of superior right pulmonary lobe. Note that more dorsal branch is laterally in contact with lesion and medially in contact with posterior bronchial branch of superior right pulmonary lobe.

View larger version (127K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2D. —74-year-old woman with lung metastases from colorectal carcinoma. CT scan obtained 1 month after radiofrequency ablation shows tumoral lesion to be fully cavitated with reparative hyperemic hyperdense envelope. Areas labeled 1 and 2 were printed during CT process and refer to attenuation. Area 1 indicates the cavitated area with a densitometric value of–886 H. Area 2 indicates surrounding hyperdense ring with a densitometric value of 33 H. Note that envelope encompasses more dorsal branch of right superior pulmonary vein (arrow), which is partially surrounded by necrotic tissue originating from fragmentation of treated nodule.

Only one subject, who was affected by non–small cell lung cancer with a maximum diameter of 7 cm, showed contrast enhancement in a small peripheral area 2 months after radiofrequency ablation. A fine-needle aspiration biopsy was performed under CT guidance that revealed tumoral relapse.

Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Radiofrequency thermal ablation is an interesting technique that is emerging as a possible alternative to surgery as a minimally invasive treatment of various solid neoplasms [1–15]. Although the procedure is considered safe and effective and is widely used to treat patients with liver neoplasms, few studies have reported results with regard to the use of radiofrequency ablation therapy for the treatment of humans with lung tumors [16–18, 26].

Surgery is considered to be the standard treatment for patients with localized primary lung cancer and metastatic resectable lesions, although only a small percentage of patients are candidates for surgery because of comorbidity, poor cardiorespiratory reserve, and technical contraindications. Therefore, the use of a minimally invasive procedure such as radiofrequency ablation is attractive, especially when considering the generally poor outcome of these patients when being treated with systemic chemotherapy and radiotherapy.

In this study, the 18 treated subjects showed a strong willingness to receive radiofrequency ablation therapy. Pneumothorax requiring pleural drainage occurred in only three sessions (12.5%) and was effectively treated in each case, along with the other side effects of treatment. This procedure, performed with a monopolar electrode needle under CT guidance and the patient under general anesthesia, was found to be safe and technically feasible. This assessment takes into account the potential risk for cerebrovascular accident due to microbubble passage into the pulmonary veins [27].

General anesthesia was deemed necessary for both medical and radiologic reasons. With regard to medical considerations, general anesthesia provides the ability to control airway passages in the event of a massive pneumothorax or serious intraparenchymal hemorrhage. It also provides the ability to improve the ventilation–perfusion rate in the event of serious concomitant bronchopulmonary insufficiency and due to physiologic changes during treatment secondary to the lateral positioning of the subject. The use of general anesthesia also ensures the complete immobilization of the subject, which contributes to making the technique as minimally invasive as possible because abrupt, unintentional movements of the body or respiratory movements can be avoided. Moreover, intubation with a doublelumen tube allows the management of a possible massive and monolateral pneumothorax while allowing ventilation of the other lung. This capability is especially useful in patients with severe obstructive chronic bronchial disease and even more so in cases of massive hemorrhage [16, 18, 26, 28].

Radiologic motives for using general anesthesia include the assurance of a correspondence between the thoracic CT scans and each superficial section of the nodule being treated being obtained as a result of the patient's immobility and avoiding the need to obtain repeated CT scans in the event that the patient had moved in some way or in cases in which there are multiple or large lesions. In addition, performing radiofrequency ablation on a small nodule (e.g., 1 cm) in the lower portion of the lung would be impossible to center with the patient breathing normally. The use of a double-lumen tube makes it possible to block ventilation of the lung being treated using just enough O₂ to keep it inflated by continuous positive airway pressure (5–10 cm H₂O) while ventilating the other lung, thereby allowing accurate centering of the needle.

Most subjects were completely autonomous within 12 hr of treatment. The median hospitalization time was influenced by factors such as the experimental nature of the study as well as continued monitoring and observation of subjects after treatment in the absence of complications and in three cases in which three subjects required pleural drainage secondary to development of pneumothorax. With respect to our discussion of the cockade phenomenon in the Results section of this article, our description correlates well with the results reported by Miao et al. [29] in an article highlighting typical MR images of lung neoplasms in rabbits treated with radiofrequency ablation. The authors believe that the cockade phenomenon could reflect similar histopathologic changes (Figs. 3A and 3B) with concentric layers of varying thicknesses, which they attribute to thermal gradients between the tumoral nodule and the surrounding parenchyma. Radiofrequency ablation of a tumor results in an area at the periphery of the ablated tumor that is in contact with necrotized healthy tissue, thereby creating an area that reduces the risk of local recurrence of the disease. This area is referred to as the "safety zone." The thickness of the safety zone is inversely correlated to the diameter of the tumor. Small lesions have a more extensive peripheral safety zone because of a higher thermal gradient. In large lesions, heat loss occurs easily because the greater the distance from the center of the nodule, the greater the occurrence of heat loss, resulting in a smaller peripheral safety zone. Generally, scar tissue forms at the periphery of the nodule where microhemorrhages and hyperemic rings are found and surrounds the necrotic area to form widespread air pockets in nodules smaller than 2 cm. In these smaller lesions, the formation of these empty spaces often resulted in the fragmentation of the nodule and the fragments migrating toward the periphery and attaching themselves to the scar-tissue fibers (Fig. 2E).

View larger version (11K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3A. —Diagrams of lung neoplasm before and after radiofrequency ablation. Diagram shows lung neoplasm before treatment.

View larger version (33K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3B. —Diagrams of lung neoplasm before and after radiofrequency ablation. Diagram shows same tumoral lung lesion after radiofrequency ablation. Area of enzymatic necrosis with partially destroyed capillaries, microthrombosis, and lysosomal enzyme activation is labeled D. Peripheral ring of this area (D1) appears to express presence of microhemorrhagic border mixed with outermost layer (E), with edema, inflammatory reaction, and vascular congestion. A = central area intersected by electrode needle; B = partial emptying (dark), likely due to vaporization of lesion, and coagulative necrotic area with destroyed capillaries and "ghost phenomenon" (term used by Miao et al. [29] to describe seemingly intact tissue after sudden thermal coagulation); C = coagulative necrotic area surrounding nodule and containing collapsed alveoli with entrapped air and ghost phenomenon.

View larger version (124K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2E. —74-year-old woman with lung metastases from colorectal carcinoma. MR image obtained with gadolinium 2 months after radiofrequency ablation shows cavitated area appears moderately enlarged; surrounding envelope has less thickness; and necrotic fragments of treated lesion, which adhere to very hyperintense internal surface, are unenhanced. Note that envelope includes more dorsal branch of right superior pulmonary vein (arrow), which is partially surrounded by necrotic fragment of treated lesion. See Miao et al. [29].

In this study, only one patient with a diagnosis of primary non–small cell lung cancer, with a diameter of 7 cm, presented with relapsed disease visible on CT and MRI at the periphery of the treated lesion (Fig. 4A). Three months after the first treatment, the subject underwent a second radiofrequency ablation treatment to completely eradicate the lung neoplasm. Five months after the second procedure, the subject is alive with no evidence of disease shown on MRI with gadolinium (Fig. 4B). Despite the short followup, these data suggest that radiofrequency ablation is an efficient treatment for lung neoplasms with a low percentage of local relapse (1/40 [2.5%] treated nodules). Four subjects with relapse at pulmonary sites distant from the initially treated lesions were referred for an additional therapeutic session.

View larger version (169K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4A. —69-year-old man with primary lung carcinoma. MR image obtained after marginal relapse 2 months after first treatment shows large hypointense necrotic nodule is surrounded by thin, hyperintense fibrous scar. In peripheral dorsal sector markedly hyperintense tissue (arrow), representing tumoral relapse, is visible.

View larger version (174K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4B. —69-year-old man with primary lung carcinoma. MR image obtained at 5-month check-up after second treatment shows entire hypointense volume of tumor (single arrow), including treated area of relapse. Entire lesion is surrounded by thin hyperintense fibrous scar that has posterior contact with cardiovascular structures. Double arrows point to left inferior pulmonary veins that empty into left atrium.

Notwithstanding the theoretic considerations regarding the capability of the cooledtip electrode needle to encompass the entire tumoral lesion and safety margin, we deem radiofrequency ablation useful in treating nodules larger than 3.5 cm in diameter with adjunctive radiotherapy, when possible, to reduce the risk of recurrent disease at the peripheral areas of ablated neoplasms.

As previously described in the treatment of liver neoplasms [30], histopathologic findings seem well correlated to radiologic imaging [29]. Therefore, CT and MRI could be useful in making it easier to assess the efficacy of treatment [29–32].

In this study, four (22.2%) of 18 patients had paramediastinal lesions close to the hilus, pericardium, proximal bronchi, and major vessels without infiltration of these structures. Nevertheless, the treatment was performed without technical problems or complications, thus confirming its feasibility in such cases.

We wish to emphasize the safety of lung radiofrequency ablation. It is a conservative, minimally invasive treatment that can be administered multiple times; it could be effective especially in patients not eligible for surgery or with slow-growing lesions. In addition, the promising results obtained in treating small lesions warrant investigation of this technique in patients with resectable lung neoplasms. In conclusion, lung radiofrequency ablation has been found to be an interesting technique that could play a role in a multidisciplinary approach to primary and secondary lung tumors. We strongly suggest that further investigation with larger and randomized studies is performed to assess the optimal combination of radiofrequency ablation with other antitumoral treatments and to better identify patients who could benefit from this therapeutic option.

Acknowledgments
 
We thank Giuseppe Laricchia, Vito Cilifrese, Teresa Lionetti, and Vincenzo Colaluce for their technical expertise in the realization of this study. We also thank Michael Kolk for his help in the preparation of this manuscript.

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