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Ann Thorac Surg 2007;83:1978-1984
© 2007 The Society of Thoracic Surgeons

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Original Articles: General Thoracic

Transxiphoid Hand-Assisted Videothoracoscopic Surgery

Thoracic Surgery Division, Policlinico Tor Vergata University, Rome, Italy

Accepted for publication February 7, 2007.

^_* Address correspondence to Dr Mineo, Cattedra di Chirurgia Toracica, Policlinico Tor Vergata, Viale Oxford 81, Rome, 00133, Italy (Email: mineo{at}med.uniroma2.it).

	Abstract

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Background: We have performed transxiphoid hand-assisted videothoracoscopy since 1995 to allow manual palpation in bilateral lung metastasectomy. This approach was extended to other thoracoscopic procedures requiring a handport. No extensive report about early and late results has yet been published.

Methods: We retrospectively reviewed the first 100 consecutive patients undergoing transxiphoid hand-assisted videothoracoscopy. Acute and chronic postoperative pain, respiratory function, patient’s satisfaction score (1 to 5), quality of life (Short Form-36), and survival rate were evaluated.

Results: Seventy-four patients had lung metastases, 5 had primary lung cancers, 16 had benign nodules, and 5 had Morgani’s hernia. Five patients needed conversion to thoracotomy, whereas 7 successfully underwent a second transxiphoid operation. Sixty-five metastatic patients were bilaterally explored, 44 were without radiologic evidence of controlateral lesions, discovering 23 occult metastases and 10 patients with occult controlateral disease. A total of 207 minimal resections and 11 lobectomies were performed. Mean operative time was 103 ± 35 minutes. We had no intraoperative mortality or major complications. Thirty-day postoperative morbidity documented arrhythmia (n = 4) and acute pneumonia (n = 4). Visual Analogue Scale pain, C-reactive protein, fibrinogen, and serum interleukin-6, -8, and -10 normalized within 72 hours. Respiratory function and most of the Short Form-36 domains recovered within 3 months. Six-month mean patient satisfaction score was 4.0 ± 0.8. Three- and 5-year survival rates for metastatic patients were 52% and 43%, respectively. Mean disease-free interval was 12 ± 5.8 months.

Conclusions: Transxiphoid hand-assisted videothoracoscopy proved a good alternative to conventional approaches, and provided rapid recovery without affecting the survival rate in those patients with metastatic lesions. We recommend it whenever a handport during video-assisted procedure is required.

	Introduction

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Video-assisted thoracic surgery (VATS) was perceived to be less invasive than the conventional open thoracotomy with respect to less pain, better preservation of pulmonary function, and less impairment of the shoulder girdle [1–3]. Minimal resection by the VATS approach is a widespread and accepted therapeutic method for treating small peripheral lung lesions [4, 5]. Nevertheless, having one hand inside the chest may simplify the identification of subcentimetric nodules detected by spiral computed tomography (CT) scan, facilitate the resection for nodules sited in posterior segments of the lung, and permit the exploration of the controlateral hemithorax [6].

Transxiphoid hand-assisted videothoracoscopy was developed to face these obstacles without increasing operative morbidity [7]. This incision was useful for bilateral approaches during the same operation, required by the metastatic nature of the disease. We also found the access useful to facilitate video-assisted procedures such as resection of deeply located nodules, lower lobectomies, and Morgagni’s hernia repair. Our experience has now reached 100 patients and a significant follow-up is available. The purpose of this study was to analyze the short- and long-term results of using this approach.

	Patients and Methods

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We retrospectively reviewed our experience with the first 100 consecutive patients who underwent transxiphoid hand-assisted videothoracoscopy in our division. Early and long-term postoperative results were collected from clinical reports or during outpatient clinics. The study was approved by the Ethics Committee of our University. Patient’s permission for use of personal data was asked and obtained.

Indication for the Procedure
Since 1995, when we first introduced this approach for pulmonary metastases, we limited its use to some selected conditions. Complete control of the primary tumor and absent or resectable extrapulmonary metastases were considered the two mandatory prerequisites. Furthermore, we excluded patients with metastases at more than 2 cm from the visceral pleura at the CT, or greater than 3 cm or anyway requiring lobectomy, or with a history of pleuritis or pleurodesis, or in the presence of cardiomegaly or arrhythmia. Nevertheless, through the transxiphoid approach, we performed controlateral manual palpation even in the case of negative imaging. Neither previous thoracic nor abdominal surgery represented absolute contraindication to this operation in itself. Four patients had a previous VATS for metastasectomy; another 4 had an abdominal operation through a subcostal access, and transxiphoid incision was made along the middle trait of this scar. Finally, in 7 patients, we performed a successful redo transxiphoid operation.

Following the same technique, we developed a new approach for resection of pulmonary and hepatic metastasis, combining the subcostal transverse laparotomy with the transxiphoid hand-assisted approach. Thereafter, we extended this approach to facilitate video-assisted procedures such as lobectomy or resection of nodules difficult to localize by instrumental palpation. In addition, we found it very useful in surgery of the anterior leaflet of the diaphragm such as Morgagni’s hernia repair.

Preoperative Studies
After the discovery of lung metastases, all patients underwent further examination (total body CT scan, ultrasonography, bone scan) to exclude primary tumor recurrence or extrapulmonary relapse. The lung lesions were also restaged immediately before planned surgery by means of a helical chest CT scan (Tomoscan SR 7000; Philips Medical Systems, Eindhoven, Netherlands, and more recently, LightSpeed¹⁶ scanner; General Electric Medical Systems, Milwaukee, Wisconsin) without intravenous contrast medium. This also allowed determination of the stability of pulmonary lesions. The mean interval between helical CT scan and surgical exploration was 8 days (range, 4 to 15).

Operative Details
Transxiphoid hand-assisted videothoracoscopy technique has been described elsewhere [7], and the main steps of the procedure are reported in Table 1 and and shown in Figure 1. General anesthesia was always induced with a double-lumen endotracheal tube. Exploration started from the side deemed more technically demanding, either because of the greater number of lesions or a more difficult resection. The entire lung, both partially inflated or totally deflated, was carefully palpated between thumb and forefinger according to a precise sequence regardless of radiologic findings and thoracoscopic appearance. Thereafter, all areas predicted by helical CT to be site of metastases were specifically explored until the predicted lesions could be identified and evaluated for resection. All palpated nodules were excised with minimal resection by an endoscopic stapler or laser beam, taking care to spare the surrounding healthy parenchyma. After the resection, the lung was manually reinflated until visible collapse had disappeared.

View larger version (27K): [in this window] [in a new window]   Fig 1. Position of the patient and setup of surgical approach.

Postoperative Treatment
All patients were extubated in the operatory room. Epidural anesthesia (fentanyl and bupivacaine) administered for the first 48 hours after surgery was used until 1999. Thereafter, postoperative pain was treated only by tramadole 300 mg and ketorolac 90 mg in continuous intravenous infusion until chest tube removal.

Acute Pain Evaluation
Evaluation of acute postoperative pain was assessed using the Visual Analogue Scale (VAS) that graded from 0 (no pain) to 10 (most severe imaginable pain) as an index of the patient’s perception of pain [8]. The VAS was explained to patients preoperatively and consisted of patients marking a grade of pain on a graded ruler. Pain was quantified both at basal level and when provoked by particular movements. Assessments were made twice daily for the first 2 days, then once daily until the discharge.

Acute Pain Stress Markers
It is known that elective thoracic surgery provokes an increase in acute pain stress serum markers such as C-reactive protein, fibrinogen, white blood cell count, and interleukin-6, -8, and -10 using comercially available assays. The magnitude of the elevation is related directly to the degree of tissue injury [9]. Blood samples were drawn preoperatively, at the end of the procedure, and every 12 hours postoperatively for the first 48 hours, centrifuged at 3,000g for 5 minutes, and then stored in deep refrigeration at –70°C until serum measurements were performed.

Patient Satisfaction
Patient satisfaction with the operation was assessed 6 months later by asking the patient to choose one of the five possible responses: poor, fair, good, very good, or excellent, assigning them a point score from 1 to 5.

Quality of Life Evaluation
We used the Medical Outcomes Study Short-Form 36-Item Questionnaire (SF-36) [10], which consists of 36 multiple-choice questions that cover eight health concepts: physical functioning, social functioning, physical role, emotional role, vitality, body pain, mental health, and general health perception (best score = 100, worst = 0). To simplify the evaluation, the Physical and Mental Component Summary (Health Assessment Lab, New England Medical Center, Boston, Massachusetts,1994) was also used. We chose this questionnaire because of its relative simplicity, wide use in chronic pulmonary diseases, specific presence of body pain domain, and availability of a validated version for the Italian population [11]. The questionnaire was administrated preoperatively and at 1 month and 6 months after the operation. Further evaluations were not included in the present study, as the natural history of patients’ disease greatly affects their quality of life.

Follow-Up
Follow-up included clinical visit, timed spirometry, serum biochemical, and chest radiography to be performed every 6 months (every 3 months for the neoplastic patients) for the first 2 years and thereafter once per year. Total body CT scan was done twice per year for the first 2 years and then yearly. For neoplastic patients, functional assessment (ie, electrocardiogram, clearance creatinine, blood urea nitrogen, bilirubin, and liver enzymes) was repeated before each chemotherapic cycle.

Statistical Analysis
Data were expressed throughout as mean ± SD. Postoperative changes were assessed by the Student t test. All tests were two-tailed with a significant level of 0.05. Overall survival and disease-free survival curves were estimated using the Kaplan-Meier method, and the significance test was based on the log-rank test as given by Mantel. The survival time was counted from the day of surgery. Recurrence was considered any new neoplastic lesion, second primaries included. All causes of death were treated as final events.

	Results

Top Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
Early Results
General details of the operated patients are summarized in Table 2. Seventy-four patients had lung metastases, 13 of whom had simultaneous liver metastasectomy through the same access. Four patients had already undergone a previous thoracic procedure in other institutions. Bilateral transxiphoid exploration was performed in a total of 65 patients, 44 without CT evidence of controlateral lesions. In 6 patients with CT evidence of unilateral disease, contralateral palpation was impossible for the presence of tenacious adherences.

Table 2 shows operative and postoperative results. Mean operative time was 103 ± 35 minutes, decreasing from a mean time of 138 minutes at the beginning of our experience to 91 minutes in the last patients (p < 0.01). A total of 207 minimal resections and 11 lobectomies were performed in 102 operations.

We converted the procedure to open lateral thoracotomy in 5 instances: 4 on the left and 1 on the right. In 2 cases, there were two primary lung cancers requiring lobectomy in which we found the hilar dissection difficult. In the other 3 cases, we performed a rib-spreading minithoracotomy of 6 to 8 cm through which it was possible to better circumscribe the lesion and separate it from adjacent major vessels; this was necessary owing to the presence of deeply located metastasis. This incision was usually accomplished by prolonging a trocar port.

In the metastatic patients subset, we performed a total of 189 minimal resections and 8 lobectomies, removing a total of 211 lesions: 87 were located in the upper lobes (45 right, 42 left), 97 were found in the lower lobes (46 right, 51 left), and 27 were detected in the middle lobe. The maximum number of resected nodules per patient was 10. One hundred and seventy-eight lesions were identified as metastasis at histologic examination. Twenty-three CT-documented occult metastases were discovered in 18 patients, and controlateral occult disease in 10. The size of occult lesions ranged between 3 and 12 mm (mean, 6.7 ± 2.8 mm). There were 33 benign nodules with a mean diameter of 7.5 ± 4.4 mm, 25 of which had been judged metastasis by the imaging studies. Seven nodules diagnosed using the CT scan were not detected at palpation, and they were interpreted as small blood vessels.

We did not report intraoperative mortality. Mild and transitory hypotension or arrhythmia from right ventricle compression could be avoided by raising the sternum. Neither substernal bleeding nor phrenic nerve palsy were recorded. Intraoperative cardiac arrhythmia was experienced in 15.4% of the right and 34.5% of the left approaches. We were never compelled to stop the operation or defibrillate the patient. Eight patients presented with a significant morbidity: atrial fibrillation (n = 4) and acute pneumonia (n = 4).

After the expected increment, 24 hours postoperatively, all acute pain variables presented a significant decrement at 48 hours and a return to basal value after 96 hours (Table 3) in almost all measures. Figure 2 documents the timed variations of the three interleukins, showing a normalization after 72 hours.

View larger version (11K): [in this window] [in a new window]   Fig 2. Interleukin (IL) changes in the first 72 hours after surgery. Intragroup significance: ***p 0.001; **p 0.01; *p 0.05. (Bars = standard error of the mean; dotted line = IL-6; dashed line = IL-8; solid line = IL-10.)

Despite parenchyma loss, changes of forced expiratory volume in one second at 3 months were unsignificant (–4.2% ± 3.2%, p = 0.1).

All domains of the SF-36 questionnaire and both physical and mental component summaries did not significantly decrease at 1 month postoperatively (Fig 3). All SF-36 domains, including also the physical component summary and mental component summary, approximated the preoperative value within 3 months from the operation. Interestingly, vitality demonstrated a marginal significant improvement compared with the baseline value. Data about all SF-36 domains are reported in Figure 2.

View larger version (43K): [in this window] [in a new window]   Fig 3. Mean values of Short Form-36 (SF-36) domains at 1 and 6 months and relative polar graphic. (BP = bodily pain; GH = general health; MCS = mental component summary; MH = mental health; n. pts = number of patients; NS = not significant; PCS = physical component summary; PF = physical function; RE = role emotional; RP = role physical; SF = social function; VT = vitality.)

Figure 4 describes overall survival of patients with lung metastases. Three- and 5-year overall survival rates for metastatic disease were 52% and 43%, respectively. Among patients who relapsed, mean disease-free interval was 12 ± 5.8 months. First site of relapse (Table 4) showed a significant shorter interval in nonpulmonary sites or in nonpalpated lungs. There were 4 patients with pulmonary recurrences of 6 lungs not palpated for technical reasons, after a mean interval of 6 ± 1.8 months. Conversely, only 22 of 65 bilaterally explored patients recurred after a mean disease-free interval of 21 ± 12 months. Seven patients had a second transxiphoid approach. In none of them did we find adhesion dense enough to impede the second procedure. Furthermore, no recurrence was found in the transxiphoid incision, along the thoracoscopic ports, or adjacent to previous resection margins. Although selection biases do not allow statistical comparison, overall recurrence rate in the lungs was lower than that of the patients operated on with a unilateral pure thoracoscopic approach durign the same period. That was likely attributable to later findings in the nonexplored lung.

View larger version (14K): [in this window] [in a new window]   Fig 4. Kaplan-Meier curve for patients with lung metastases.

	Comment

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In 2003, Wright and colleagues [19] reported a modified approach using a transdiaphragmatic route. This combination of approaches was very appropriately defined by the same authors as "hand-assisted thoracoscopic surgery." In comparison with the transxiphoid, the transdiaphragmatic route allows easier resection of lesions sited in the left lower lobe. However, it implies the dissection of the diphragmatic fibers with potential damages of phrenic branches and creation of a locus minoris resistentiae, predisposing to diaphragmatic hernias.

In a recent article, Detterbeck and Egan [20] reproposed the transxiphoid approach through which they performed 24 consecutive operations, including pulmonary metastasectomy, biopsy, and lung cancer resection. They demonstrated that this substernal handport allowed biopsy and resection of lesions otherwise not amenable to a minimally invasive approach. They also evaluated short- and long-term results with less postoperative pain and morbidity and shorter hospital stay compared with the sternotomy, with equivalent relapse rate and long-term survival.

The advantages in using the transxiphoid hand-assisted videothoracoscopy approach can be summarized as follows. At the moment, the hand is the best device to detect small metastases or deeply located nodules in lung parenchyma. With the refinement of imaging devices, the concept of CT-documented occult metastases is going to become obsolete [21]. Indeed, actual CT allows the discovery of very small lesions. Nevertheless, we still consider palpation to be fundamental in finding such a small nodule within the parenchyma and to simplify resection procedure. Even the introduction of positron emission tomography [22] does not seem to change our policy. The scant predictive power for subcentimetric lesions of this technique still allows us to consider resection under palpation as the preferable option.

The confidence and reliability that we have acquired with transxiphoid hand-assisted videothoracoscopy for lung metastasectomy allows us to propose routine manual palpation of both lungs [23], making this technique really comparable with median sternotomy or bilateral thoracotomy. Comparing VAS values with those measured after median sternotomy performed in the same period for thoracic pathologies, there were significant differences at day 1 (mean basal pain, 2.15 versus 2.7; p < 0.05), 1 week (mean basal, 1.0 versus 1.8; p = 0.001), and 1 month (mean provoked by movement, 0.9 versus 1.5; p = 0.01). Similarly, acute stress makers were lower and recovered earlier than those recorded after sternotomy. Finally, serum interleukin-6, -8, and -10 were lower than those registered for median sternotomy in other studies [24]. Although cardiac arrhythmia is still one of the most important contraindications to this procedure, we found that in cardiac healthy patients, rhythm disorders induced by the arm insertion are mild and transitory. Our conversion rate was 5%: this is comparable with the conversion rate for any other VATS and may be justified by an accurate preoperative selection. In our experience, we had no right phrenic palsy as reported by other authors [19]. We would also like to stress the oncologic benefits of the procedure, which are usually the more criticized aspects of thoracoscopic approaches. We found a risk of recurrence comparable with that of the other conventional bilateral accesses, with an analogous overall and disease-free survival.

We acknowledge that no statistical comparison with a control group was made in this study, but results are anyway remarkable and should be an inducement to authorize a multicentric study done on a prospective randomized basis.

We conclude that transxiphoid hand-assisted videothoracoscopy proved less invasive than conventional bilateral approaches and improved long-term quality of life without affecting the survival rate. On these bases, transxiphoid hand-assisted videothoracoscopy deserves to be included in the "standard armamentarium" of approaches for thoracic surgery. Hence, we recommend it whenever manual palpation during video-assisted procedure is required.

	Acknowledgments

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This study was supported by grants from the Ministry of Health and Regione Lazio 2002 "Profilo genetico associato al fenotipo metastastico ed alla prognosi nei tumori polmonari" and partially (60%) by the Ministry of Health.

	References

Top Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 

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				F. C. Detterbeck Invited commentary Ann. Thorac. Surg., June 1, 2007; 83(6): 1984 - 1985. [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Tommaso Claudio Mineo Vincenzo Ambrogi Eugenio Pompeo Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Mineo, T. C. Articles by Pompeo, E. Search for Related Content PubMed PubMed Citation Articles by Mineo, T. C. Articles by Pompeo, E. Related Collections Lung - cancer Related Article