Abstract
The surgical treatment of malignant pleural mesothelioma (MPM) involves procedures to achieve macroscopic complete resection, depending on the patient’s condition. We reviewed the evolution of surgical approaches for resectable MPM. Since surgery is no more than a single step in the set of processes in multimodality treatment (MMT), we concluded that these procedures should give precedence to lung preservation and minimize resection whenever possible. Postoperative quality of life must be prioritized when the patient can receive appropriate adjuvant therapy.
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Introduction
Radical surgery for resectable malignant pleural mesothelioma (MPM) aims to achieve macroscopic complete resection (MCR) [1, 2]. Conversely, combining chemo-, radiation, and novel therapies has improved the prognosis of patients with MPM [3,4,5]. The treatment outcomes of patients with resectable MPM, including overall survival (OS), are improved in a multimodality treatment (MMT) setting. Recent guidelines recommend the MMT protocol combined with various modalities, including surgical therapy, based on the results of trials. However, there is still no final consensus on the standard treatment sequence [6, 7]. There are two surgical procedures to treat MPM: extra-pleural pneumonectomy (EPP) and pleurectomy/decortication (P/D) to preserve the lung parenchyma [8]. At the 2011 international mesothelioma interest group (IMIG) annual meeting, the debate on “whether EPP or P/D should be done” for resectable MPMs reached the consensus that “the type of cytoreductive procedure should be selected based on the disease distribution, institutional experience, and the surgeon’s preference and experience” [2]. Both procedures can achieve MCR, but P/D presents several advantages over EPP in sparing patients’ lungs, reducing postoperative complications, and improving their quality of life (QoL) [9]. Therefore, P/D is the surgical procedure of choice for MPM at major facilities (high-volume centers) in Europe and the United States [10, 11].
Surgical techniques have gained stability in line with the increasing number of MPM cases in experienced institutions [8, 12,13,14,15,16]. At the same time, MMT improves the survival rate. In addition to the standardization of pemetrexed-platinum combination therapies, some promising new therapies established in the treatment of lung cancer, such as angiogenesis inhibitors, immune checkpoint inhibitors, and targeted therapies, have been introduced into the treatment of MPM [3,4,5, 17, 18]. Incorporating the benefits of these new therapies into postoperative adjuvant therapy and post-recurrence treatment may improve long-term prognosis. Thus, it is essential to consider postoperative cardiopulmonary function and QoL when choosing a surgical procedure [19]. This review aims to identify the optimal surgical procedure for improving the outcomes of MPM treatment.
Definition of surgical treatment for MPM
Surgery for MPM, which is mainly cytoreductive, considers the characteristics of pleural tumors; however, due to the histological nature of MPM, microscopic residual tumor cells in the surgical margin cannot be avoided [20]. In 2006, Sugarbaker et al. defined the goal of surgical treatment for MPM as a macroscopic complete resection (MCR) [1].
Theoretically, based on the definition of R0, R1, and R2 resections, MCR stands for R1 surgery considered to be the maximum radicality possible for MPM [21]. At the 2019 International Association for the Study of Lung Cancer taskforce, Friedberg et al. defined the specific method of achieving MCR as follows: “no visible residual tumor or palpable cancer, equal to R1 resection” [22]. Moreover, the following consensus on surgical treatment was reached at the 2012 IMIG annual meeting in Boston: “in a surgical indication where MPM is histologically diagnosed, there is a lesion for which MCR can be achieved, and other therapeutic means can be implemented” [2]. Considering the importance of surgical treatment, we must mention the Mesothelioma and Radical Surgery (MARS) trial, the only randomized phase 3 clinical trial that involves surgical treatment [23]. However, some evaluations of the MARS trial reported that the number of patients is statistically underpowered (EPP (n = 24), no EPP (n = 26)) and the conclusion is too bloated outside the setting of the primary endpoint [24, 25]. Consequently, negative assessments for surgical treatment presented as outcomes must be managed carefully. Subsequently, the MARS researchers have stated that careful evaluation is needed [26].
Trend of surgical procedures
Between the 1970s and 2000s, curative-intent surgery for MPM indicated EPP followed by P/D [27, 28]. Conversely, the current guideline recommends the choice of P/D as lung-sparing surgery (ERS/ESTS/EACTS/ESTRO guidelines for the management of MPM, 2020) [6].
Looking back at the early MPM surgical interventions, there was only pleurectomy, which was performed as palliation [29]. Subsequently, two types of curative-intent surgery were reported: EPP and lung-sparing surgery, the so-called P/D. EPP was initiated in the 1970s [27] and P/D was reported several years later as less invasive with a lower significant morbidity rate [30]. Technically, the first half of the procedure is common and consists of the parietal pleura detachment [31]. In 2012, at their annual meeting in Boston, IMIG members discussed whether to use EPP or P/D for resectable MPM. They agreed that the surgeon should select the appropriate surgical method for each case, as long as MCR could be achieved [2].
Comparing postoperative mortality and adverse events, EPP had significantly higher mortality and complication rates than P/D (6.8% vs. 2.9% and 62.0% vs. 27.9%, respectively) [4]. On the other hand, P/D may be less curative oncologically than EPP [32]. In this context, no clinical trial has directly compared EPP and P/D and will be impossible to conduct in future. For this reason, there is no clear evidence of the superiority or inferiority of either of these procedures [33]. Since both EPP and P/D are designed for R1 resections, their radicality of tumor resection and oncological significance are considered equivalent. As P/D has relatively lower rates of severe complications and the advantage of being lung-sparing [21], EPP is not prioritized over P/D. Since 2008, evidence of clinical practices showed that surgeons who chose P/D had better results than those who performed EPP. The median survival rates (months) are reported as: 10.4–26 vs. 6.0–19.5 [10], 16 vs. 12 [12], 17 vs. 13 [34], 23 vs. 12.8 [35]. Moreover, because perioperative complications are reduced with P/D (27.9% (P/D) vs. 62.0% (EPP), P < 0.01) [4], postoperative QoL is not compromised, and postoperative treatment and retreatment at the time of recurrence are possible, the surgical method that preserves the lungs is considered superior [10, 25, 35, 36].
Since 2012, we have modified resection for MPM to prioritize P/D at our hospital [36]. Based on the findings during surgery, the surgeon can decide whether to resect the diaphragm or the pericardium. In a multicenter clinical trial in Japan, we tried to unify the surgical techniques specified in the document for quality control of P/D [37]. Following the 8th edition of the TNM staging system, we revised the surgical indications. Furthermore, we recently introduced non-incisional P/D in the expectation that the prognosis of resected MPM patients would be further improved [38].
Here we introduce Japan's first phase II multicenter clinical trial (JMIG0601), a clinical study that examined the validity (feasibility study) of a tri-modality strategy (induction chemotherapy, EPP, and radiation) for resectable MPM, conducted between May 2008 and November 2010. The primary endpoints of MCR > 70% and mortality < 1.0% were achieved. However, the results were unsatisfactory, with a median survival of 19.9 months and treatment-related mortality of 9.5% [39].
Following the lead of Europe and the U.S., which switched to P/D in about 2000, a second phase II multicenter clinical trial was conducted in Japan between November, 2012 and October, 2013, demonstrating the validity of P/D in multimodality treatment. The primary endpoint of MCR achievement was > 90% and the 30-day/90-day mortality rates were 0%. Median survival was 43.3 months, surpassing previous results, and the ratio of pre- and postoperative lung function was FVC/FEV1.0 = 78%/82.5% during the postoperative follow-up period. The results of this study led to the switch to P/D in Japan [37].
Surgical treatment is indicated only when performed as part of MMT
Theoretically, surgical resection for MPM focuses on R1 resection, where surgery is only included as part of combined therapy. However, there is evidence that MMT contributes to OS more than treatment with a single modality. A retrospective analysis of the IASLC database (n = 1360) showed a median survival of 20 months for the multidisciplinary treatment group vs. 11 months for the surgery alone group [40]. Although the European and United States guidelines recommend MMT, no standard treatment sequence has been established until now.
In the 1970s, MPM treatment required adjuvant therapy either before or after surgery because the surgical resection leaves inevitable microscopic tumor cells [27]. Therefore, the results of surgery alone for MPM are poor, with a median survival time (MST) of 11–13 months vs. > 20 months achieved by MST combined with adjuvant therapy. Therefore, MMT contributes to a better prognosis [40, 41]. As such, surgical resection should be performed as part of MMT to improve outcomes [42]. It is ideal to “perform treatment based on an appropriate protocol” [24], but the optimal treatment sequence for chemotherapy and surgery has not been established. A prospective controlled trial of preoperative and postoperative chemotherapy (EORTC 1205) has been conducted in in Europe since 2018. The results of this trial are expected to give the first answer to the previously debatable question [43]. The consensus and guidelines of several academic societies recommend MMT for resectable MPM. In this context, the following guidelines recommend including surgery as part of MMT: ERS and ETS in 2010 and ERS/ETS/EACTS/ESTRO guidelines in 2020 [6, 7, 44]. On the other hand, some facilities use a combination of intraoperative treatment to enhance local control, but no related guideline recommendations exist [45]. There are also reports on the effectiveness of other treatments as local controls, such as hyperthermic intraoperative cisplatin chemotherapy [46] and photodynamic therapy (PDT) [47].
Postoperative QoL
The effects of immune checkpoint inhibitors and novel treatments in systemic cancer therapy have been observed [17]. Furthermore, the combination of chemo-, immuno-, and targeted therapies has evolved, with further improvements in cancer treatment results expected. Following the improvement in prognosis, the next focus is on postoperative QoL. If the latter is preserved adequately, we may be able to expand treatment indications for recurrence. For this reason, QoL has become essential in determining the selection and adaptation of surgical procedures [48]. Therefore, even for MPM, P/D, which maintains a high QoL and expands the options for additional treatment, tends to be more advantageous than EPP. A comparison of 659 cases (102 EPP, 432 P/D) extracted in a systematic review found that postoperative QoL tended to be better after P/D [49]. A single-center study reported that after EPP, the median vital capacity decreased significantly from 2.8 L (77.7%) to 1.8 L (47.6%) [50]. Adjuvant therapy and post-relapse treatment are indicated for many patients. In our single institution study, among 57 patients with recurrence after P/D (1-year post-recurrence survival rate, 59.5%) and 39 with recurrence after EPP (1-year post-recurrence survival rate, 40.0%), 43 (75.4%) of the P/D group and only 21 (53.8%) of the EPP group underwent post-recurrence treatment [19, 51]. The contribution of P/D surgery on QoL may also be based on an ongoing comparative study between surgery plus chemotherapy and chemotherapy alone (MARS2 trial) [52].
Has the role of EPP ended?
EPP was first reported by Butchart and is well established as a curative surgery for MPM [27]. The first half of the procedure, parietal pleurectomy, is common for EPP and P/D [31]. In considering which surgical technique to use, we summarized reports from several high-volume centers comparing EPP and P/D in multimodality treatment (Table 1) [8, 10, 12,13,14,15,16, 36, 53,54,55]. The superiority and inferiority of EPP vs. P/D have been reported from various viewpoints. According to one meta-analysis, the MST was about 12–20 months for EPP and 7.1–31.7 months for P/D in a systematic review, being slightly better for P/D; however, the data was insufficient [4]. EPP is more surgically invasive and has far more complications, whereas adjuvant radiotherapy is possible only after unilateral pneumonectomy [56]. Some post-EPP retrospective analyses reported good OS for epithelioid MPM patients without lymph node metastases [57, 58].
Regarding resection radicality, P/D is considered sensuously inferior to EPP [32]. On the other hand, reports state that the prognosis was extended by the advantage of adjuvant therapy and QoL [10, 11, 43]. However, because of the bias related to the subjects and uneven differences in MMT, the comparison between surgical procedures, which is retrospective, is meaningless. Therefore, both procedures having different therapeutic effects and characteristics should be considered incompatible. Yet, it is appropriate for an experienced surgeon to examine and select a wide range of surgical procedures according to each patient’s condition.
Current status of P/D surgery
The term P/D was first proposed by Rusch in 1993 [30], but the technique has been revised by various institutions with varying styles, purposes, and nomenclature, and is currently not unified.
A consensus report jointly published by IASLC and IMIG in 2012 defined the term as follows [2]:
-
(1)
Extended P/D: parietal and visceral pleurectomy with resection of the diaphragm and/or pericardium and removal of all macroscopic tumors.
-
(2)
P/D: parietal and visceral pleurectomy with MCR without the diaphragm and/or pericardium resection.
These are the curative procedures, namely those that can achieve MCR. In terms of achieving MCR, the following questions have been raised:
-
(1)
If there is no tumor macroscopically, should the pleura be left intact, or should the organ pleura be completely resected because of the assumption of microscopic tumor?
-
(2)
If the tumor has invaded the lung parenchyma, should a combined resection of the lungs be performed, and should the procedure be evaluated differently depending on the extent of parenchymal resection?
In 2019, a joint effort arising from a task force formed at NCI-IASLC-MARF attempted to answer these questions and set out to form an international consensus on the nomenclature and description of surgical treatments for MPMs [22]. As a further improvement, a technique to perform P/D without touching the pleura where the tumor is involved was introduced in Japan, and our institution has been using this technique, whenever indicated, since 2020. We expect that this technique will contribute to improving the prognosis of patients with local recurrence and other life-threatening diseases (no-touch technique: non-incisional P/D) [38].
Finally, we present the perioperative results of P/D performed at our hospital. A total of 204 patients underwent P/D (median age, 67 years; range, 16–82 years). Men accounted for 80.9% (n = 165) of the patients. The histologic tumor types were epithelioid/biphasic/sarcomatoid (n = 188/13/4). IMIG pathological stage I (Ia + Ib) was confirmed in 54.9% (I/II/III/IV, n = 112/11/73/8). Table 2 summarizes the perioperative data, including adverse events and, prognosis, of the patients who underwent P/D at our hospital. The 30-day and 90-day mortality rates of the patients who underwent P/D were 0.5% (1/204) and 2.0% (4/204), respectively. There were no grade 4 or higher adverse events related to chemotherapy or radiation therapy. Grade 3 or higher adverse events occurred in 41 patients (20.1%). Reoperation was required for 12 patients (5.9%), and a long-term air leak, defined as an air leak lasting more than 7 days, occurred in 119 patients (58.3%). Most of these patients required pleurodesis and re-drainage. The median follow-up time after diagnosis for survivors was 28.7 months (range 1–106 months). The median overall survival (MST) and progression-free survival (PFS) times for all patients (n = 204) were 42 and 12 months, respectively.
Conclusions
The essence of surgical resection for MPM is to achieve MCR, which is possible by performing a minimum resection rather than the simple alternative between EPP and P/D. Nevertheless, achieving a QoL that can allow adjuvant therapy and optional treatment for any recurrence is of the utmost importance.
In the 2020s, lung-sparing surgery is an important part of MMT. Moreover, the surgeon should select the optimal surgical procedure according to the patient’s condition and the degree of tumor invasion. We must also be responsible for improving the patient’s prognosis from a long-term perspective, including the indications for treatment of postoperative recurrence and metastasis.
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Kondo, N., Hasegawa, S. Optimal surgery for resectable malignant pleural mesothelioma in the setting of multimodality treatment. Surg Today 54, 663–669 (2024). https://doi.org/10.1007/s00595-023-02723-8
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DOI: https://doi.org/10.1007/s00595-023-02723-8