Outcome of Management of Pseudomyxoma Peritonei: National Cancer Institute.

Article Information

Gad Z1*, Nassar O1, Soliman H1, Mohamed S2 and Mohamed M3

1Surgical Oncology Derpartment, National Cancer Institute, Cairo University, Giza, Egypt

2Medical Oncology Derpartment, National Cancer Institute, Cairo University, Giza, Egypt

3Ain Shams University, Cairo, Egypt

*Corresponding Author: Dr. Zeiad Samir Gad, Surgical Oncology Derpartment, National Cancer Institute, Cairo University, Giza, Egypt

Received: 14 February 2018; Accepted: 26 February 2018; Published: 28 February 2018

Citation: Gad Z, Nassar O, Soliman H, Mohamed S, Mohamed M. Outcome of Management of Pseudomyxoma Peritonei: National Cancer Institute. Journal of Cancer Research 2 (2018): 25-37.

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Abstract

Background: The current treatment for pseudomyxoma peritonei (PMP) consists of radical cytoreductive surgery (CRS) followed by hyperthermic intra-peritoneal chemotherapy (HIPEC).

Aim: To assess PMP patients regarding the clinical and pathological characteristics, the treatment including surgery (CRS) and chemotherapy either HIPEC type or post-operative systemic chemotherapy aiming to evaluate end results regarding recurrence and survival.

Patients and Methods: This retrospective study included 39 patients with PMP who were diagnosed, treated and followed-up from 2009-2014 at National Cancer Institute, Cairo, Egypt.

Results: High grade mucinous adenocarcinoma was found in 23.1% of patients. Patients with low grade tumor showed higher survival rate compared with patients with high grade disease. The mean operative PCI score all patients who were explored was 15.81. Our study reported success to achieve complete cytoreduction that was combined with HIPEC in 44% of patients who were planned for this modality. Treatment related postoperative grade (3-5) complications mainly surgery related developed in 17.3 of patients. Operative mortality was 22.2%. The follow up period in our study was quite short (mean 22.9). However the overall survival at the end of the follow up in our study was 48.7%, 1 year survival was 82%, and 2 year survival was 41%. The overall survival in patients treated with CRS and HIPEC was 66.6%, with 1 year and 2 year survival of 91% and 66.6% respectively. Only 2 patients developed recurrent disease during the follow up period.

Conclusion: The outcome of PMP treatment process is extremely variable. Combined CRS and HIPEC were considered the best therapeutic approach for patients with PMP. Surgical experience combined with proper patient selection have to be built up together

Keywords

Pseudomyxoma peritonei, Hyperthermic intra-peritoneal chemotherapy, Tumor, Chemotherapy

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Article Details

1. Introduction

Pseudomyxoma peritonei (PMP) is a rare intraperitoneal tumor, characterized by disseminated intraperitoneal tumor implants on peritoneal surfaces. The disseminated neoplastic cells produce mucin, which leads to the characteristic mucinous ascites [1].

Traditionally PMP has been treated with serial debulking procedures. This technique can provide relief for some time; however repeated debulking procedures become increasingly difficult, and lead to more complications [2].A more aggressive approach combining Cytoreductive Surgery (CRS) and Intraperitoneal Chemotherapy (IPEC) is being used. CRS is performed to remove as much macroscopic disease as possible often undertaken according to Sugarbaker’s protocol. This is combined with IPEC that targets the microscopic residual disease and free neoplastic cells in the peritoneal cavity. This chemotherapy may be heated (hyperthermic) (HIPEC), which is used intra-operatively; or this can be used either preoperatively or early postoperative [3]. Retrospective studies have shown that debulking procedures alone can provide 5- year survival rates of 55% -75%, however, around 90% of patients have disease recurrence within 2 years and will often require multiple debulking procedures [4].

Combining CRS and HIPEC can greatly improve survival with average 5 year survival rate around 76% [5]. However other studies have shown that 5 year disease free survival can range from 37.4% to 74%. This difference between studies may be a reflection of patient selection and experience of the centers than an evaluation of the treatment regimen [6]. The aim of this work was to assess patients with PMP regarding the clinical and pathological characteristics, the treatment including surgery (CRS) and chemotherapy either HIPEC type or post-operative systemic chemotherapy aiming to evaluate end results regarding recurrence and survival.

2. Patients and Methods

2.1 Patients

This is a retrospective study that was conducted at National Cancer Institute (NCI) in Cairo, Egypt. The study included patients with PMP who were diagnosed (radiologically and pathologically), treated and followed up in the period from 2009 to 2014.

2.2 Methods

Histologically proven PMP were identified at the Histopathology department database. Patients’ files were retrieved from the Biostatistics department. Data were extracted from the medical records, and selected variables were collected including; Demographic characteristics included age and gender, patient medical history regarding diabetes mellitus and hypertension, history and number of previous surgeries that were related to PMP diagnosis and management, time between disease diagnosis and definitive surgery, number and types of lines of preoperative and postoperative systemic chemotherapy, and patients’ response, pathological features of the disease including type, grade, margins and lymph nodes involvement, preoperative evaluation including laboratory, radiological investigations including CT scan for the chest and abdomen, MRI, and PET CT if available, to estimate the preoperative PCI and metastasis, presence of extra-peritoneal metastasis, Operative data (operative PCI score, whether complete or incomplete cytoreduction was done, data about hyperthermic intra peritoneal chemotherapy and type of chemotherapy, intraoperative morbidity, operative mortality), post-operative data (ICU admission and duration of ICU admission, hospital stay was calculated starting from date of operation till date of discharge, follow up data including disease progression and recurrence), survival data (event free survival was calculated from date of surgery till date of recurrence, progression or date of last follow up, overall survival was calculated from date of diagnosis of the primary cancer till date of death or date of last follow up if not died).

Date of diagnosis was determined by the date of the operation or by the date of the first pathology report if biopsy was taken. Histopathology of the tumor was classified according to the WHO classification, to low grade mucinous carcinoma and high grade mucinous carcinoma. Tumor markers included in the study were CA125, CA19-9 and CEA. Data about completeness of cytoreduction was not documented according the CC score, so it was estimated according to R score; where R0 means no microscopic residuals at the end of the operation, R2 means macroscopic residual, while R1 means microscopic residuals detected as positive margin. Operative complications were considered as any deviation from the ideal operative and postoperative course, while operative mortality was defined as death within one month of the operation.

Progression and recurrence was diagnosed in case of marked rise of tumor markers and/or evidence of relapse in abdominal CT scan, or during laparotomy for any cause.

3. Results

This study included 39 patients with pseudomyxoma peritonei. Their mean age was 53.8 years (Table 1). Female to male ratio was about 1:1 [20 females (51%): 19 males (49%)]. Diabetic patients represented 5.6% of patients and 12.5% of patients were hypertensive. Twenty eight patients (71.7%) were diagnosed outside NCI, while 11 patients (28.2%) were diagnosed at NCI. The circumstances leading to the discovery of PMP were; open biopsy during abdominal surgery in 84.6% (n=33) of patients, core biopsy in 10.2% (n=4), laparoscopic in 2.6% (one patient), and cytology in 2.6% (one patient). These abdominal surgeries included Panhystrectomy in 11 patients (33.3%), exploration in 13 patients (39.3%), appendectomy in 4 patients (30.3%), hernioplasty in 3 patients (9.1%), during caesarian section in one patient (3%), and iliopsoas mass in one patient (3%). Twenty three patients (58.9%) were presented with abdominal or pelvic mass, 6 patients with abdominal or pelvic cysts while ascites was manifested in 66.7% of patients ranging from mild to massive. Extra-peritoneal metastasis was reported in 4 patients (10.2%) that included liver metastasis in 3 patients and one patient presented with spread along the insertion of iliopsoas muscle at the upper thigh.

Descriptive Statistics

Range

Mean ± SD

Age (years)

25-70

53.846 ± 12.014

Time between diagnosis

15-Jan

4.577 ± 3.880

and operation (months)

ICU stay (days)

21-Jan

6.368 ± 5.387

Total hospital stay (days)

Jan-68

11.115 ± 13.698

Follow up time (months)

Jan-63

22.974 ± 15.875

Table 1: Descriptive statistics.

CEA was elevated in 15/22 patients (68.1%) in whom the test was done while CA 19-9 was measured in 19 patients and it was elevated in 9 patients (47%). CA125 was measured in 14 patients and it was elevated in 6 patients (42%). Low grade mucinous adenocarcinoma was reported in 30 patients (76.9%), while high grade mucinous adenocarcinoma in 9 patients (23.1%).

In preoperative assessment, 32 patients (82%) had history of one previous surgery related to their illness, while 12% did not undergo any previous surgeries. The mean time between disease diagnosis and the operation was 4.6 months (range= 1-15). Twenty six patients (68%) were eligible and planned for combined CRS and HIPEC, and one patient for laparoscopic exploration. Only 12 patients (44.4%) underwent cytoreductive surgery and HIPEC, 6 patients were inoperable. Five patients had CRS without HIPEC; as their operations were aborted after completion of cytoreduction due to intraoperative complications or anesthetic limitations. However the operation was incomplete in 3 patients, and aborted before complete cytoreduction due to intraoperative morbidity. The mean operative PCI score was 15.8 (Range=0-31).

The other 11 patients (28%) who were excluded from CRS and HIPEC were planned for follow up with or without systemic chemotherapy, or for best supportive care. One patient died before treatment. Among patients that underwent CRS with or without HIPEC, a macroscopic complete cytoreduction (R0) was reached in 13 patients (76.4%), R1 in 2 patients, and R2 in 2 patients. Bowel resection was done in 57.6% of patients who were planned for surgery.

During the study period, 8 patients (20.5%) received one line of systemic chemotherapy, 5 patients (12.8%) received two lines. The response of the disease to chemotherapy was progressive in 5 patients and stationary in the other 8 patients. The different lines of chemotherapy used in those patients are shown in Table 2. However three patients gave history of treatment with chemotherapy outside NCI but the lines used were not documented.

Chemotherapy line

Number of patients

Taxol - Carboplatin

6

FOLFOX

2

Taxol - Gemzar

1

Cisplatin

1

FU - xeloda

1

Xeloda

1

Oxaloplatin - xeloda

2

IFL

1

Table 2: Lines of chemotherapy used.

3.1 Morbidity and mortality

Intraoperative complications encountered in 8 patients (29%), the most common was bleeding in 6 patients. Treatment related postoperative grade [3-5] complications mainly surgery related developed in 4 patients (17.3%) that consisted of leakage in 2 patients, pulmonary embolism, and reactionary hemorrhage. Operative mortality was 22.2% (n=6). Nineteen patients (70.4%) needed postoperative ICU admission with the mean ICU stay was 6.3 days (range 1-21), while the mean postoperative hospital stay was 11.1 days (range 1-68).

3.2 Outcome and survival

The mean follow up period was 22.9 months (range 1-63). At the end of the follow up 19 patients were alive and 20 patients (51.3%) died, the overall survival was 48.7%, 1 year overall survival rate was 82%, and 2 year overall survival rate was 41%. The 1 and 2 years overall survival in patients treated with CRS and HIPEC were 91%, and 66.6% respectively. Two patients (16.7%) developed disease recurrence that needed reoperation with cytoreductive surgery and HIPEC. There was a significant relation between patients’ age and their final status or survival; young patients were associated with higher survival rates. In patients who underwent the operation after a period less than 6 months survival rate was 45%, 66.7% in operations within 6 -12 months, and 0% in operations done within a period more than a year. However these results were insignificant. Overall survival in patients with low grade mucinous adenocarcinoma was 56.6% compared to 22.2% in patients with high grade mucinous adenocarcinoma but the difference was of borderline significance (P=0.070). Patients with low grade tumor who underwent CRS and HIPEC showed significantly better overall survival when compared with those with high grade disease who underwent the same surgery (P=0.028). Correlating the number of elevated preoperative tumor markers and survival showed no significant relation between the number of elevated tumor markers and the overall survival. In all patients who were explored the mean operative PCI score was 15.81 (range 1-30).The mean PCI score of those patients who were alive at the end of the follow up period was 13, compared to 18 in patients who died. Although the mean PCI score was higher in patients who died at the end of follow up period, the correlation between the mean PCI score and survival or recurrence in our study was not significant (Table 3). Among patients who had any trial for CRS and HIPEC, operative complications were significantly related to post-operative mortality (Table 4), and overall survival (Table 3). Survival was 12.5% in patients who developed operative complications compared with 63.2% among other patients. There was no significant relation between treatment with chemotherapy and the overall survival (Table 3).

Table icon

Table 3: Effect of different variables done on the survival rate.

Table icon

Table 4: Effect of operative complications on operative mortality rate.

4. Discussion

The introduction of cytoreductive surgery followed by intraperitoneal chemotherapy as a more aggressive approach has resulted in a favorable impact on survival in patients with PMP. The pathological process of PMP is a subclinical event in the majority of patients, and pathological diagnosis is commonly made after laparotomy. Most of patients included in our study were diagnosed outside NCI, and were referred with at least one previous laparotomy. PMP is generally 2-3 times more common in females. Chua et al. [7] reported that age more than 53 years negatively affects overall survival. Our study reported a male to female ratio of 1:1 with mean age 53.8 years. We reported a significant relation between patients’ age and their final status or survival, as young patients were associated with higher survival rates.

Improving the outcome of surgery requires careful patient selection through the proper preoperative investigations. However accurate assessment of preoperative PCI is not often possible. The surgical PCI score is considered a strong prognostic factor, as it helps to predict the chance to achieve complete cytoreduction, which directly affects patients’ morbidity and survival [8]. In this study the mean operative PCI score was 15.81. Although the mean PCI score was higher in patients who died at the end of follow up period, the correlation between the mean PCI score and survival or recurrence in our study was not significant.

Most of patients with PMP have elevation in one or more of the serum tumor markers. However it is non-specific to diagnose PMP but it is considered significant and independent prognostic factor regarding disease free survival and overall survival. A 5 year overall survival of 91% was reported in patients with no elevation in preoperative tumor markers compared to 60.8% overall survival in patients with elevated tumor markers [9]. In the current work, the correlation in between higher tumor markers and the final status of patients was insignificant. This might be related to small number of patients who were tested for tumor markers.

The most recent pathological classification of PMP is according to the WHO classification, categorized the disease to low grade and high grade mucinous adenocarcinoma [10]. So in this study it was important to unify the classification depending on the grade and cell type. We reported low grade mucinous adenocarcinoma in 76.9% of patients. Patients with low grade tumor showed higher survival rate compared with patients with high grade disease. However these results were not significant. The histopathological grade is considered an important prognostic factor regarding patients’ outcome, as patients with high grade tumor demonstrated invasive component and had poor outcome compared with those with low grade disease.
Survival was much better with low grade tumor than those with high grade tumor. So a non-invasive histopathology is extremely important in selecting patients who are most likely to benefit from this treatment strategy [11]. In patients with low grade tumor the overall survival rate at 20 years was 68% versus 18% in patients with high grade. Low grade patients with a PCI score less than 20 had 20 years survival of 90%, versus 65% survival among those with PCI more than 20 with the same pathology. High grade tumor patients with PCI less than 20 the 10 years survival was 45% compared to 28% in patients with PCI more than 20 [12]. However we reported higher survival in patients with low grade tumors compared to high grade, it was difficult to compare our results with other studies due to the short follow up period in this study.

The pathological process is mostly subclinical, and may be an incidental finding during laparotomy. Symptoms of appendicitis, increased abdominal girth, and ovarian mass are the most common presentation. Abdominal pain, hernia and ascites are less common presentations [13]. In this study 58.9% of patients presented with abdominal or pelvic mass, 6 patients with abdominal or pelvic cysts while ascites was manifested in 66.7% of patients ranging from mild to massive. Extra-peritoneal metastasis was reported in 10%.

To identify appropriate surgical candidate and to predict tumor resectability, it was extremely important to do preoperative imaging. A full contrast abdomino-pelvic CT can provide information about the extent of the disease and to estimate the radiological PCI. CT sensitivity varies from 60% to 90%, depending on the quality of CT, size of tumor nodules, the regions examined and the interpretation of the radiologist. However an accurate assessment of radiological PCI is often not possible as it is poor at detecting nodules less than 5mm so the presence of milliary disease is a common cause of underestimation of PCI [14]. Recent advances in MRI suggested that it can be a better predictor of the surgical PCI compared to CT especially in detection of small bowel involvement. However it is limited by the experience of the radiologist [15].

Extent of the disease reported with PCI score is the most important factor in predicting resectability and hence there is a strong relation between the PCI and the chance to achieve complete cytoreduction that is directly related to survival. Studies reported that when PCI score is greater than 20 the 5 year survival rate is less than 10% and here it is recommended to avoid cytoreductive surgery and HIPEC in PCI score more than 20 [8]. The most frequently used regimens in HIPEC are; Mitomycin C/doxorubicin, perfused intraperitoneal for 90 minutes (Sugarbaker’s protocol) [12], and Oxaloplatin perfused intraperitoneal for 30 minutes (Elias’ protocol) [16]. However there are many other regimens that may include single chemotherapeutic drug Mitomycin C or Oxaloplatin alone.

This study reported success to achieve complete cytoreduction that was combined with HIPEC in only 44% of patients who were planned for this treatment modality. The chemotherapeutic regimen we used was Mitomycin C alone heated to 42°C and perfused through closed abdomen technique.
In a series of patients, Smeenk et al. [6] reported complete cytoreduction in 32% of patients. However, Jarvinen et al. [17] in another series reported complete cytoreduction combined with HIPEC in 81% of patients who were suitable for CRS and HIPEC. Andreasson et al. [18] studied the outcome differences between debulking surgery and combined CRS and HIPEC, where R1 resections were achieved in 25% of patients, and R2 resections achieved in 75% of patients. Multiple operations were needed in 62% for persisting tumor in this group. While the 5 year survival in the combined CRS and HIPEC was 94% with R1 resections, and 28% with R2 resections. Patients with tumor nodules smaller than 2.5 mm in diameter (CC-0 and CC1) after cytoreduction were much more likely to survive than those with an incomplete cytoreduction [19]. Among patients who underwent CRS alone or combined with HIPEC in this study, a macroscopic complete cytoreduction (R0) was reached in 76.4% of patients. The relation between R score and survival in our study was 61.5% in patients with R1 resection however these results were not significant.

All available studies regarding the role of systemic chemotherapy are retrospective and limited to unresectable disease. Sugarbaker et al. [20] reported radiological response rate of 44% progression free survival of 6.9 months, and 50% progressive disease. Sugarbaker et al. [21] analyzed the role of FOLFOX4 neoadjuvant chemotherapy, and reported 29% objective response rate; but there was also 50% progression. However neoadjuvant chemotherapy is considered a poor prognostic factor regarding progression free survival and overall survival [22]. In this study there was no significant relation between treatment with chemotherapy and the overall survival.

Cytoreductive surgery combined with HIPEC is a quite complicated operation that carries significant rates of morbidity and mortality. This risk is acceptable in such lethal disease. And so many studies reported variable rates of operative and post-operative complications. In a systematic review on the efficacy of cytoreductive surgery and perioperative intraperitoneal chemotherapy for PMP, reported overall morbidity rate varied from 33% to 56%. And overall mortality rate ranged from 0 to 18%. With mean hospital stay ranged from 26 to 29 days, and median hospital stay from 16 to 21 days [23].

The incidence of complications depended more on the extent of the disease, number of peritonectomy procedures, and time required to complete the cytoreduction, rather than as a direct association with the intraperitoneal chemotherapy administration [24]. Smeek et al. [25] studied the morbidity and mortality in patients with PMP treated with CRS and HIPEC, and reported treatment related morbidity of 54%, mainly surgery related and reported treatment related mortality of 11%. Baratti et al. [26] evaluated the outcome of combined CRS and HIPEC, and reported grade 3-5 surgical complications occurred in 18.7% of patients following surgery, while operative mortality occurred in one patient.

In this study we reported intraoperative complications developed in 29% of patients. Operative mortality was 22.2%. Among patients who had any trial for CRS and HIPEC, operative complications were significantly related to post-operative mortality, and overall survival. Comparing these results with the previously mentioned studies results showed that we have an average operative complications rate. However small number of patients stands against reporting significant results. A two-step approach may be used by doing HIPEC five days after CRS as a trial to decrease operative morbidity. The delayed HIPEC offers a chance to avoid long operation time for the patient and the surgeon, and also a chance to diagnose complications related to CRS as anastomotic leak that can be treated before HIPEC. However the long ICU stay and the cost of two operations are disadvantages limiting its use. Moreover adhesions and fibrin barrier limits the chemotherapy penetration to the tumor decreasing its cytotoxicity [27].

Survival and progression of the disease depends on multiple prognostic factors including PCI score, completeness of cytoreduction, tumor histology, prior surgical score, and previous lines of chemotherapy. These results showed no difference in short term survival between serial debulking and HIPEC. This finding suggested that CRS and HIPEC do not cause dramatic improvement in survival within the first 5 years. However in the long-term the survival benefits become more apparent, as the natural history of the disease is moderately slow. However survival is not the only aspect that matters. As number of reoperations were higher for the debulking era group than those for HIPEC era group (1.6 vs. 0.8). Andreasson et al. 2012 [18] reported 5 year overall survival of 74% for HIPEC compared to 40% for debulking surgery. Development of the combined CRS and HIPEC, as a treatment, has significantly improved outcomes of PMP, regarding survival and disease free survival. The outcome of treatment depends on numerous factors that affects prognosis, and lack of homogeneity between centers makes a comparison of results across various studies difficult, this makes prediction of factors for short-term outcomes unclear.

In a multicenter study Elias et al. [8] analyzed data of 301 patients with PMP treated with surgery and intraperitoneal chemotherapy. The overall survival was 89% at 1 year, 84% at 3 years, 72% at 5 years and 54% at 10 years. Disease free survival was 56% at 5 years. Grade 3 to 4 complications occurred in 40% of patients that required reoperation in 17.5% of them. Chua et al. [7] in a multi institutional study including more than 2000 patients, reported 3 years survival of 80%, 5 years survival of 74%, 10 years survival of 64% and 15 years survival of 59%. Their study also reported progression free survival of 8.2 years with median survival of 16.3 years. In a series of 465 patients in the UK, an overall survival rate at 5 years of 87%, and 74% at 10 years [28]. In a study to evaluate the outcome and recurrence after CRS and HIPEC in 512 patients with PMP, Lord et al. [5] reported 26% of patients who had complete cytoreduction then developed recurrence during the follow up period, 25% of those recurred patents underwent redo surgery with complete tumor removal in 57% of them. The disease free survival at 5 years was 90% in no recurrence patients, 79% in patients who had recurrence and redo surgery, and 64% in those who had recurrence without redo surgery. Smeenk et al. [6] studied patients with PMP and reported a 3 year survival of 70.9% and 5 year. Baratti et al. [26] evaluated the outcome of combined CRS and HIPEC, and reported an overall survival of 79% at 5 years, and disease free survival of 42% at 5 years.

The follow up period in our study was quite short. The mean follow up period was 22.9 months, along with the small number of patients, were two factors against reporting significant results regarding treatment outcome. The learning curve in different centers regarding PMP treatment is extremely long as it depends on various factors including; the procedure itself, surgeons and the way they achieve their experience and proficiency which depends mainly on external observer based fellowships, and number of principal surgeons per center ‘centers with more than 3 principal surgeons were at higher risk of their performance getting worse over time [29]. To acquire optimal experts, at least 100 procedures per center and 96 procedures per surgeon are necessary. This raised a fact that, the greater the institutional specialization in treatment of PMP, the lower the rate of early failure [29]. A limitation of this study remains the small number of patients that affected the significance of our final results and conclusion. So the need for more centralization through continuous cooperation between other centers, by referring PMP patients to more expert and specialized centers. Along with continuous collection of data over a long period of years is considered necessary for stronger and significant conclusions.

In order to identify the most effective follow up regimen, research is ongoing to identify patients at higher risk of recurrence and the risk factors. However currently, recurrence is diagnosed when there is marked rise in tumor markers, or evidence of relapse with CT [6]. The diagnosis of progressive disease is not always easy, as after extensive surgery CT scans are usually difficult to interpret due to post-surgical changes. So it is useful to make a baseline CT scan 3 months after primary surgery, and compare further CT scans [6]. CT has low sensitivity to detect tumor deposits less than 5mm, tumors located on lesser omentum, root of mesentery, left hemi-diaphragm, and bowel wall due to the use of oral contrast. MRI is more sensitive to detect these tumors. However availability of high resolution CT and its rapid technique makes it the primary imaging modality compared to MRI that has long scanning time, high cost and more dependence on radiologist experience [30]. PET/CT has better diagnostic accuracy compared to MRI, as well as its coverage of the whole body giving information about possible metastasis; (PET/CT vs MRI) sensitivity 93/87%, specificity 96/92% [30].

The post-operative follow up protocol we use is to do CT scan and tumor markers every 3 months in year one, then every 6 months in year 2 and 3, then annually, with PET/CT once per year. Patients, with mucinous neoplasms, should be followed for years to detect PMP in early stage. A minimal follow up for 5 years consisting of physical examination, tumor markers, CEA and CA 19-9 and CT scan once a year or when indicated is reasonable. This is because of the long latency time and indolent tumor behavior [6].

References

  1. Andreasson H, Lorant T, Pahlman L, et al. Cytoreductive surgery plus perioperative intraperitoneal chemotherapy in pseudomyxoma peritonei: Aspects of the learning curve. Eur J Surg Oncol 40 (2014): 930-936.
  2. McBride K, McFadden D, Osler T. Improved survival of patients with pseudomyxoma peritonei receiving intraperitoneal chemotherapy with cytoreductive surgery: a systematic review and meta-analysis. J Surg Res 183 (2013): 246-252.
  3. Alves S, Mohamed F, Yadegarfar G, et al. Prospective longitudinal study of quality of life following cytoreductive surgery and intraperitoneal chemotherapy for pseudomyxoma peritonei. Eur J Surg Oncol 36 (2010): 1156-1161.
  4. Chua TC, Yan TD, Smigielski ME, et al. Long-term survival in patients with pseudomyxoma peritonei treated with cytoreductive surgery and perioperative intraperitoneal chemotherapy: 10 years of experience from a single institution. Ann Surg Oncol 16 (2009): 1903-1911.
  5. Lord AC, Shihab O, Chandrakumaran K, et al. Recurrence and outcome after complete tumour removal and hyperthermic intraperitoneal chemotherapy in 512 patients with pseudomyxoma peritonei from perforated appendiceal mucinous tumors. Eur J Surg Oncol 41 (2014): 396-399.
  6. Smeenk RM, Verwaal VJ, Antonini N, et al. Survival analysis of pseudomyxoma peritonei patients treated by cytoreductive surgery and hyperthermic intraperitoneal chemotherapy. Ann Surg 245 (2007): 104-109.
  7. Chua TC, Moran BJ, Sugarbaker PH, et al. Early- and long-term outcome data of patients with pseudomyxoma peritonei from appendiceal origin treated by a strategy of cytoreductive surgery and hyperthermic intraperitoneal chemotherapy. J Clin Oncol 30 (2012): 2449-2456.
  8. Elias D, Gilly F, Boutitie F, et al. Peritoneal colorectal carcinomatosis treated with surgery and perioperative intraperitoneal chemotherapy: retrospective analysis of 523 patients from a multicentric French study. J Clin Oncol 28 (2010): 63-68.
  9. Taflampas P, Dayal S, Chandrakumaran K, et al. Pre-operative tumour marker status predicts recurrence and survival after complete cytoreduction and hyperthermic intraperitoneal chemotherapy for appendiceal Pseudomyxoma Peritonei: Analysis of 519 patients. Eur J Surg Oncol 40 (2014): 515-520.
  10. Panarelli NC, Yantiss RK. Mucinous neoplasms of the appendix and peritoneum. Arch Pathol Lab Med 135 (2014): 1261-1268.
  11. Sugarbaker PH. Cytoreductive surgery and perioperative intraperitoneal chemotherapy: a new standard of care for appendiceal mucinous tumors with peritoneal dissemination. Clin Colon Rectal Surg 2005; 18: 204-14.
  12. Sugarbaker PH. Pseudomyxoma peritonei and peritoneal metastases from appendiceal malignancy. In: Sugarbaker PH, editor. Cytoreductive surgery and perioperative chemotherapy for peritoneal surface malignancy. Textbook and Video Atlas 3 (2013): 57-75.
  13. Sugarbaker PH, Esquivel J. Clinical presentation of the pseudomyxoma peritonei syndrome. Br J Surg 87 (2000): 1414-1418.
  14. de Bree E, Koops W, Kroger R, et al. Preoperative computed tomography and selection of patients with colorectal peritoneal carcinomatosis for cytoreductive surgery and hyperthermic intraperitoneal chemotherapy. Eur J Surg Oncol 32 (2006): 65-71.
  15. Menassel B, Duclos A, Passot G, et al. Preoperative CT and MRI prediction of non-resectability in patients treated for pseudomyxoma peritonei from mucinous appendiceal neoplasms. Eur J Surg Oncol 42 (2016): 558-566.
  16. Elias D, Lefevre JH, Chevalier J, et al. Complete cytoreductive surgery plus intraperitoneal chemohyperthermia with oxaliplatin for peritoneal carcinomatosis of colorectal origin. J Clin Oncol 27 (2009): 681-685.
  17. Jarvinen P, Ristimaki A, kantonen J, et al. Feasibility of radical cytoreductive surgery and Hyperthermic intraperitoneal chemotherapy for pseudomyxoma peritonei of appendicular origin. Scandinavian Journal of Surgery 102 (2013): 145-151.
  18. Andreasson H, Graf W, Nygren P, et al. Outcome differences between debulking surgery and cytoreductive surgery in patients with Pseudomyxoma peritonei. Eur J Surg Oncol 38 (2012): 962-968.
  19. Harmon RL, Sugarbaker PH. Prognostic indicators in peritoneal carcinomatosis from gastrointestinal cancer. Int Semin Surg Oncol 2 (2005): 3.
  20. Sugarbaker P, Chang D. Results of treatment of 385 patients with peritoneal surface spread of appendiceal malignancy. Ann Surg Oncol 6 (1999): 727-731.
  21. Sugarbaker PH, Bijelic L, Chang D, et al. Neoadjuvant FOLFOX chemotherapy in 34 consecutive patients with mucinous peritonealcarcinomatosis of appendiceal origin. J Surg Oncol 102 (2010): 576-581.
  22. Chen CF, Huang CJ, Kang WY, et al. Experience with adjuvant chemotherapy for pseudomyxoma peritonei secondary to mucinous adenocarcinoma of the appendix with oxaliplatin/fluorouracil/leucovorin (FOLFOX4). World J Surg Oncol 6 (2008): 118.
  23. Yan TD, Black D, Savady R, et al. A systematic review on the efficacy of cytoreductive surgery and perioperative intraperitonealchemotherapy for pseudomyxoma peritonei. Ann Surg Oncol 14 (2007): 484-492.
  24. Stephens AD, Alderman R, Chang D, et al. Morbidity and mortality of 200 treatments with cytoreductive surgery and hyperthermic intraoperative intraperitoneal chemotherapy using the Coliseum technique. Ann Surg Oncol 6 (1999): 790-796.
  25. Smeenk RM, Verwaal VJ, Zoetmulder FAN. Toxicity and mortality of cytoreduction and intraoperative hyperthermic intraperitoneal chemotherapy in pseudomyxoma peritoneida report of 103 procedures. Eur J Surg Oncol 32 (2006): 186-190.
  26. Baratti D, Kusamura S, Nonaka D, et al. Pseudomyxoma peritonei: clinical pathologic and biological prognostic factors in patients treated with cytoreductive surgery and hyperthermic intraperitoneal chemotherapy (HIPEC). Ann Surg Oncol 15 (2008): 526-534.
  27. Mohr Z, Hirche C, Liebeskind U, et al. Feasibility of Delayed Hyperthermic Intraperitoneal Chemotherapy in Case of Unforeseen Complications. Eur Surg Res 47 (2011): 19-25.
  28. Youssef H, Newman C, Chandrakumaran K, et al. Operative findings, early complications, and long-term survival in 456 patients with pseudomyxoma peritonei syndrome of appendiceal origin. Dis Colon Rectum 54 (2011): 293-299.
  29. Kusamura S, Moran BJ, Sugarbaker PH, et al. Peritoneal Surface Oncology Group International (PSOGI). Multicentre study of the learning curve and surgical performance of cytoreductive surgery with intraperitoneal chemotherapy for pseudomyxoma peritonei. Br J Surg 101 (2014): 1758-1765.
  30. Krishnamurthy S, Balasubramaniam R. Role of Imaging in Peritoneal Surface Malignancies. Indian J Surg Oncol 7 (2016): 441-452.

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