Abstract
Yong-Kun Chi1, Ying Chen1, Xiao-Ting Li1 and Ying-Shi Sun1
1Key Laboratory of Carcinogenesis and Translational Research (Ministry of Education), Department of Radiology, Peking University Cancer Hospital & Institute, Beijing 100142, China
Correspondence to:
Ying-Shi Sun, email: [email protected]
Keywords: esophageal cancer, pN0, survival, computed tomography, neoadjuvant chemotherapy
Received: March 22, 2017 Accepted: April 28, 2017 Published: June 27, 2017
ABSTRACT
The prognosis of patients with esophageal cancer improves by using neoadjuvant chemotherapy (NAC). More patients obtain pathological N0 staging (pN0) after surgery. The heterogeneity of prognosis of these patients poses a great challenge of customizing therapeutic strategies for individual patients. The signs of lymph nodes on both pre and post NAC computer tomography (CT) scan can provide more information for evaluation. Therefore, we investigated a new approach to lymph node (LN)-survival analysis by using pre-/post-NAC CT in pN0 esophageal cancer. 79 patients undergone curative resection after NAC obtained pN0 staging. The long and short axis diameter of maximal lymph node (MaxLN) and LN number on pre-/post-NAC CT scans were recorded and assessed for predicting survival by univariate and multivariate survival analysis. The prognosis of patients with esophageal cancer was correlated with the LN size and number on pre-/post-NAC CT. The LN number on pre-NAC CT and short-axis diameter of MaxLN on post-NAC CT remained the independent predictor of overall survival. By using these two factors as classification criterion, N0b group included patients with LN number>4 on pre-NAC CT or short-axis diameter of MaxLN >7 mm on post-NAC CT and the rest patients were included in N0a group. N0a group had a significantly better overall survival than N0b group (5-year survival rate: 75.2% vs. 32.6%). The size and number of lymph node on pre-/post-NAC CT were reliable and important prognostic factors in patients with pN0 esophageal cancer. This new criterion could distinguish these patients into N0a and N0b, according to different prognosis.
INTRODUCTION
Recent treatment paradigms of esophageal cancer tend to evolve into a multimodality approach to management including surgical resection and preoperative or definitive chemoradiation therapy [1]. Increasingly, neoadjuvant chemotherapy (NAC) is becoming the neoadjuvant treatment of choice for patients with resectable esophageal cancer [2]. A number of these patients obtain ypN0 after neoadjuvant chemotherapy. Although the N classification is the most important prognostic factor in esophageal cancer because patients without lymph node involvement have a better prognosis than those with nodal involvement [3], we find that these patients presented different survival benefit after NAC downstaging occurrence in clinical follow-up. Thus, we wonder what other factors can be indicators of prognosis in patients with pN0 esophageal cancer. More pathological indicators are not available for pN0 patients except T staging. However, the characteristic of lymph nodes before surgery is revealed on the pre- and post-NAC CT.
The size of pathological lymph nodes is a well-known prognostic factor in esophageal cancer, so nodal size is a criterion for predicting nodal involvement. Unlike the sixth edition of TNM cancer staging manual, the new N classification was determined by the number of metastasis lymph nodes [4]. The change of N staging suggests that number of lymph nodes can be important indicator of prognosis. Furthermore, we demonstrate that CT is an effective tool for measuring the size and counting the total number of lymph nodes [5]. In our prior study, we found that the characteristic of lymph nodes on pretreatment CT was related to the patients’ prognosis in other gastrointestinal cancer [6].
Therefore, we decided to review characteristic of lymph nodes on pre- and post-NCA CT for assessing prognosis of ypN0 patients with esophageal squamous cell carcinoma. Further, we investigate a new approach to CT lymph node (LN)-survival analysis for 5 years follow-up in patients with esophageal carcinomas.
RESULTS
One hundred and thirty three patients undergone curative resection after neoadjuvant chemotherapy were studied. 79 patients obtaining pN0 staging after surgery were included in the follow up study (Figure 1). There were 59 men and 20 women in the study, with a mean age of 59.87 years (range 42–75). More details of patients’ characteristics and therapeutic regimens were listed in Table 1.
Figure 1: Flow chart of patient enrollment.
Table 1: Summary of patient characteristics and therapeutic regimen
Patient character(n=79) | Description | |
|---|---|---|
Age | 60±8(42 to 75) | |
Sex | Male | 59(74.7%) |
Female | 20(25.3%) | |
cTNM stages | T3N0M0 | 9(11.4%) |
T2N1M0 | 10(12.7%) | |
T1N2M0 | 1(1.3%) | |
T3N1M0 | 21(26.6%) | |
T3N2M0 | 5(6.3%) | |
T4aN0M0 | 3(3.8%) | |
T4aN1M0 | 17(21.5%) | |
T4aN2M0 | 11(13.9%) | |
T4aN3M0 | 2(2.5%) | |
Pathological differentiation | Well differentiated | 20(25.3%) |
Moderately differentiated | 41(51.9%) | |
Poorly differentiated | 18(22.8%) | |
Neoadjuvant chemotherapy (NAC) scheme | 1 cycle | 14(17.7%) |
2 cycles | 50(63.3%) | |
3 cycles | 7(8.9%) | |
4 cycles | 8(10.1%) | |
Pathological tumor regression grading (TRG) | TRG0 | 15(19.0%) |
TRG1 | 22(27.8%) | |
TRG2 | 9(11.4%) | |
TRG3 | 33(41.8%) | |
Number of lymph nodes analyzed | 18±9(6 to 48) |
cTNM stages=clinical TNM stages; NAC scheme=neoadjuvant chemotherapy scheme; TRG=tumor regression grading.
The distribution of postoperatively pathological T stages was as follows: 16 patients belonged to pT0, 6 patients to pT1a, 11 patients to pT1b, 19 patients to pT2, 25 patients to pT3, one patient to pT4a and one patient to pT4b.
Sixty-one percent of patients (48 of 79 patients) remained alive, at the last follow-up. The overall 1-year, 3-year and 5-year survival rate were 96.2%, 68.9% and 58.9% for all 79 patients.
Univariate survival analysis
The results of univariate survival analysis were listed in Table 2. For age and sex of the patients, pathological differentiation grade, tumor location, NAC scheme, pathological tumor regression grading, number of lymph nodes analyzed, cT and cN staging, univariate survival analysis did not show any factor related to the OS and DFS.
Table 2: Univariate analysis of prognostic factors according to OS and DFS
Prognostic factor | Number of patients | Overall survival | Disease-free survival | ||||
|---|---|---|---|---|---|---|---|
Rate | 95% CI | P value | Rate | 95% CI | P value | ||
Age(y) | 0.508 | 0.825 | |||||
≤59 | 42 | 57.6 | 38.8-76.4 | 60.6 | 45.5-75.7 | ||
≥60 | 37 | 52.6 | 35.2-70.0 | 54.8 | 37.4-72.2 | ||
Sex | 0.191 | 0.663 | |||||
Male | 59 | 45.9 | 25.7-66.1 | 57.3 | 43.6-71.0 | ||
Female | 20 | 68.7 | 47.7-89.7 | 59.6 | 37.8-81.4 | ||
Pathological differentiation | 0.128 | 0.133 | |||||
Well differentiated | 20 | 34.3 | 10.6-58.0 | 45 | 23.2-66.8 | ||
Moderately differentiated | 41 | 61.6 | 45.3-77-9 | 62.2 | 46.1-78.3 | ||
Poorly differentiated | 18 | 71.4 | 50.2-92.6 | 77.4 | 57.8-97.0 | ||
NAC scheme | 0.461 | 0.617 | |||||
1 cycle | 14 | 49 | 22.3-75-7 | 54.4 | 30.0-81.8 | ||
2 cycles | 50 | 56.1 | 36.5-75.7 | 64.9 | 50.6-79.2 | ||
3 cycles | 7 | 57.1 | 20.4-93.8 | 57.1 | 20.4-93.8 | ||
4 cycles | 8 | 50 | 15.3-84.7 | 50 | 15.3-84.7 | ||
TRG | 0.361 | 0.263 | |||||
TRG0 | 15 | 52.5 | 26.8-78.2 | 52.5 | 26.8-78.2 | ||
TRG1 | 22 | 71.8 | 52.4-91.2 | 71.8 | 52.4-91.2 | ||
TRG2 | 9 | 33.3 | -2.0-68-6 | 37.5 | 4.0-71.0 | ||
TRG3 | 33 | 65.7 | 49.2-82.2 | 64.5 | 47.4-81.6 | ||
cT | 0.273 | 0.473 | |||||
cT1 | 1 | - | - | - | - | ||
cT2 | 11 | 63.6 | 35.2-92.0 | 63.6 | 35.2-92.0 | ||
cT3 | 34 | 39.1 | 13.0-65.2 | 55.2 | 37.0-73.4 | ||
cT4 | 33 | 67 | 50.1-83.9 | 68.3 | 52.0-84.6 | ||
cN | 0.810 | 0.761 | |||||
cN0 | 12 | 60.6 | 29.8-91.4 | 54.5 | 25.1-83.9 | ||
cN1 | 48 | 51 | 32.6-69.4 | 61.6 | 46.9-76.3 | ||
cN2 | 17 | 56.6 | 31.7-81.5 | 58.8 | 35.5-82.1 | ||
cN3 | 2 | - | - | - | - | ||
pT | 0.03 | 0.051 | |||||
pT0 | 16 | 55.6 | 30.9-80.3 | 55.6 | 30.9-80.3 | ||
pT1 | 17 | 68.2 | 45.1-91.3 | 61.4 | 37.1-85.7 | ||
pT2 | 19 | 47 | 14.7-79.3 | 61.5 | 39.2-83.8 | ||
pT3 | 25 | 58.4 | 38.6-78.2 | 61.2 | 41.2-81.2 | ||
pT4 | 2 | 50 | -19.4-119.4 | 50 | -19.4-119.4 | ||
Tumor location | 0.157 | 0.119 | |||||
Upper 1/3 | 27 | 43.1 | 22.7-63.5 | 44.3 | 24.7-63.9 | ||
Middle 1/3 | 26 | 43.2 | 6.16-80.2 | 60 | 39.0-81.0 | ||
Lower 1/3 | 26 | 69.2 | 51.4-87.0 | 68.7 | 50.7-86.7 | ||
LN Number on pre-NAC CT | 0.001 | 0.002 | |||||
≤4 | 34 | 78.4 | 62.7-94.1 | 79.6 | 64.9-94.3 | ||
>4 | 45 | 38.8 | 21.4-56.2 | 47.6 | 32.5-62.7 | ||
Short-axis diameter of MaxLN on pre-NAC CT | 0.240 | 0.125 | |||||
≤9mm | 40 | 58.0 | 38.8-77.2 | 68.1 | 53.0-83.2 | ||
>9mm | 39 | 52.2 | 35.0-69.4 | 53.2 | 36.3-70.1 | ||
Long-axis diameter of MaxLN on pre-NAC CT | 0.050 | 0.022 | |||||
≤15mm | 40 | 60.5 | 40.5-80.5 | 72.1 | 57.2-87.0 | ||
>15mm | 39 | 49.9 | 33.6-66.2 | 49.9 | 33.6-66.2 | ||
LN Number on post-NAC CT | 0.005 | 0.014 | |||||
≤4 | 39 | 73.5 | 58.2-88.8 | 71.8 | 56.9-86.7 | ||
>4 | 40 | 39.2 | 21.0-57.4 | 45.1 | 28.8-61.4 | ||
Short-axis diameter of MaxLN on post-NAC CT | 0.006 | 0.002 | |||||
≤7mm | 40 | 64.3 | 41.2-87.4 | 75.9 | 62.2-89.6 | ||
>7mm | 39 | 43.5 | 27.0-60.0 | 40.6 | 24.3-56.9 | ||
Long-axis diameter of MaxLN on post-NAC CT | 0.055 | 0.025 | |||||
≤12mm | 40 | 59.6 | 38.6-80.6 | 70.0 | 55.1-84.9 | ||
>12mm | 39 | 49.9 | 33.6-66.2 | 46.1 | 29.6-62.6 | ||
LNs analyzed | 0.088 | 0.205 | |||||
≤17 | 42 | 46.2 | 28.0-64.4 | 54.8 | 39.1-70.5 | ||
>17 | 37 | 65.3 | 48.1-82.5 | 67.6 | 51.3-83.9 | ||
NAC scheme=neoadjuvant chemotherapy scheme; TRG=tumor regression grading; cT=clinical T stages; cN=clinical N stages; pT=pathological T stages; LN=lymph node; MaxLN=maximal lymph node.
Although pT was found significant for overall survival, only pT4 patients showed statistically poorer OS than other pT stages when we conducted multiple comparisons among pT stages.
Among all the image characteristics, LN number and long diameter of MaxLN on pre-NAC CT were related to the OS and DFS. On post-NAC CT, both size and number of lymph node were demonstrated as prognostic factors significantly.
Multivariate survival analysis
Multivariate survival analysis, including all statistically significant prognostic factors mentioned in univariate analysis (p value less than or equal to 0.05), was performed to determine the independent prognostic factors for pN0 esophageal squamous cell carcinoma. The pathologic T staging was also included in the analysis. Multivariate analysis by Cox proportional hazard model showed that LN number on pre-NAC CT and LN size on post-NAC CT were most important independent prognostic factors (HR=1.137, 95%CI: 1.041 to 1.240 ; HR=1.083, 95%CI: 1.002 to 1.171) (Table 3). Max LN short diameter was better than long diameter in predicting overall survival.
Table 3: Multivariate analysis of prognostic factors
Prognostic factor | Hazard ratio* | P Value |
|---|---|---|
pT | NA | NA |
LN Number on pre-NAC CT | 1.137(1.041,1.240) | 0.004 |
Long-axis diameter of MaxLN on pre-NAC CT | NA | NA |
LN Number on post-NAC CT | NA | NA |
Short-axis diameter of MaxLN on post-NAC CT | 1.083 (1.002,1.171) | 0.044 |
Long-axis diameter of MaxLN on post-NAC CT | NA | NA |
pT=pathological T stages; LN=lymph node; MaxLN=maximal lymph node.
NA=not applicable; hazard ratio not calculated when P≥0.1.
*Numbers in parentheses are 95% confidence intervals.
Combined criterion for prognosis assessment estimated on CT
We combined these two factors as criterion in order to distinguish the different prognosis for pN0 patients with esophageal squamous cell carcinoma. We chose median values (4 and 7mm) as cutoff points, the patients were divided into two groups. N0b group included patients with LN number>4 on pre-NAC CT or short-axis diameter of MaxLN>7 mm on post-NAC CT and the rest of pN0 patients were included in N0a group (Figure 1). The 1-year, 3-year and 5-year survival rates of the two groups were listed in Table 4. The 5-year survival rate was 75.2% and 32.6% in two group patients respectively, and difference of overall survival time was statistically significant (P<0.001).
Table 4: Survival rates of different groups according to combined criteria
Group | N0a | N0b |
|---|---|---|
N | 50 | 29 |
Mean survival (months) | 95.07 | 54.30 |
1 year survival rate(%) | 100.0 | 89.7 |
Standard error | - | 5.7 |
3 year survival rate(%) | 85.5 | 41.4 |
Standard error | 5.1 | 9.1 |
5 year survival rate(%) | 75.2 | 32.6 |
Standard error | 6.6 | 9.1 |
P value | <0.001 |
N0a group: LN number≦4 on pre-NAC CT and short-axis diameter of MaxLN≦7 mm on post-NAC CT.
N0b group: LN number>4 on pre-NAC CT or short-axis diameter of MaxLN>7 mm on post-NAC CT.
Patients in pN0a group (n=50, median survival time not reached) survived longer (Figure 2). The median survival time of remaining patients in pN0b group (n=29) was only 43 months. Moreover, this indicator derived from two preoperative CT examinations provided satisfactory predictability for prognosis. See Figure 3, Figure 4.
Figure 2: Kaplan-Meier curves of N0a, N0b and pN1 on survival outcomes. (N0a group:LN number≦4 on pre-NAC CT and short-axis diameter of MaxLN≦7 mm on post-NAC CT. N0b group:LN number>4 on pre-NAC CT or short-axis diameter of MaxLN>7 mm on post-NAC CT.).
Figure 3: 58 year-old man with good prognosis of esophageal squamous cell carcinoma. Pre-neoadjuvant chemotherapy CT (a, b) showed MaxLN (arrow): 16x5mm, the number of LN (arrow) was 3. Post-neoadjuvant chemotherapy CT (c, d) showed MaxLN(arrow):13x5mm, the number of LN (arrow) was 3. OS=70.1 months, DFS=70.1 months.
Figure 4: 66 year-old man with poor prognosis of esophageal squamous cell carcinoma. Pre-neoadjuvant chemotherapy CT (a, b) showed MaxLN (arrow): 24x13 mm, the number of LN was 10. Post-neoadjuvant chemotherapy CT (c, d) showed MaxLN (arrow):10x6mm, the number of LN was 9. OS=7.3 months, DFS=5.6 months.
DISCUSSION
Different influence between N0a and N0b
Esophageal cancer staging is changing gradually and has undergone several revisions with the emergence of new prognostic factors. The post-operative pathological stage is widely accepted to be the best prognostic factor. But the prognosis of patients with pN0 staging was not discussed in previous study. According to the data of this study, none of cT, cN and pT staging was very useful prognostic predictor for these patients. Thus, it suggested that more factors should be considered for predicting overall survival as we could not obtain accurate prediction for OS in pN0 patients. In clinical routine follow-up data, some pN0 patients appeared new metastatic lymph nodes after the surgery. The patients’ survival seemed different within all pN0 patients. Screen out this worse prognostic part of pN0 patients may change the treatment plan.
The results of our study suggested that the size and number of lymph nodes on pre- and post-NAC CT may help us to stratify esophageal squamous cell carcinoma patients with pN0 stage into prognostically different groups.
According to the result of survival analysis, we combined the best two factors into a new criterion, which could distinguish N0a and N0b groups. Because of low accuracy of CT for estimating lymph node metastasis [7], some patients without lymph node involvement in N0a group may be overstaging by pre-treatment CT. So, these patients had better prognosis than patients with extensive lymph node metastasis before treatment. But this factor did not influence all the patients in N0a group. In a word, esophageal cancer with better biological behavior indicated the patients had better prognosis. Our findings confirmed the correlation between severity of LN infiltration and characteristics of lymph node on CT, which was selected as one of the biomarkers. On the other hand, some hazards of lymphadenopathy recurrence were involved in N0b group, which made their survival time similar to patients with pN1 staging. For example, the micro-metastasis of lymph node mentioned in recent pathological literatures may be an important hazard [8]. However, normal-sized lymph nodes which contain microscopic metastatic foci cannot be differentiated from nonmetastatic lymph nodes at CT and can lead to understaging [9].
We also compared the OS of pN0b patients with that of pN1 patients in the same study population (Figure 2). OS of these two groups were not different statistically (p=0.801). Thus, the patients in N0b group may need more aggressive treatment after surgery. We thought that the pre- and post-NAC CT imaging could influence treatment strategies of patients with esophageal squamous cell carcinoma, especially for patients with pN0 staging. The management principle of pN1 patients might be fit for pN0b stage patients.
LN size on CT scan as independent prognostic factor
The size of lymph node is always a hot issue in cancer studies. Most studies of gastrointestinal tumors consider nodal size as a criterion for predicting nodal involvement. Lymph nodes of 10 mm or greater on CT have been defined as metastasis in esophageal cancer [10, 11].
For tumor patient, lymph node enlargement is an important feature, which is usually detected on CT examination. The diameter of largest mediastinal lymph nodes is about 12mm in healthy population [12]. In contrast, the largest LN diameter detected on post-NAC CT was 22mm of the pN0 esophageal squamous cell carcinoma patients in this study. It demonstrated that the lymph node enlargement was an important change in cancer patients. So, we inferred that the size of lymph node on CT may reflect the severity of esophageal cancer.
We noticed that the short-axis diameter of the largest lymph node on post-NAC CT was one of the indicators of patient survival. In our previous study, the independent prognostic role of LN size was also proved in patients with other gastroenteric cancer [6].
In clinical oncology, lymph node status is one of the most common findings associated with the biological behavior of cancer. LN size remains the strongest independent predictor of survival in patients with esophageal squamous cancer [13]. Larger lymph nodes are more easily to be seen in patients with more aggressive cancer. Thus, the size of lymph nodes on CT scan can reflect the disease progression and patient survival.
LN number on CT as another predictor of survival
Some pathological studies demonstrate that the number of metastatic lymph nodes is a significant independent survival indicator in esophageal cancer [14, 15]. The AJCC and UICC seventh edition of the staging manual for cancer in the esophagus and esophagogastric junction describes the number of cancer-positive nodes. Several studies have shown that the pN classification by number of LNs is superior to the previous pN classification by the location of the LNs [16–18].
These articles prompted us that LN number on CT could be a prognostic marker, in addition to LN size, in patients with esophageal cancer. In our study, we demonstrate that nodal numbers obtained from pre-NAC CT can be added to the list of prognostic factors for patient survival. In our previous studies, we also discovered that the combined evaluation of these two factors yields a better prognostic prediction than any other factor.
Not all the lymph nodes detected on CT were metastasis in this study. But the pathologic diagnosis of pretreatment lymph node was not available. Although all the patients were diagnosed as pN0 staging after surgery, the number of lymph nodes on post-NAC CT was different obviously. The patients with more lymph nodes on CT images presented poor survival in all pN0 patients. So, it suggests that the number of lymph nodes detected on CT is an indirect feature of the aggressiveness of the tumor. More lymph nodes on CT scans suggest a more adverse prognosis.
Clinical consequences
Patients with locally advanced esophageal squamous cell carcinoma can benefit from neoadjuvant chemotherapy (NAC) or neoadjuvant chemo-radiation therapy (NCRT). The data from FFCD9901 study [19] suggested NCRT increased incidences of complication and mortality. Many surgeons from China and Japan prefer to choose NAC in treating esophageal squamous cell carcinoma. However most scholars in European and US guessed the preoperative chemoradiotherapy proposed by the CROSS trial was the better preoperative combinational plan [20–21]. In our study, the patients of N0b group did not benefit satisfactorily from NAC alone. So the NCRT plan maybe more effective for these patients.
The characteristics of tumor and lymph node on CT scan can be used to observe the biological behavior of esophageal cancer. It is also revealed in patients with pN0 staging. In this study, our results confirmed that the measurement of size and number of lymph nodes on pre-/post-NAC CT could divide the patients into pN0a and pN0b groups with different survival. CT imaging features would provide important guidance and clues for the prediction of pN0 patients’ prognosis. A part of pN0 patients may benefit from the new staging method by CT imaging.
LIMITATIONS
First, this is a single center study with a small sample. Second, most of patients didn’t receive preoperative PET-CT, thus we could not use the result of PET-CT as contrast. Third, we didn’t conduct stratification analysis among different pT stages due to the limited sample size.
In conclusion, the size and number of lymph node measured on pre-/post-NAC is a reliable and important prognostic factor in patients with pN0 esophageal squamous cell carcinoma. Therefore, this new criterion can distinguish the pN0 patients into N0a and N0b, according to the different prognosis. It also makes the LN size and number feasible to assess the extent of malignancy, determine prognosis, and aid in the selection of treatment.
MATERIALS AND METHODS
Patients
A total of 79 consecutive patients were retrospectively enrolled in this study (Figure 1), who had pathologically proven esophageal squamous cell carcinoma with pN0 staging from November 2005 to December 2011. All the patients were collected from the prospective database of Peking University Cancer Hospital for esophageal cancer.
All the patients were administered pre-NAC contrast enhancement chest CT at our institution as routine staging examinations and then received chemotherapy followed by surgical R0 resection. Clinical staging was obtained mainly using enhanced CT images since few patients received endoscopic esophageal ultrasonography or PET/CT. According to the 7th Edition of the UICC-AJCC TNM Classification for Esophageal Cancer [4], patients in this study were all classified as > cT2 and/or cN+. The post-NAC CT was performed to evaluate the response to neoadjuvant therapies. The pathological staging was performed according to the 7th Edition of the UICC-AJCC TNM Classification for Esophageal Cancer [4]. The distribution of cTNM staging, differentiation grade, pathological tumor regression grading (TRG) and number of removed lymph nodes were all listed on Table 1.
Patients were excluded if: a) other pathological types of esophageal cancer than squamous cell carcinoma; b) they underwent other preoperative therapies simultaneously; c) they had history of other malignancy or esophageal multiple primary carcinoma; d) they received R1 or R2 resection; e) they died within 30 days after surgery; or f) enhanced CT images before and after preoperative chemotherapy could not be obtained or interpreted.
In addition, to protect patient privacy, we removed all identifiers from our records at the completion of analyses. The retrospective investigation project has been examined and certified by Ethics Committee of Beijing Cancer Hospital with waiver of the informed consent.
Imaging techniques
All patients received enhanced CT scanning within one week before chemotherapy and within one week before surgery. CT examinations were performed with a 64 row helical CT scanner (General Electrical Medical Systems, Milwaukee, WI, Lightspeed VCT). Scans of the chest were performed in the cranio-caudal direction starting from the neck to the renal hilum level. The scans were started 55 s after intravenous injection of non-ionic contrast material (1.5 ml/kg body weight; Omnipaque 300, GE Healthcare) at a rate of 3 ml/s by a high pressure injector via the antecubital vein. The following scan parameters were used: tube peak voltage 120-140 KV, tube current 300 mAs, collimation thickness 1.25 mm, helical pitch 1.5:1. The original data was post-processed at Advantage Workstation 4.2 Image Workstation (General Electrical Medical Systems, Milwaukee, WI), and the coronal and sagittal images were reconstructed using multiplanar reconstruction (MPR) (thickness 0.625 mm).
CT images were analyzed on a PACS station by two independent radiologists who were blinded to clinical and histopathologic information. The short and long diameters of the largest lymph node were measured on CT scans and were considered as the LN size. The total number of all the visible lymph nodes on CT was considered as the LN number. Any nodule larger than 2 mm was deemed as a lymph node. The average of the two radiologists’ results was used in analysis for short and long diameters. The interpretation of the total number was resolved by consensus if there was discrepancy.
Neoadjuvant chemotherapy and surgery
Platinum-based 2-drug combination, mainly paclitaxel (175 mg/m2, iv, d1 Q21) and cisplatin (25 mg/m2iv, d1-3 Q21) at a 97% (129/133) proportion. The other 4 cases used nedaplatin (80 mg/m2 of body surface area) combined with paclitaxel. Approximately 1-4 neoadjuvant chemotherapy cycles were administered before surgery. Among them, 23, 90, 9, and 11 cases received 1, 2, 3, and 4 cycles, respectively. Surgery was 3-6 weeks after neoadjuvant chemotherapy.
All 133 subjects (pN0 & pN+) underwent radical surgery for ESCC, 114 underwent transthoracic esophagectomy, and 19 underwent transhiatal esophagectomy. Among 114 transthoracic cases, 99 underwent modified Mckeown operation, 10 underwent modified Ivor-Lewis operation, and 5 received trans-left thorax operation (modified Sweet). 111 cases underwent 2-field lymphadenectomy, and 3 underwent 3-field. The number of lymph nodes analyzed was more than six for each patient (Table 1).
Follow-up
The follow-up consisted of outpatient interviews at 3 month intervals for 2 years, then at 6 month intervals for 3 years, and finally at 12 month intervals until death. Disease-free survival (DFS) was measured from the pre-NAC CT examination date until progression at any site, and patients alive and disease free were censored at the last follow-up. Overall survival (OS) was measured from the pre-NAC CT examination date until esophageal cancer-specific death, and patients alive or dead from other causes were censored at the last follow-up. The follow-up was conducted until June in 2015. The median follow-up time was 64.1 months, ranged from 7.3 to 121 months.
Statistical analysis
The following parameters from clinical pathological information and pre-/post-treatment CT were chosen as parameters for survival analysis: patient age (≤59 vs. ≥60 years), sex (male vs. female), tumor location (upper middle and lower), pT staging, LN number on pre-/post-treatment CT, short-axis and long-axis diameter of MaxLN on pre-/post-treatment CT images.
The overall survival rate of the different groups as well as the median survival time and survival curves were achieved by using the Kaplan-Meier method. Overall differences in the survival curves were analyzed with the log-rank test.
The multivariate Cox proportional hazards model was used to adjust for the influence of prognostic factors. All statistical analyses and graphs were performed by using the Statistical Package for Social Sciences Program, version 18.0 (SPSS, Chicago, IL). For all analyses, P values less than .05 was considered to denote a significant difference.
Abbreviations
cT=clinical T staging; pT=pathological T staging; cN=clinical N staging; pN=pathological N staging; LN=lymph node; MaxLN=maximal lymph node; NAC= neoadjuvant chemotherapy; CT=computer tomography; TRG=pathological tumor regression grading; MPR=multiplanar reconstruction; DFS=disease-free survival; OS=overall survival; NCRT=neoadjuvant chemo-radiation therapy.
Author contributions
Ying-Shi Sun designed the study, Yong-Kun Chi and Ying Chen collected patients, retrieved CT images and conducted measurement, Xiao-Ting Li performed statistical analysis, all authors participated in drafting the paper and approved of the final work.
CONFLICTS OF INTEREST
All authors confirm that there are no conflicts of interest to declare.
FUNDING
This work was supported by the National Natural Science Foundation of China (Grant No. 81471640) and Beijing Natural Science Foundation (Grant No. 7172049).
REFERENCES
1. Korst RJ, Altorki NK. Imaging for esophageal tumors. Thorac Surg Clin. 2014; 14: 61–69.
2. Medical Research Council Oesophageal Cancer Working Group. Surgical resection with or without preoperative chemotherapy in oesophageal cancer: a randomised controlled trial. Lancet. 2002; 359: 1727–1733.
3. Lerut T, Coosemans W, Decker G, De Leyn P, Nafteux P, Van Raemdonck D. Cancer of the esophagus and gastro-esophageal junction: potentially curative therapies. Surg Oncol. 2001; 10: 113–122.
4. Edge SB, Byrd DR, Compton CC, Fritz AG, Greene FL, Trotti AI (eds). Esophagus and esophagogastric junction. In: AJCC cancer staging manual, 7th edn. New York: Springer. 2009; pp 103–115.
5. Hong SJ, Kim TJ, Nam KB Lee IS, Yang HC, Cho S, Kim K, Jheon S, Lee KW. New TNM staging system for esophageal cancer: what chest radiologists need to know. RadioGraphics. 2014; 34: 1722–1740.
6. Chi YK, Zhang XP, Li J, Sun YS. To be or not to be: significance of lymph nodes on pretreatment CT in predicting survival of rectal cancer patients. Eur J Radiol. 2011; 77: 473–477.
7. Kalantzis N, Kallimanis G, Laoudi F, Papavasiliou E, Gabriel G. Endoscopic ultrasonography and computed tomography in preoperative (TNM) classification of oesophageal carcinoma [abstr]. Endoscopy. 1992; 24(suppl): 653.
8. Prenzel KL, Hölscher AH, Drebber U, Agavonova M, Gutschow CA, Bollschweiler E. Prognostic impact of nodal micrometastasis in early esophageal cancer. Eur J Surg Oncol. 2012; 38: 314–318.
9. Markowitz A, Gerdes H. Diagnosis and preoperative staging of esophageal cancer. In: Posner MC, Vokes EE, Weichselbaum RR (eds) Cancer of the upper gastrointestinal tract. Lewiston: Decker. 2002; pp 23–46.
10. Dorfman RE, Alpern MB, Gross BH, Sandler MA. Upper abdominal lymph nodes: criteria for normal size determined with CT. Radiology. 1991; 180: 319–322.
11. Fultz PJ, Feins RH, Strang JG, Wandtke JC, Johnstone DW, Watson TJ, Gottlieb RH, Voci SL, Rubens DJ. Detection and diagnosis of nonpalpable supraclavicular lymph nodes in lung cancer at CT and US. Radiology. 2002; 222: 245–251.
12. Glazer GM, Gross HB, Quint LE, Francis IR, Bookstein FL, Orringer MB. Normal mediastinal lymph nodes: number and size according to American Thoracic Society mapping. AJR Am J Roentgenol. 1985; 144: 261–265.
13. Dhar DK, Tachibana M, Kinukawa N, Riruke M, Kohno H, Little AG, Nagasue N. The prognostic significance of lymph node size in patients with squamous esophageal cancer. Ann Surg Oncol. 2002; 9: 1010–1016.
14. Chen J, Xu R, Hunt GC, Krinsky ML, Savides TJ. Influence of the number of malignant regional lymph nodes detected by endoscopic ultrasonography on survival stratification in esophageal adenocarcinoma. Clin Gastroenterol Hepatol. 2006; 4: 573–579.
15. Natsugoe S, Yoshinaka H, Shimada M, Sakamoto F, Morinaga T, Nakano S, Kusano C, Baba M, Takao S, Aikou T. Number of lymph node metastases determined by presurgical ultrasound and endoscopic ultrasound is related to prognosis in patients with esophageal carcinoma. Ann Surg. 2001; 234: 613–618.
16. Talsma K, van Hagen P, Grotenhuis BA. Steyerberg EW, Tilanus HW, van Lanschot JJ, Wijnhoven BP. Comparison of the 6th and 7th editions of the UICC-AJCC TNM classification for esophageal cancer. Ann Surg Oncol. 2012; 19: 2142–2148.
17. Mehta SP, Jose P, Mirza A, Pritchard SA, Hayden JD, Grabsch HI. Comparison of the prognostic value of the 6th and 7th editions of the Union for International Cancer Control TNM staging system in patients with lower esophageal cancer undergoing neoadjuvant chemotherapy followed by surgery. Dis Esophagus. 2013; 26: 182–188.
18. Hsu PK, Wu YC, Chou TY, Huang CS, Hsu WH. Comparison of the 6th and 7th editions of the American Joint Committee on Cancer tumor-node-metastasis staging system in patients with resected esophageal carcinoma. Ann Thorac Surg. 2010; 89: 1024–1031.
19. Mariette C, Dahan L, Mornex F, Maillard E, Thomas PA, Meunier B, Boige V, Pezet D, Robb WB, Le Brun-Ly V, Bosset JF, Mabrut JY, Triboulet JP, et al. Surgery alone versus chemoradiotherapy followed by surgery for stage I and II esophageal cancer: final analysis of randomized controlled phase III trial FFCD 9901. J Clin Oncol. 2014; 32: 2416–2422.
20. van Hagen P, Hulshof MC, van Lanschot JJ, Steyerberg EW, van Berge Henegouwen MI, Wijnhoven BP, Richel DJ, Nieuwenhuijzen GA, Hospers GA, Bonenkamp JJ, Cuesta MA, Blaisse RJ, Busch OR, et al. Preoperative chemoradiotherapy for esophageal or junctional cancer. N Engl J Med. 2012; 366: 2074-2084.
21. Oppedijk V, van der Gaast A, van Lanschot JJ, van Hagen P, van Os R, van Rij CM, van der Sangen MJ, Beukema JC, Rütten H, Spruit PH, Reinders JG, Richel DJ, van Berge Henegouwen MI, et al. Patterns of recurrence after surgery alone versus preoperative chemoradiotherapy and surgery in the CROSS trials. J Clin Oncol. 2014; 32: 385-391.
