Introduction
Generally, additional total mesenteric excision
(TME) is recommended for the treatment of pathological T2 lower
rectal cancer after local excision (LE) because the high risk for
local recurrence (LR) persists even if LE was performed curatively
(1). Although TME is the gold
standard procedure for lower rectal cancer, this procedure is
associated with complications such as sexual, urinary, or anal
dysfunction, and with temporary or permanent stoma. In particular,
anal dysfunction and stoma can affect patients' quality of life
(2,3)
and are serious problems for the elderly and those who desire anal
preservation. Recently, combination treatment of postoperative
chemoradiotherapy (CRT) after LE for T1/T2 rectal cancer has become
one optional treatment in the National Comprehensive Cancer Network
guidelines (4), and several studies
have shown good oncological outcomes and excellent anal function
compared to TME, particularly in T1 rectal cancer (5-8).
However, a few studies on long-term patient outcomes in T2 rectal
cancer showed LE to have a higher LR rate than TME (5,7,8). Hence, when undertaking postoperative
CRT after LE in T2 rectal cancer, it is necessary to select
patients with a low risk of recurrence, and in particular it is
useful to select patients with a low risk of lymph node metastasis
(LNM) (9-11).
Although some reports showed risk factors of nodal involvement in
T2 colorectal cancer (9-13),
a few reports limited to lower rectal cancer had indications for
LE. The aim of this study was to evaluate the risk factors of nodal
involvement with updated parameters in T2 lower rectal cancer and
to select patients with low risk of LNM.
Materials and methods
Study design and patient
characteristics
This is a retrospective cohort study at Osaka
International Cancer Institute. The study protocol was approved by
the institutional review board (No. 18033-2). Written informed
consent was waived because of the retrospective design. We
collected specimens from 95 consecutive patients with pathological
T2 lower rectal adenocarcinoma who underwent R0 resection by TME or
TSME (14) between January 2008 and
December 2018 (Table I). Exclusion
criteria were recurrent carcinoma, multiple carcinoma, stage IV,
and preoperative chemotherapy or radiotherapy. To evaluate rectal
cancer which has indication for LE, we picked up rectal cancer
located within 10 cm from the anal verge as lower rectal
cancer.
 | Table IClinicopathological
characteristics. |
Table I
Clinicopathological
characteristics.
| Characteristics | All patients
(n=95) |
|---|
| Age, years
(range) | 70 (33-84) |
| Sex (male:female),
n | 59:36 |
| Distance of tumor
from AV, cm | |
|
10>X>5 | 51 |
|
5≥X | 44 |
| pN0/pN1, n | 69/26 |
| Lateral pelvic lymph
node metastasis, n | 2 |
| pStage I/IIIA/IIIB,
n | 69/21/5 |
| Recurrence, n | 14 |
| 3-year RFS, % | 84.9 |
Surgical procedure
TME/TSME was performed with D3 dissection (15). Bilateral lateral pelvic lymph node
dissection was performed after TME/TSME for clinical T3 tumors.
Pathology evaluation
After formalin fixation, more than two pathologists
cut the rectum and lymph nodes along the long axis, and performed
microscopic examinations of hematoxylin and eosin stained
specimens. A pathologist (M.K) who was blind to the clinical
information reviewed all tumors on silane-coated glass slides.
Clinicopathological data are shown in Table II. A desmoplastic reaction (DR) was
defined as a fibrotic stromal response in cancer development and was
divided into three groups: Mature, when the stroma was composed of
mature collagen fibers; intermediate, when keloid-like collagen was
intermingled with mature fibers; and immature, consisting of a
myxoid stroma that included no mature fibers (16). To evaluate the association between
LNM and the extent of tumor invasion in the muscularis propria (MP)
layer, the depth/width of tumor invasion into the MP layer were
measured, and the tumor rate of invasion into MP layer was
calculated by dividing the length of tumor invasion into the MP
layer by the thickness of the MP layer.
| Table IIUnivariate analysis for factors
associated with lymph node metastasis. |
Table II
Univariate analysis for factors
associated with lymph node metastasis.
| | LN negative,
(n=69) | LN positive
(n=26) | |
|---|
| Factors | Number | % | Number | % | P-value |
|---|
| Age, years | | | | | 0.246 |
|
<65 | 28 | 66.6 | 14 | 33.4 | |
|
≥65 | 41 | 77.3 | 12 | 22.7 | |
| Sex | | | | | 0.622 |
|
Male | 44 | 74.6 | 15 | 25.4 | |
|
Female | 25 | 69.4 | 11 | 30.6 | |
| AV, cm | | | | | 0.934 |
|
≥5 | 46 | 71.9 | 18 | 28.1 | |
|
<5 | 23 | 74.2 | 8 | 25.9 | |
| Morphology | | | | | 0.692 |
|
Polypoid | 13 | 76.5 | 4 | 23.5 | |
|
Non-polypoid | 56 | 71.8 | 22 | 28.2 | |
| Size, mm | | | | | 0.117 |
|
≥23 | 62 | 75.6 | 20 | 24.4 | |
|
<23 | 7 | 53.8 | 6 | 46.2 | |
| Histology | | | | | 0.083 |
|
Well-differentiated | 23 | 33.3 | 4 | 15.4 | |
|
Others | 46 | 66.7 | 22 | 84.6 | |
| Lymphovascular
invasion | | | | | 0.008 |
|
Negative | 25 | 89.3 | 3 | 10.7 | |
|
Positive | 44 | 65.7 | 23 | 34.3 | |
| Tumor budding | | | | | 0.012 |
|
Grade 1 | 61 | 78.2 | 17 | 21.8 | |
|
Grade
2/3 | 8 | 47.1 | 9 | 52.9 | |
| Perineural
invasion | | | | | 0.175 |
|
Negative | 63 | 75.0 | 21 | 25.0 | |
|
Positive | 6 | 54.5 | 5 | 45.5 | |
| Desmoplastic
reaction | | | | | 0.211 |
|
Mature | 28 | 80.0 | 7 | 20.0 | |
|
Intermediate/immature | 41 | 68.3 | 19 | 31.7 | |
| Depth of invasion
into MP layer, mm | | | | | 0.854 |
|
<2 | 28 | 73.7 | 10 | 26.3 | |
|
≥2 | 41 | 71.9 | 16 | 28.1 | |
| Width of invasion
into MP layer, mm | | | | | 0.122 |
|
<12 | 38 | 66.7 | 19 | 33.3 | |
|
≥12 | 30 | 81.1 | 7 | 18.9 | |
| Rate of invasion
into MP layer, % | | | | | 0.247 |
|
<80 | 64 | 74.4 | 22 | 25.6 | |
|
≥80 | 5 | 55.6 | 4 | 44.4 | |
Statistical analysis
The parameters of tumor size, depth of tumor
invasion into the MP layer, width of tumor invasion into the MP
layer, and rate of invasion into the MP were evaluated by receiver
operating characteristic (ROC) curves using the area under the
curve (AUC) to determine the optimal cut-off value.The associations
between LNM and these parameters were analyzed with the
χ2 test. Variables with a P-value <0.2 in a
univariate analysis were further evaluated in a multivariate
logistic model. Three-year-relapse free survival was determined
using the Kaplan-Meier method. Values of P<0.05 were considered
statistically significant. Statistical analyses were performed
using JMP version 8.0.2 software (SAS Institute, Cary, NC).
Results
Clinicopathological
characteristics
The demographic and pathological characteristics of
patients are provided in Table I.
The median follow-up duration was 37.4 months (range 1.0-120.1).
LNM was confirmed in 26 patients (27%), including 2 patients (2%)
with lateral pelvic lymph node metastasis. Fourteen patients
developed recurrence, of whom 5 had local recurrence, 6 had distant
metastases and 3 had both local and distant metastases.
Parameters and associations between
parameters and LNM
The AUC for LNM and cut-off values for tumor size
and depth, width, and rate of invasion into the MP layer were 0.61
and 23 mm, 0.51 and 2 mm, 0.55 and 12 mm, and 0.49 and 80%,
respectively. Univariate analyses of the association between these
parameters and LNM are represented in Table II. LVI (P=0.008), and tumor budding
(P=0.012) were significantly related to LNM, and a possible
association between LMN and histology other than
well-differentiated adenocarcinoma was indicated (P=0.083);
however, there were no relationships between LNM and these updated
parameters, such as depth, width, and rate of invasion into the MP
layer, based on the ROC curves and the AUC values and also state
(data not shown).
Risk factors for LNM
Multivariate analysis revealed that LVI (P=0.03) was
an independent risk factor for LNM. Histology also showed a
tendency toward being a risk factor, but there was no significant
difference (P=0.07) (Table III).
Table IV shows the rate of LNM in
relation to these risk factors of LVI, tumor budding, and
histological type. LNM was confirmed in 9 patients (9/13, 69.2%)
with three risk factors, in 10 patients (10/39, 29.6%) with two
risk factors, and in 7 patients (7.34, 20.6%) with one risk factor.
LNM was not confirmed in any patients lacking all 3 risk factors
(0/9).
| Table IIIMultivariate analysis for factors
associated with lymph node metastasis. |
Table III
Multivariate analysis for factors
associated with lymph node metastasis.
| Variables | OR | 95% CI | P-value |
|---|
| Size (≥23) | 0.42 | 0.10-1.81 | 0.24 |
| Histology | 2.95 | 0.89-11.90 | 0.07 |
| Lymphovascular
invasion | 4.00 | 1.13-19.10 | 0.03 |
| Tumor budding | 1.99 | 0.49-7.93 | 0.32 |
| Perineural
invasion | 1.16 | 0.24-5.18 | 0.84 |
| Length of invasion
in MP | 0.47 | 0.15-1.36 | 0.17 |
| Table IVRate of LNM depending on risk
factors. |
Table IV
Rate of LNM depending on risk
factors.
| Number of risk
factors | Patients, n | LNM patients,
n | Rate of LNM, % |
|---|
| 3 | 13 | 9 | 69.2 |
| 2 | 39 | 10 | 25.6 |
| 1 | 34 | 7 | 20.6 |
| 0 | 9 | 0 | 0 |
Discussion
This study investigated the relationship between LNM
and clinicopathological parameters in T2 lower rectal cancer for
select patients with a low risk of LNM, and revealed LVI, tumor
budding, and histology other than well-differentiated
adenocarcinoma were risk factors for LNM. The values of our study
are limited to lower rectal cancer, which had indications for LE,
and evaluating updated parameters such as DR, tumor budding,
perineural invasion, and the extent of tumor invasion into the MP
(9,12,17,18).
This paper showed that LVI was an independent risk
factor for LNM in T2 lower rectal cancer by multivariate analysis.
In addition, LVI and tumor budding were risk factors and
histological type was likely to be a risk factor for LNM in T2
lower rectal cancer by univariate analysis. These results were
similar to a previous study by Kobayashi et al (11) published in 2010, which showed
biological sex, histology other than well-differentiated
adenocarcinoma, and lymphatic invasion as risk factors for LNM in
lower rectal cancer in a large retrospective multi-institutional
study. Kobayashi et al (11)
showed that the LNM rate in T2 patients was 9.1% without lymphatic
invasion; however, our data revealed no patients (0/9) without
unfavorable pathological features who had risk of LNM (Table IV), even though the number was small
by univariate analysis. Hence, we considered these risk factors may
be more valuable indicators to select an LNM-negative patient
group. Similar to previous reports (9-11,16-18),
the present study also included clinical LNM-positive patients. If
they are excluded on CT or MRI in clinical practice, patients with
favorable pathological features are expected to have a lower risk
of LNM. In general, a poorly differentiated component was
recognized as one of the risk factors for LNM (9,10,17,19,20).
However, the present study included only 2% of poorly
differentiated adenocarcinoma; therefore, we did not statistically
analyze this risk factor. Table V
showed some risk factors published in previous reports, including
updated data such as the extent of tumor invasion into the MP
(12,17,18), DR
(9), and perineural invasion
(10). However, in our study these
factors did not show statistically significant differences.
| Table VLiterature reports about the risk
factors for lymph node metastasis in colorectal cancer. |
Table V
Literature reports about the risk
factors for lymph node metastasis in colorectal cancer.
| Author, year | Location | T1 | T2 | Risk factors in
T2 | (Refs.) |
|---|
| Kajiwara et
al, 2010 | Colorectal | - | 244 | Female, LVI, tumor
budding, poorly differentiated component, myxoid cancer stroma,
extent of tumor invasion in MP | (9) |
| Masaki et
al, 2005 | Rectum | - | 72 | Female, tumor
budding | (13) |
| Kobayashi et
al, 2010 | Lower rectum | 233 | 334 | Female, lymphatic
invasion, histological type | (11) |
| Tong et al,
2011 | Colorectal | - | 317 | LVI, extent of
tumor invasion in MP | (17) |
| Ding et al,
2011 | Rectum | - | 346 | Age, location,
extent of tumor invasion in MP, histological type | (18) |
| Chang et al,
2012 | Rectum | 264 | 679 | LVI, histological
type, morphology, perineural invasion, desmoplasia (T1/T2), | (10) |
| Saraste et
al, 2013 | Rectum | 205 | 472 | LVI, histological
type (T1/T2) | (19) |
| He et al,
2015 | Rectum | 113 | 463 | Histological type,
extent of tumor invasion in MP, CA19-9, ulcerative mass,
(T1/T2) | (12) |
| Yoshida et
al, 2018 | Colorectal | 202 | 115 | Location, tumor
size, lymphatic invasion, histological type | (20) |
| Present study,
2019 | Lower rectum | - | 95 | LVI, tumor budding,
histological type | - |
Garcia-Aguilar et al (1) showed a high LR rate (37%, n=27) by LE
alone, even if the study involved patients with good pathological
features (i.e., without LVI and mucinous component and with R0
resection). They indicated additional CRT should be adopted to
control LR. Some recent reports have shown a high LR rate even
after LE and CRT (5,7,8).
Greenberg et al (8) showed
18% LR rate (n=51) that included patients with unfavorable
pathological features who were clinical LNM positive. Rackley et
al (5) showed a 22% LR rate
(n=42) that included patients with unfavorable pathological
features, positive margin, and unevaluable margin after LE,
although patients that were clinically LNM positive were excluded.
Considering these findings, to perform LE and CRT for T2 lower
rectal cancer with a good oncologic outcome, it is necessary to
select patients with at least good pathological features and R0
local resection by LE, and without clinical LNM.
Some limitations must be considered when
interpreting the results of this study. First, this study was a
single-institute, retrospective analysis. Second, because this
study was small, we chose the histological type as a marginally
significant risk factor that showed P<0.1 in univariate
analysis, in addition to the two other factors, and we analyzed the
rate of LNM with the risk factors calculated by univariate analysis
(Table IV). Third, this study
showed the risk factors for LNM with specimens after TME. When
adopting these risk factors for LE, we should recognize that
pathological evaluation may become insufficient, for example due to
heat degeneration around the tumor. Fourth, in the clinical
setting, we have to perform local excision instead of biopsy to
obtain information about the risk factors such as LV1 and tumor
budding.
In conclusion, our study showed LVI, tumor budding,
and histological type can be risk factors for LNM in lower rectal
cancer. When performing LE and CRT for T2 rectal cancer based on
risk factors, a large prospective multicenter study should be
conducted.
Acknowledgements
Not applicable.
Funding
No funding was received.
Availability of date and materials
The datasets used and/or analyzed during the present
study are available from the corresponding author on reasonable
request.
Authors' contributions
HU, MO, MY and ST conceived and designed the present
study. HU and MO wrote the manuscript. MK and SN were responsible
for the pathological examination. NH, JN, MY, HW, HT, TO and HM
performed follow-up and collected the data. MY and ST revised the
manuscript critically for important intellectual content. All
authors read and approved the final manuscript.
Ethics approval and consent to
participate
This was a retrospective cohort study at Osaka
International Cancer Institute. The study protocol was approved by
the Institutional Review Board of the Osaka International Cancer
Institute (approval no. 18033).
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing
interests.
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