Introduction
Endoscopic full-thickness resection (EFTR) [1]
[2] and laparoscopic and endoscopic cooperative surgery (LECS) [3] are used to avoid excessive resection of the gastric wall and subsequent postoperative
complications, such as stenosis or deformity. In these procedures, the tumor can be
confirmed endoscopically to determine the appropriate resection line. However, the
techniques also have some disadvantages, namely loss of endoscopic view caused by
stomach collapse, and peritoneal infection or tumor dissemination due to outflow of
gastric juice.
A combination of laparoscopic and endoscopic approaches to neoplasia with non-exposure
technique (CLEAN-NET) [4] and non-exposed endoscopic wall-inversion surgery (NEWS) [5] have recently been devised as a procedure for local resection that does not expose
the intragastric space. These procedures are characterized by a circumferential seromuscular
incision made from outside the stomach under the guidance of either submucosal dye
injection or intragastric navigation; that is, use of the endoscope to push against
the gastric wall. We considered that it is important to resect the tumor from inside
of the stomach while confirming the location of the tumor endoscopically.
Thus, we have devised a new technique, called sealed EFTR, whereby the serosa of the
stomach is sealed using a silicone sheet to prevent stomach collapse and outflow of
gastric juice.
Materials and methods
In an ex vivo experiment, three whole stomachs harvested from slaughtered pigs were
used. After washing with water and 20,000 units of pronase, each stomach was set on
an endoscopic submucosal dissection (ESD) training model.
First, markings were made around a virtual lesion using a HookKnife (KD-620; Olympus,
Tokyo, Japan) in swift coagulation mode (effect 4;40 W). The knife was powered using
a VIO300 D electrosurgical unit (ERBE; Tubingen, Germany). Next, 0.9 % saline with
indigo carmine was injected into the submucosa around the markings. A circumferential
mucosal – submucosal incision was then made using the HookKnife in dry cut mode (effect
4; 60 W) in a manner similar to ESD ([Fig. 1a]). Four marks were made on the incision line of the serosa from inside of the stomach
using the HookKnife in coagulation mode ([Fig. 1b]). A silicone sheet 5 cm in diameter and several types of gauze 8 to 10 cm in diameter
were placed on the serosa to cover the marks. These were then pasted using a fibrinogen – thrombin
solution ([Fig. 2a]). Because a silicone sheet could not be directly adhered to the serosa, a gauze
was overlapped and pasted. To cover the silicone sheet, one layer of gauze, four layers
of gauze or non-woven gauze were used. Finally, a seromuscular incision was made using
the HookKnife in dry cut mode ([Fig. 1e], [Fig. 2b], [Fig. 2c]).
Fig. 1 Procedure of sealed EFTR. a Circumferential mucosal incision — performed deeply and evenly to achieve exposure
of muscular layer. b Marks on serosa placed on incision line using HookKnife. c Ligation of silicone and polyglycolic acid (PGA) sheets to the serosa of lesion,
with the center of silicone sheet at the center of the serosa marks. d Pasting of silicone and PGA sheets to the serosa using fibrinogen-thrombin solution.
e Dissection of seromuscular layer; simultaneous confirmation of mucosal marks.
Fig. 2 Sealed EFTR using non-woven gauze (ex vivo experiment). a Pasting of silicone sheet and gauze to the serosa using fibrinogen-thrombin solution.
b, c Confirmation of each stomach layer and layer-by-layer incision. d, e Maintenance of the stomach in expanded state even after all-layer incision. f, g Resected specimen (f, mucosal side; g, serosal side).
In this experiment, we examined whether it is possible to resect the virtual lesion
from inside the stomach while keeping the lumen of the stomach expanded. In other
words, we confirmed whether the silicone sheet could be adhered to the serosa with
fibrinogen-thrombin solution; the sheet was not peeled off by endoscopic forceps manipulation
or by expansion or contraction of the stomach; and whether the lumen of the stomach
could be maintained in an expanded state after perforation.
After verifying the feasibility of our new technique in an ex vivo model, we conducted
in vivo experiment. In the in vivo experiment, polyglycolic acid (PGA) sheet (Neoveil;
Gunze, Tokyo, Japan) was used instead of non-woven gauze.
In the in vivo experiment, four domestic pigs (30 – 40 kg) were used for the new sealed
EFTR method and three were used for the conventional LA-EFTR method. All procedures
were performed under general anesthesia and the animals were sacrificed in a painless
manner.
Under general anesthesia, a laparoscope was inserted via an incision in the umbilical
region to observe the abdominal cavity. Four trocars were placed in the left upper,
left middle, right upper, and right middle abdomen, respectively. The stomach was
cut free of the lesser and greater omenta using laparoscopic coagulation shears (SonoSurg;
Olympus, Tokyo, Japan). Virtual lesions measuring 2 to 3 cm in diameter were created
in various positions of the stomach.
In the same manner as the ex vivo experiments, markings were made around the virtual
lesions; saline with a small amount of indigo carmine was then injected locally into
the
submucosal layer, and a circumferential mucosal incision was performed using the HookKnife
([Fig. 1a], [Fig. 3a]). The incision was then deepened until the muscular layer was exposed. As far as
possible, it was made to an even depth throughout the circumference. The marks were
placed without perforation at four points on the incision line of the serosa from
inside the stomach using the HookKnife in coagulation mode ([Fig. 1b], [Fig. 3b]).
Fig. 3 Sealed EFTR (in vivo experiment). a Circumferential mucosal incision—performed deeply and evenly to achieve exposure
of muscular layer. b Marks on serosa (arrowhead) placed on incision line. c Ligation of silicone and polyglycolic acid (PGA) sheets to the serosa of lesion,
with the center of silicone sheet at the center (arrow) of the serosa marks (arrow
head). d Pasting of silicone and PGA sheets to the serosa using fibrinogen – thrombin solution.
e Dissection of seromuscular layer; simultaneous confirmation of mucosal marks. f Maintenance of good endoscopic view after removal of resected specimen. g Laparoscopic closure of defect in the gastric wall. h, i Resected specimen (h, mucosal side; i, serosal side).
Subsequently, a silicone sheet and PGA sheet were ligated to the serosa so that the
center of the silicone sheet matched the center of the serosal marks ([Fig. 1c], [Fig. 3c]). The silicone and PGA sheets had been ligated beforehand to ensure their centers
matched. Next, these sheets were pasted using a fibrinogen – thrombin solution ([Fig. 1 d], [Fig. 3d]). Specifically, the sheet was pasted to the serosa several minutes after the solution
was sprayed so that it resembled a gel film.
Seromuscular dissection was then performed using a HookKnife and/or ITknife2 (KD-611L;
Olympus, Tokyo, Japan). Specifically, a small hole was made on the incision line using
the HookKnife, and the tip of the knife was inserted into the hole. The seromuscular
layer was dissected using the HookKnife while confirming the presence of the mucosal
marks around the lesion ([Fig. 1e], [Fig. 3e]).
After circumferential seromuscular dissection, the lesion was only attached by the
thread with which the silicone sheet was ligated. The thread was cut using the HookKnife,
and the resected specimen was removed through the oral cavity. The silicone and PGA
sheets were peeled off the serosa using laparoscopic forceps and removed through the
oral cavity. At that time, the stomach was kept elevated using laparoscopic forceps
so that no gastric juice flowed into the abdominal cavity. Finally, the gastric wall
defect was closed laparoscopically using hand-sewn sutures ([Fig. 3 g]).
In the experiment using the conventional method, after circumferential mucosal and
submucosal incision, the serosa was incised under counter-traction provided by gripping
the gastric wall with laparoscopic grasping forceps [6].
We compared resection time, stomach collapse, confirmation of the lesion and quality
of endoscopic view between our new sealed EFTR technique and conventional LA-EFTR
by using counter-traction with laparoscopic forceps or threads. Time for incision
was measured separately from time for mucosal incision, time for sealing (from ligation
the silicone sheet and PGA sheet to the serosa to adhesion them using fibrinogen-thrombin
solution) and time for seromuscular incision. Stomach collapse and quality of endoscopic
view were evaluated based on whether the lumen could be maintained in an expanded
state and whether lesion, marks and incision line could always be confirmed. When
the lumen of the stomach was kept open and the lesion could be confirmed only with
a simple endoscopic manipulation, confirmation of lesion is defined as "possible and
easy" and quality of endoscopic view was defined as "good". Quality of the endoscopic
view was defined as "not good" when the stomach collapsed and the lesion could not
be confirmed only by endoscopic manipulation. In that case, if the lesion could be
recognized by sufficient air supply or laparoscopic assistance, the confirmation of
lesion was defined as "possible, but difficult," and if the lesion could not be recognized
even by laparoscopic assistance, it was termed "impossible." Data were analyzed using
t-test. Probability values less than 0.05 were considered statistically significant.
The animal procedures were approved by the ethics committee of the Japan Consortium
for Advances in Surgical Endoscopy.
Results
Ex vivo experiment
To seal the serosa, one layer of gauze, four layers of gauze, or non-woven gauze were
used in duplicate. In all cases, the gauze was stuck to the serosa within approximately
5 minutes and was never peeled off by endoscopic forceps manipulation or by expansion
or contraction of the stomach.
In cases that were sealed using one layer of gauze, incision in the serosa caused
air outflow and
subsequent stomach collapse. The stomach was expanded by the air supply, but it could
not
maintain the expanded state, and it was therefore difficult to incise the seromuscular
layer. In cases that were sealed using four layers of gauze, air leakage was prevented
more effectively and stomach collapse was suppressed. The lumen of the stomach was
expanded by air supply with the endoscope, and the lesion could be confirmed. It was
possible to incise the seromuscular layer while confirming the lesion. In cases that
were sealed using non-woven gauze, the air outflow was prevented and the stomach did
not collapse. It was possible to confirm the layers and incise the seromuscular layer
more easily and rapidly, with a better endoscopic view ([Fig. 2b], [Fig. 2c], [Fig. 2 d], [Fig. 2e]).
The silicone sheet was not incised during seromuscular dissection with the HookKnife.
Because there was a silicone sheet between the serosa and the gauze, it was possible
to operate the HookKnife without breaking the gauze.
Furthermore, it was possible to resect specimens of almost identical sizes on the
mucosal (mean specimen size: 40 × 38 mm) and serosal sides (mean specimen size: 38 × 37 mm)
([Fig. 2f], [Fig. 2 g]).
In vivo examination
Eight lesions, excluding that of the angle lesser curvature, were completely resected
from inside the stomach using the ITknife2 and/or the HookKnife, without laparoscopic
assistance. The silicone sheet and gauze could not be adhered to the angle lesser
curvature, so tumor resection was therefore impossible. During the endoscopic procedure,
the lumen of the stomach was kept open and a good endoscopic view was maintained ([Fig. 3e], [Fig. 3f]). It was possible to dissect the seromuscular layer while confirming the mucosal
marks around the lesion ([Fig. 3e]). The sizes of the mucosa and serosa in the resected specimen were almost the same,
measuring 35 × 33 mm and 33 × 30 mm, respectively ([Fig. 3 h], [Fig. 3i]).
Mean time required for seromuscular incision with the sealed EFTR method was significantly
shorter than that with the conventional method (10.5 minutes ± 3.7 vs. 27.0 minutes ± 3.2, P < 0.01) ([Table 1] and [Table 2]).
Table 1
Summary of sealed EFTR in vivo experiment.
|
Case
|
Position
|
Resection
|
Time for incision (min)
|
Size of resected specimen (mm)
|
|
Mucosal incision
|
Sealing
|
Seromuscular incision
|
Mucosal side
|
Serosal side
|
|
1
|
M ant.
|
Success
|
12
|
13
|
12
|
29 × 27
|
25 × 22
|
|
2
|
M GC
|
Success
|
15
|
19
|
6
|
32 × 30
|
27 × 26
|
|
3
|
M ant.
|
Success
|
25
|
19
|
10
|
37 × 34
|
35 × 32
|
|
4
|
U ant.
|
Success
|
20
|
30
|
16
|
36 × 33
|
35 × 30
|
|
5
|
M post.
|
Success
|
16
|
32
|
6
|
34 × 32
|
32 × 29
|
|
6
|
U GC
|
Success
|
22
|
29
|
15
|
34 × 33
|
34 × 28
|
|
7
|
L ant.
|
Success
|
17
|
17
|
7
|
39 × 37
|
35 × 35
|
|
8
|
M LC
|
Failure
|
|
|
|
|
|
|
9
|
U post.
|
Success
|
33
|
35
|
12
|
37 × 35
|
38 × 34
|
|
|
Average
|
|
20.0
|
24.3
|
10.5
|
34.5 × 32.6
|
32.6 × 29.5
|
EFTR, endoscopic full-thickness resection; L, lower; M, middle; U, upper; GC, greater
curve; LC, lesser curve; ant., anterior wall; post., posterior wall
Table 2
Comparison of serosa sealing method and the conventional method.
|
|
Sealed EFTR
|
Conventional method
|
P value
|
|
|
(n = 8)
|
(n = 6)
|
|
|
Time for resection (min)
|
|
|
(Average)
|
54.8 ± 14.2
|
42.0 ± 3.7
|
0.07
|
|
(Range)
|
(37 – 80 )
|
(38 – 48)
|
|
|
|
20.0 ± 6.2
|
15.0 ± 3.8
|
0.11
|
|
|
(12 – 33 )
|
(10 – 22)
|
|
|
|
|
24.3 ± 7.6
|
–
|
|
|
|
(13 – 35)
|
|
|
|
|
10.5 ± 3.7
|
27.0 ± 3.2
|
< 0.01
|
|
|
(6 – 15)
|
(22 – 32)
|
|
|
Stomach collapse
|
(–)
|
(+)
|
|
|
Quality of endoscopic view
|
Good
|
Not good
|
|
|
Confirmation of the lesion
|
Possible and easy
|
Possible, but difficult
|
|
EFTR, endoscopic full-thickness resection
Using the conventional method, it took a mean of 27 minutes to incise the seromuscular
layer because of poor endoscopic view and poor operability caused by interference
of the endoscope and the laparoscopic forceps ([Table 2]). Confirmation of the lesion was possible but difficult, because it was necessary
to provide air supply and laparoscopic assistance. With the sealed EFTR method, it
was possible to smoothly incise the seromuscular layer of the stomach under good endoscopic
view, since air outflow was suppressed and there was no interference of the endoscope
and the laparoscopic forceps.
When the lesions were in the upper region or on the posterior wall, it took more time
to seal the serosa than when they were in the middle or lower regions or on the anterior
wall ([Table 1]).
Discussion
EFTR was developed as a minimally invasive endoluminal surgery to treat gastrointestinal
tumors (GISTs). It is a flexible endoscopic technique that can be used to excise all
layers of the gastric wall while confirming the lesion from inside the stomach. Furthermore,
it allows resection, with minimal surgical margin, of lesions that have penetrated
into the deeper layers of the stomach wall [1]
[2].
LECS was also developed as a minimally invasive surgery to treat gastric submucosal
tumors [3]. In this method, resection of the tumor and closure of the defect are performed
simultaneously using a laparoscopic linear stapler after endoscopic full-thickness
incision covering approximately three-quarters of the defect circumference. Thus,
LECS is thought to be more convenient and has gradually become accepted in Japan [3].
However, these methods create a hole in the gastric wall from which the stomach contents
may flow into the abdominal space. For this reason, they may cause infection or tumor
dissemination into the abdominal space [4]
[5]. Therefore, indications for these methods should be determined carefully in cases
of GISTs with ulceration or epithelial tumors. Indeed, CLEAN-NET [4] and NEWS [5] were developed to avoid exposing the intragastric space in such cases. In these
methods, a circumferential seromuscular incision is made from outside the stomach
under the guidance of submucosal dye injection. Therefore, it is difficult to confirm
the location of the tumor during incision. We considered that it is important to resect
the tumor while confirming tumor location.
To avoid tumor dissemination and ensure resection of the full layer with an optimal
surgical margin, we developed a new method of EFTR in which the serosa is sealed by
a silicone sheet using a fibrinogen – thrombin solution. In the current study, we
explored the feasibility of our new technique in an ex vivo and in vivo porcine model
Using this method, we suppressed outflow of air and gastric juices by adhering a silicone
sheet to the serosa. In this way, we ensured a good endoscopic view while preventing
intraperitoneal infection or dissemination.
During circumferential incision, the submucosal layer must be incised deeply and evenly
to expose the muscular layer. Therefore, compared with the conventional method, it
took more time to carry out circumferential incision of the mucosal and submucosal
layer using our new method. It also took more time to seal the serosa. However, it
was possible to incise the seromuscular layer while confirming the lesion with good
endoscopic view in a shorter time than with the conventional method.
After resection of the tumor using our new technique, the gastric lumen is temporarily
released to allow the sheet to be retrieved. Because the tumor has already been removed
at this point, risk of dissemination is low. Nonetheless, gastric juice must be prevented
from escaping; to that end, the stomach wall is pulled using laparoscopic forceps.
In clinical cases, intraperitoneal lavage must be performed after closure of the stomach
wall.
Ikehara et al. [7] reported that there was no peritoneal dissemination in 90 cases of endoscopic resection-related
perforation and concluded that peritoneal dissemination was unlikely to occur after
perforation during endoscopic resection. Although there are some reports of peritoneal
dissemination after endoscopic resection-related perforation, it is presumed that
they occurred due to inappropriate manipulation [8]
[9]. In the report of submucosa-infiltrating gastric cancer of peritoneal seeding after
ESD perforation, it was reported that the tumor was adhered to the omentum because
it was closed with an endoscopic clip while leaving the tumor after perforation and
the operation was performed later [8]. In a report of peritoneal dissemination after laparoscopic partial resection of
duodenal cancer, it was reported that the abdominal cavity came into contact with
the resected specimen [9]. If the tumor is properly manipulated so as not to come into contact with the peritoneal
cavity, peritoneal dissemination after perforation is unlikely to occur, as reported
by Ikehara et al [7].
Fibrinogen-thrombin solution, which consists of biological components, was used to
avoid damage of the serosa, when the silicone sheet was adhered to the serosa. Silicone
sheets cannot be directly adhered to the serosa, but they can be adhered using overlapping
non-woven gauze. The silicone sheet and gauze were never peeled off by endoscopic
forceps manipulation or by expansion or contraction of the stomach. However, they
could be easily peeled from the serosa using laparoscopic forceps. Moreover, because
the silicone sheet is not directly adhered to the serosa, the HookKnife can be moved
around, allowing sliding during the serosal incision.
Submucosal gastric cancer negative for sentinel lymph nodes may be considered one
indication for this method. Indeed, because submucosal gastric cancer is often associated
with lymph node metastasis, gastrectomy with prophylactic regional lymphadenectomy
is usually conducted, according to the guidelines of the Japanese Gastric Cancer Association
[10]. However, reported incidence of lymph node metastasis in cases of submucosal gastric
cancer is only 18 % [11], and many patients with submucosal gastric cancer undergo a larger lymphadenectomy
than is necessary. In the remaining approximately 80 % of patients without lymph mode
metastasis, lymphadenectomy can be avoided altogether [6].
In this regard, Kitagawa et al. [12] reported that the sentinel node concept was valid in cases of clinical T1N0 or T2N0
gastric cancer with a tumor diameter of 4 cm or less. In cases negative for sentinel
lymph nodes, lymph node dissection can be reduced, and local resection of submucosal
gastric cancer is possible. Furthermore, because the nerve damage caused by lymphadenectomy
can be reduced, gastric function can be preserved and postoperative problems, such
as early satiety and stasis of the stomach, can be reduced.
However, this adaptation of the procedure has some limitations. For instance, it is
difficult to apply to lesions located in the angle lesser curvature, because the sheet
cannot be adhered to the serosa. To overcome this problem, it is necessary to prepare
a silicone sheet that fits the shape of the stomach; this aspect needs to be addressed
in the future. It is possible to resect the lesions located in other positions where
the silicone sheet can be adhered. In particular, it is a good indication for lesions
located in the anterior wall or the great curvature. In cases of posterior wall lesions,
the tumor can be resected; however, it takes a long time to adhere the sheet to the
serosa because of stomach mobilization and space limitations in the abdominal cavity.
Conclusion
Sealed EFTR is a potentially useful technique that allows minimally invasive resection
of gastric tumor, because it was possible to incise all layers of the stomach while
confirming the incision line endoscopically and avoiding exposure of the tumor to
the abdominal cavity.
