Keywords
indocyanine green - laparoscopy - fluorescence - thoracoscopy - minimally invasive
surgery
New Insights and the Importance for the Pediatric Surgeon
The ability to visualize the vascular structures or the bile duct allows us to approach
laparoscopic techniques of different complexities, with greater safety for the patient.
We have verified its use in children.
Introduction
Since the 1980s, minimally invasive surgery has provided technological advances in
different areas of surgery.
The current use of new techniques has allowed the recent introduction of indocyanine
green (ICG), which has facilitated the approach and the prevention of intraoperative
complications in adults. It provides greater clarity and depth image visualization
and reduces surgical time.[1] Regarding cholecystectomy, it helps to better identify the bile duct anatomy, and
in case of urological or oncological surgery, it allows to define the vascular anatomy,
reducing the number of iatrogenic lesions[2]
The experience with the use of ICG fluorescence in adults has shown multiple applications
in recent years (colorectal, vascular, hepatobiliary, or tumor surgery)[3]; however, the experience and bibliography described in pediatric cases are specific.
We present our experience in different laparoscopic procedures performed in children
using ICG fluorescence imaging.
Case Reports
A high-definition camera (10 mm) (Stryker) equipped with a visible infrared light
source (800 nm) was used.
The laparoscopy camera used includes 3 CMOS chip technology, 1920 × 1080 p resolution,
DVI, and S-VHS outputs and interval of 1/60 (1/50)-1/50000 seconds.
The ENV (endoscopic near-infrared visualization) mode is used as a light source.
Case 1
A 14-year-old girl presented with aortocoronary fistula, which caused a decreased
coronary flow during diastole. Her clinical condition worsened during exercise. Right
three-port (3 mm) thoracoscopy was performed in upright positions. The fistulous tract
was readily identified and dissected on arrival at the right atrium. The presence
of this rare vascular anomaly was confirmed by fluorescence by immediate injection
of ICG (dose of 0.2 mg/kg), allowing better visualization and secure ligature ([Fig. 1]).
Fig. 1 Aortocoronary fistula ligation. The image shows vascular permeability of the fistula,
clearly demonstrated with the uptake of indocyanine green through it.
Case 2
A 13-year-old boy was scheduled for varicocelectomy. He had a clinical history of
asymmetry and testicular pain. Umbilical, and right and left flank trocars (5 mm)
were introduced for lens and instruments, respectively.
After intravenous (IV) injection of ICG, the arterial vessels were initially visualized
following by the venous vessels. Thereafter, ligation of the spermatic cord was performed
in block, ensuring selection of all vessels and avoiding the section of lymphatics
that are not filled in this phase ([Fig. 2]).
Fig. 2 Ligation of spermatic vessels in varicocele. After the injection of the contrast,
the vessels are filled (arterial and venous) and its correct ligature is verified,
thanks to the infrared light of the fluorescence that indicates the vascular tree.
Case 3
A 13-year-old girl was admitted because of cholelithiasis and recurrent abdominal
pain. She required two previous hospital admissions. Laparoscopic cholecystectomy
was scheduled few days after admission. Fifteen minutes after ICG IV injection, the
biliary tree was perfectly drawn, allowing clear identification of cystic artery,
common bile duct, and hepatic duct. Safe dissection of the bile duct and artery was
performed, completing cholecystectomy with total control of all surgical maneuvers
([Fig. 3]).
Fig. 3 Cholecystectomy. Thanks to the fluorescence, contrast uptake can be observed initially
in the cystic artery (A) and later in the cystic duct (C). In the image, we are in
a late phase of fluorescence since both structures can be visualized.
Cases 4 and 5
Two children aged 3 and 6 years, respectively, had steroid-resistant hypertension
and renal failure. Nephrectomy was indicated in each of them, which was performed
by retroperitoneal laparoscopy. In both cases, intraoperative injection of indocyanine
dye allowed renal vascular anatomy to be identified with certainty, showing the peripheral
vascularization of the ureter. This technique definitively facilitated safe dissection
of the renal hilum ([Fig. 4]).
Fig. 4 Nephrectomy. The image shows the renal artery (A) and periureteral vessels (U). Without
fluorescence, the differentiation between the ureter and the vessels is difficult.
Thanks to the fluorescence, we can identify them more easily since the ureter does
not present contrast uptake.
In all cases, we initially administrated ICG dye through a peripheral venous access
at a standard dose of 0.2 mg/kg.
No adverse effects were present during or after IV ICG injections.
All patients were observed for 30 minutes to 1 hour in the recovery room, except the
patient with aortocoronary fistula who was in the pediatric intensive care unit overnight.
Discussion
ICG is an anionic molecule that is soluble in water, with a molecular mass of 776
daltons. After IV injection, ICG binds rapidly to plasma proteins, especially to lipoproteins
(albumin).
Under near-infrared light, the released fluorescence can be detected using a specifically
designed camera.[1]
Not every laparoscopic equipment includes or is compatible for usage of an infrared
light source, nor all equipment have the same technology for doing that.
We advise the use of devices that allow a vision with gray-scale functionality compared
with those that only have black-and-white vision.
ICG has an exclusively biliary excretion; therefore, its most logical application
in the visualization of biliary tree anatomy during laparoscopic cholecystectomy,[2] as shown in our case. After injection of ICG, the cystic artery could be initially
observed, and 15 minutes later, the common hepatic, common bile duct, and cystic duct
were identified. In addition, this allowed better visualization and anatomical dissection,
avoiding injury to the biliary tree. This technique also avoids performing intraoperative
cholangiography when bile duct injury is suspected during the procedure.[4]
ICG has many other applications already described in the literature; it allows identification
of sentinel node in breast tumors, melanoma, and prostate cancer among others. It
also facilitates lymphadenectomy in tumors with lymphatic spread by local injection.[5]
In colorectal surgery, it facilitates intestinal resections and is used to verify
the adequate vascularization of the intestinal anastomoses, demonstrating a lower
rate of postoperative complications.[6]
[7]
Other applications have been described in surgery, such as liver resections, nephrectomies,
and splenectomies.[8]
[9] In summary, ICG images are recommended for interventions in which visualization
of the vascular anatomy is necessary to differentiate between anatomical and vascular
variants,[3]
[10] as describe in our series of patients.
The ICG imaging system seems to be simple and safe. Its application in adult surgery
is wide and contrasted. The ability to visualize the vascular structures or the bile
duct anatomy allows us to approach laparoscopic techniques of different complexities
with greater safety for the patient. We have verified its use in children. Larger
and more specific studies are needed to confirm its applicability, expand its indications,
and address its advantages and disadvantages.
