Abstract
Purpose
Hydrocephalus is a common condition in pediatric neurosurgeon’s clinical practice. Peritoneal and atrial shunting is the treatment of choice in the immense majority of patients. Sometimes, there are complex cases that may need innovative solutions in order to implant the distal catheter of the shunt: in these situations, the gallbladder is a well-described option and it can be safely used.
Methods
We report the case of a 4-month-old baby with a wide optic-chiasmal hypothalamic glioma generating hydrocephalus with high protein values in CSF. Ventriculobiliary shunting was decided, and the distal catheter was directed by the assistance of laparoscopic surgery.
Results
The outcome was satisfactory.
Conclusions
As far as we know, laparoscopic placement of a distal catheter in the gallbladder has not been described in the literature; herein, we describe the tenets and the technical tips of this approach.
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Introduction
Ventriculobiliary shunt is a rarely used treatment for pediatric hydrocephalus, usually performed as a second- or third-line treatment when a ventriculoperitoneal shunting is not feasible or fails. Herein, we describe a minimally invasive technique for positioning a ventriculobiliary shunt with the assistance of laparoscopic surgery.
Case
A 4-month-old male presented at emergency with occasional vomiting and altered gaze. At exploration, the anterior fontanel was tense and macrocephaly was observed. The child was also progressively drowsy.
Following US imaging, a gadolinium-enhanced brain MRI was performed (Fig. 1), showing a wide, enhancing, bilateral frontal mass involving the hypothalamus and bilateral optic pathway. Hydrocephalus was also present, together with an augmentation of the extra-axial subarachnoid space.
Patient was briefly managed on emergency by a general neurosurgeon with an external ventricular drainage, thus controlling the intracranial hypertension. A biopsy of the mass was performed and the diagnosis was optic-chiasmal hypothalamic glioma (OCHA).
Placement of a definitive CSF shunt was needed to permanently manage the hydrocephalus and to start the adjuvant therapy as soon as possible. Nevertheless, the biochemical features of CSF, with a high protein concentration (901.5 mg/dL), caused concerns about the feasibility of a ventriculo-peritoneal shunt (VPS); it was also taken on account that the peritoneal venous and lymphatic system would not reabsorb such an elevated amount of proteins, generating associated lymphatic pathways obstruction and eventually ascites. Moreover, although high protein levels in CSF are actually not a contraindication for VPS placement, as occurs in conditions like tuberculous hydrocephalus and some oncologic cases, proteinaceous ascites is a well-described complication in patients with OCHA treated with VPS [1,2,3]. Olavarria [4] already showed the role of ventricular gallbladder shunt in infants with OCHA, so we decided that shunting CSF from the ventricular system to the gallbladder was a reasonable first-line treatment in this patient.
Based on previous experiences [5, 6], we found that a subhypocondrial incision was unnecessary and associated with higher postoperative pain; therefore, we decided to place the distal catheter with laparoscopic assistance, in a similar fashion that has already been described with VPS [7].
Laparoscopic assisted ventriculobiliary shunt insertion was performed by an interdisciplinary team including a neurosurgeon and a pediatric general surgeon. A ProGav 2.0 (Miethke Braun) shunt was positioned from a right frontal burr hole with standard technique.
Posteriorly, a three-port laparoscopic approach was performed using a 5-mm umbilical trocar for a 30° telescope and two 3-mm working ports. A carbon dioxide pneumoperitoneum was created with a pressure of 8 mmHg. After the identification of the gallbladder beneath the right lobe of the liver (Fig. 2a), a small incision was performed on its fundus. A 5 cm long, curved tip of a 7 French pigtail catheter was placed in the fundus of the gallbladder (Fig. 2b) with Seldinger technique. A straight connector was positioned to link it with the peripheral derivation. The catheter was first fixed laparoscopically by a purse-string suture and additionally at the level of the straight connector.
The curved form of the pigtail catheter and the straight connector, offering a resistant point to fix the ligation suture, were used to prevent migration of the catheter produced by intestinal peristalsis (Fig. 2b–d).
Postoperative X-ray showed no complications (Fig. 2d). Clinical evolution was good. Patient was discharged in 48 h; at 14-month follow-up, patient showed no complications. The shunt is currently functioning at 6 cmH2O; routine X-ray scans or sonographies are realized and no migration of the catheter’s tip has been showed. The patient follows an unrestricted diet with generic advise to avoid an excess of greasy food. Esthetic result was considered satisfactory according to both the opinion of parents and surgical team.
Discussion
It is not uncommon to find complex hydrocephalic patients, in whom it may be necessary to look for places other than peritoneum for implanting the distal catheter: these situations usually include a failure in peritoneal reabsorption (ascites, pseudo-occlusion, peritoneal or portal hypertension, previous abdominal surgery with adhesions, obesity). When peritoneal shunt is not feasible, cardiac atrium is the most commonly used second option. Nevertheless, ventricular atrial shunts have been related with higher incidence of internal jugular vein’s thrombosis in children younger than 1 year old [5].
Ventricular pleural shunts are not recommended under 4 years because they experience higher pleural effusion rate, most likely due to a smaller pleural surface area leading to reduced absorption [8, 9]. Other techniques have been described: “ventriculovascular shunt” to femoral vein [10], bladder [11], omental bursa [12].
Ventriculobiliary shunt’s feasibility was first time described by Smith and colleagues in 1958 [13]; late in 1987, West reported his experience in pediatric population [14]. Gallbladder shunting has been always conceived for cases with failure of the peritoneum to absorb CSF.
Shunt-related proteinaceous ascites subsequent to the shunting in children with OCHA is well described in the literature [1,2,3], and it has been related with a vascular permeability factor produced by the tumor cells which can generate hyper-permeability on peritoneal vessels, thus producing exudation and ascites [15]. Moreover, the high protein content of the CSF may lead to an insufficiency of the lymphatic drainage in the peritoneum to effectively absorb the fluid, which is more evident in young children [1,2,3,4]. Olavarria [4] reports that ventriculobiliary shunting can resolve ascites in patients with OCHA since lytic action of bile may breakdown proteins present in the CSF that impair absorption. Based on this previous experience, we selected the ventricular gallbladder as a first option. Moreover, considering the extremely young age of the patient, he was considered too young for an auricular or pleural shunt.
We felt that the classic subhypocondrial incision needed to localize and maneuver the gallbladder was larger than needed for the goal of surgery. In previous experiences [5], the incision was significantly reduced using intraoperative sonographic localization of the gland. Experience on laparoscopic ventriculoperitoneal shunt placement in children under the age of 1 year [7] showed good results, with a reduced operation time and similar blood loss and complications, compared with traditional mini-laparotomy. We thought that a laparoscopic approach could spare the subhypocondrial incision, improving postoperative discomfort and pain.
A three-port laparoscopy allows a complete comfort to the pediatric surgeon. The gallbladder has a small surface, comparing with the peritoneum: it is important to prevent the migration of the distal catheter which can be proximal (exiting from the gallbladder to the peritoneum) or distal (penetrating the biliar pathways). This is the reason why we decided to use the tip of a pigtail catheter and a small straight connector, which was also used as a resistant point for the fixation to the gallbladder, at the end of the peripheral peritoneal catheter.
Conclusions
The ventricular gallbladder shunt is a safe and feasible first-line option in patients with OCHA and hydrocephalus, and seems to prevent ascites in this subgroup of patients.
Laparoscopy, with the collaboration of an experienced pediatric surgical team, can be safely used to position the distal catheter, reducing postoperative scaring and pain.
References
Gil Z, Beni-Adani L, Siomin V, Nagar H, Dvir R, Constantini S (2001) Ascites following ventriculoperitoneal shunting in children with chiasmatic-hypothalamic gliomas. Childs Nerv Syst 17:395–398
West GA, Berger MS, Geyer JR (1994) Childhood optic pathway tumors associated with ascites following ventriculoperitoneal shunt placement. Pediatr Neurosurg 21:254–259
Yount RA, Glazier MC, Mealey J, Kalsbeck JE (1984) Cerebrospinal fluid ascites complicating ventriculoperitoneal shunting. J Neurosurg 61:180–183
Olavarria G, Reitman AJ, Goldman S, Tomita T (2005) Post-shunt ascites in infants with optic chiasmal hypothalamic astrocytoma: role of ventricular gallbladder shunt. Childs Nerv Syst 21(5):382–384
Rivero-Garvía M, Pancucci G, Morcillo J, Millán A, Márquez-Rivas J (2015) Ventriculobiliary shunts, another option. Pediatr Neurosurg 50(3):152–156
Aldana PR, James HE, Postlethwait RA (2008) Ventriculogallbladder shunts in pediatric patients. J Neurosurg Pediatr 1(4):284–287
Soleman J, Schneider CA, Pfeifle VA, Zimmermann P, Guzman R (2017) Laparoscopic-assisted ventriculoperitoneal shunt placement in children younger than the age of 1 year. World Neurosurg 99:656–661
Venes JL, Shaw RK (1979) Ventriculopleural shunting in the management of hydrocephalus. Childs Brain 5:45–50
Melamed EF, Christian E, Krieger MD, Berry C, Yashar P, McComb JG (2016) 200 age as a novel risk factor for revision of ventriculopleural shunt in pediatric patients. Neurosurgery. 63(Suppl 1):178–179
Gutierrez-Gonzalez R, Rivero-Garvía M, Márquez-Rivas J (2010) Ventriculovascular shunts via the femoral vein: a temporary feasible alternative in pediatric hydrocephalus. J Pediatr Surg 45:2274–2277
West CG (1980) Ventriculovesical shunt Technical note. J Neurosurg 53(6):858–860
Matushita H, Cardeal D, Pinto FC, Plese JP, de Miranda JS (2008) The ventriculoomental bursa shunt. Childs Nerv Syst 24(8):949–953
Smith GW, Moretz WH, Pritchard WI: Ventriculo-biliary shunt; a new treatment for hydrocephalus. Surg Forum 9:701–705, 1958 14
West KW, Turner MK, Vane DW, Boaz J, Kalsbeck J, Grosfeld JL (1987) Ventricular gallbladder shunts: an alternative procedure in hydrocephalus. J Pediatr Surg 22:609–612
Adegbite AB, Khan M (1982) Role of protein content in CSF ascites following ventriculoperitoneal shunting. J Neurosurg 57:423–425
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Pancucci, G., Plaza-Ramirez, E., Driller, C. et al. Laparoscopy-assisted placement of a ventriculobiliary shunt: a technical note. Childs Nerv Syst 35, 1397–1400 (2019). https://doi.org/10.1007/s00381-019-04173-5
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DOI: https://doi.org/10.1007/s00381-019-04173-5