Analysis of risk factors for infection in coplacement of percutaneous endoscopic gastrostomy and ventriculoperitoneal shunt

Patients with severe neurological impairment requiring tube feeding may have concomitant hydrocephalus. Coplacement of percutaneous endoscopic gastrostomy (PEG) and ventriculoperitoneal (VP) shunting is currently standard in such cases. The present study investigated the risk factors for shunt infection in such patients. The medical records of 23 patients with PEG and VP shunting were retrospectively reviewed. Correlations between shunt system infection and potential risk factors were analyzed including order of PEG and VP shunting, position of abdominal shunt catheter, diabetes mellitus, tracheostomy, and activities of daily living. Twelve patients underwent VP shunting after PEG and 11 underwent PEG after VP shunt placement. Four patients experienced shunt infection, and three required shunt revision. Three of these four patients underwent VP shunting after PEG. The period between PEG and VP shunt placement was 18, 19, and 25 days, shorter than the mean period of 29.3 days. VP shunting can be combined with PEG, but a larger study is required to clearly identify the risk factors. Administration of prophylactic antibiotics and a period of at least 1 month between the procedures are recommended, particularly if the shunt is placed after the PEG tube.     

Ventriculoperitoneal Shunt Failure as a Complication of Laparoscopic Surgery

Objective:

The authors report the first documented case of laparoscopically induced Ventriculoperitoneal (VP) shunt failure.

Summary Background Data:

Laparoscopic surgery has become a preferred method of accessing and treating a variety of intraperitoneal pathology.Surgeons can expect to encounter patients who have previously under-gone placement of cerebrospinal fluid (CSF) shunts who present as candidates for laparoscopic procedures. Currently, the presence of a CSF shunt is not considered to be a contraindication to laparoscopy. We report the first documented case of laparoscopically induced VP shunt failure.

Clinical History:

A patient with shunt-dependent hydrocephalus underwent laparoscopic placement of a feeding jejunostomy. Postoperatively, clinical and radiographic evidence of shunt failure was noted. The patient under-went emergent shunt revision. Intraoperatively, an isolated distal shunt obstruction was encountered. Gentle irrigation cleared the occlusion. We believe that this shunt dysfunction was secondary to impaction of either soft tissue or air within the distal catheter as a consequence of peritoneal insufflation.

Conclusions:

It is concluded that laparoscopic surgery may represent a potential danger in patients with pre-existing CSF shunts. The risk of neurological injury faced by this patient population during laparoscopy is derived from peritoneal insufflation and relates to two primary concerns. The first is impaired CSF drainage due to a sustained elevated distal pressure gradient or, as in our case, an acute distal catheter obstruction. The second concern relates to the potential for retrograde insufflation of the CSF spaces through an incompetent shunt valve mechanism. Distal shunt catheter externalization performed in conjunction with a neurosurgeon during the laparoscopic procedure would prevent these complications. Internalization of the distal shunt catheter would then be performed at the completion of the laparoscopic procedure.     

Frameless stereotactic ventricular shunt placement for idiopathic intracranial hypertension

INTRODUCTION: Cerebrospinal fluid (CSF) shunting effectively reverses symptoms of idiopathic intracranial hypertension (IIH). Lumboperitoneal (LP) shunts have traditionally been used in patients with IIH due to a frequently undersized ventricular system. However, the advent of image-guided stereotaxis has enabled effective ventricular catheter placement in patients with IIH. We describe the first large series of frameless stereotactic ventriculoperitoneal (VP) shunting for patients with slit ventricles and IIH. METHODS: We describe the frameless stereotactic VP shunting technique for IIH in 32 procedures. Outcomes following shunt placement, time to shunt failure, and etiology of shunt failure are reported. RESULTS: A total of 21 patients underwent 32 ventricular shunting procedures (20 VP, 10 ventriculoatrial, 2 ventriculopleural). One hundred percent of shunts were successfully placed into slit ventricles, all requiring only one pass of the catheter under stereotactic guidance to achieve the desired location and CSF flow. There were no procedure-related complications and each ventricular catheter showed rapid egress of CSF. All (100%) patients experienced significant improvement of headache immediately after shunting. Ten percent of ventricular shunts failed at 3 months after insertion, 20% failed by 6 months, 50% failed by 12 months, and 60% failed by 24 months. Shunt revision was due to distal obstruction in 67%, overdrainage in 20%, and distal catheter migration or CSF leak in 6.5%. There were no shunt revisions due to proximal catheter obstruction or shunt infection. CONCLUSIONS: In our experience treating patients with IIH, frameless stereotactic ventricular CSF shunts were extremely effective at treating IIH-associated intractable headache, and continued to provide relief in nearly half of patients 2 years after shunting without many of the shunt-related complications that are seen with LP shunts. Placing ventricular shunts using image-guided stereotaxis in patients with IIH despite the absence of ventriculomegaly is an effective, safe treatment option.     

Laparoscopic management of distal ventriculoperitoneal shunt complications

BACKGROUND: The traditional management of hydrocephalus still is the placement of ventriculoperitoneal (VP) shunts. However, the majority of patients require one or more revisions over their lifetime. Revisions may be required for infections, proximal site malfunction, or distal catheter complications. The authors present their experience with distal catheter complications managed laparoscopically. METHODS: Patients with recurrent symptoms of increased intracranial pressure or abdominal complaints were evaluated for shunt malfunction. Similar radiographic imaging was performed for all the patients, including computed tomography (CT) of the head and abdomen, shunt series, and/or ultrasound of the distal catheter. RESULTS: From April 2003 to July 2005, 13 patients with distal VP shunt complications were managed laparoscopically. On the basis of preoperative cerebrospinal fluid (CSF) cultures, all the patients were determined not to have an infection. Radiographic imaging showed the patients to have distal catheter problems. Preoperatively, five abdominal CT scans, six shunt series, and four abdominal ultrasounds were obtained. All studies singly and positively identified the appropriate abdominal catheter defect except in three patients who required multiple sequential radiographic studies for final determination of the diagnosis. In four patients (30.8%), the distal catheter was found to be in the extraperitoneal space. Another four patients (30.8%) had intraabdominal CSF pseudocysts. Five patients (38.4%) had issues with the position of the intraabdominal catheter: four of them subdiaphragmatic and one on the dome of the bladder. Laparoscopic repositioning was successful for all 13 patients. CONCLUSION: Regardless of the patient's presenting symptoms, appropriate imaging studies should be obtained preoperatively in a sequential manner. Distal VP shunt complications can be safely and effectively managed laparoscopically. This approach allows the intraabdominal portion of the catheter to be assessed and problems to be managed, thereby salvaging the existing shunt and avoiding the potential morbidity associated with additional VP shunt placement.     

Scrotal migration of a ventriculoperitoneal shunt

We report a case of scrotal migration of a ventriculoperitoneal (VP) shunt that presented as a hydrocele in an 18‐month‐old boy. The patient had a history of congenital hydrocephalus secondary to aqueductal stenosis requiring VP shunting at 1 month of age. He subsequently presented with painless progressive right scrotal swelling for 12 months with the distal segment of the shunt's peritoneal catheter palpable within the scrotum, which was confirmed by X‐ray imaging. Groin exploration for catheter removal and high ligation of the hydrocele were performed. Postoperatively, there was no recurrence of the hydrocele. We recommend that all infant patients with an implanted VP shunt undergo regular scrotal examinations at the neurosurgical clinic, and that early surgical intervention should be considered when a hydrocele is detected.     

Laparoscopically guided distal ventriculoperitoneal shunt placement

In standard techniques for performing ventriculoperitoneal shunts, the peritoneal catheter is threaded more or less blindly into the peritoneal cavity. Using laparoscopic techniques allows accurate peritoneal placement, without a large incision, even in replacement procedures and in patients with previous abdominal operations. We performed 28 laparoscopically guided ventriculoperitoneal shunt placements and shunt revisions in 24 patients with hydrocephalus (aged 6-80 years). Sixteen of 24 patients (67%) had previous abdominal surgery. Laparoscopic shunt placement was successful in all patients. Mean operative time was 63 +/- 34.9 minutes (range 15-150 minutes). In 2 patients, broken and disconnected distal parts of previously inserted shunts were removed from the abdomen. One shunt was removed following infection and other one was revised due to shunt malfunction. Three patients required revision of the cranial part of the shunt. Laparoscopically guided distal ventriculoperitoneal shunt placement provides definite patient benefits: it allows shunt placement under direct vision, associated with reduced trauma to the abdominal wall, and avoids a consequent risk of intra-abdominal adhesions.     

Treatment of hydrocephalus in adults by placement of an open ventricular shunt.

OBJECT: Ventricular shunt placement is the neurosurgical procedure most frequently associated with complications. Over the years, it has been a growing concern that the performance of most shunting devices does not conform to physiological parameters. An open ventriculoperitoneal (VP) bypass with a peritoneal catheter for which the cross-sectional internal diameter was 0.51 mm as a distinctive element for flow resistance was evaluated for use in the treatment of adult patients with hydrocephalus. METHODS: During a 2-year period, open shunts were surgically implanted in 54 adults with hydrocephalus; conventional shunts were implanted in 80 matched controls. Periodic evaluations were performed using neuroimaging studies and measures of clinical status. All patients were followed from 12 to 36 months. 18.5 +/- 4 months for patients with the open shunt and 19.1 +/- 8.1 months for controls (mean +/- standard deviation). The device continued to function in 50 patients with the open shunt (93%) and in 49 controls (61%: p < 0.001). The Evans index in patients with the open shunt was 0.33 +/- 0.09 throughout the follow up. No cases of infection, overdrainage, or slit ventricles were observed: the index in controls was 0.28 +/- 0.08; 60% of them developed slit ventricles. During the follow-up period occlusion occurred in four patients with the open shunt (7%) and in 31 controls (39%: p < 0.001). CONCLUSIONS: The daily cerebrospinal fluid (CSF) drainage through the open VP shunt is close to 500 ml of uninterrupted flow propelled by the hydrokinetic force generated by the combination of ventricular pressure and siphoning effect. It complies with hydrokinetic parameters imposed by a bypass connection between the ventricular and peritoneal cavities as well as with the physiological archetype of continuous flow and drainage according to CSF production. The open shunt is simple, inexpensive, and an effective treatment for hydrocephalus in adults.     

Laparoscopically assisted peritoneal shunt insertion in hydrocephalus: a prospective controlled study

Background Shunting of cerebrospinal fluid to the peritoneal cavity is standard therapy for the management of hydrocephalus. Common problems, however, are infection and shunt malfunction, which frequently is related to the peritoneal end of the catheter. Laparoscopic revision of distal shunt malfunction has become popular, but endoscopic techniques for primary placement of the peritoneal catheter are not performed often. This study aimed to compare laparoscopically assisted peritoneal catheter placement with the conventional minilaparotomy technique. Methods In the prospective arm of the study, 50 patients underwent laparoscopic distal shunt placement. The findings were compared with those for another group of 50 patients who underwent surgery by the standard transrectal or pararectal approach. Both groups were similar with regard to age, gender, American Society of Anesthesiologists (ASA) scores, indications for surgery, and frequency of previous abdominal operations. Results No intraoperative complications occurred. The mean time for surgery was 59 min in the laparoscopically assisted treatment group and 49 min in the standard group. During follow-up assessment, 3 instances of distal catheter malfunction or infection (2 malfunctions and 1 infection) occurred in the endoscopic group, and 12 instances (6 malfunctions and 6 infections) occurred in the control group. This difference was statistically significant. Conclusions The findings from this prospective controlled study indicate that the risk for long-term complications attributable to distal shunt malfunction is reduced when laparoscopic techniques are used to place the peritoneal end of the shunt catheter.     

Comparison of revision rates following endoscopically versus nonendoscopically placed ventricular shunt catheters

BACKGROUND: Endoscopic placement of ventriculoperitoneal (VP) shunt catheters in pediatric patients has been increasingly used in an attempt to minimize the unacceptably high rates of revision. Although this procedure carries an increased expense, there is currently no evidence to support an improved long-term outcome. This paper compares the rates of revision following ventricular catheter placement for shunted hydrocephalus with and without the use of endoscopy. METHODS: We retrospectively reviewed the records of all pediatric patients who had undergone shunt placement for hydrocephalus between April 1992 and February 1998. All shunts placed before March 1995 were performed without the endoscope; all subsequent shunts were placed endoscopically. The independent effect of endoscopic versus nonendoscopic shunt placement on subsequent shunt failure was analyzed via multivariate proportional hazards regression model. Multiple logistic regression analyses were used to determine the independent effect of endoscopic placement on subsequent etiology of failure (infection, proximal obstruction, distal malfunction) in the 511 failing shunts. RESULTS: There were 447 pediatric patients who underwent a total of 965 shunt placements or revisions. Six hundred and five (63%) catheters were placed with the use of the endoscope. Three hundred and sixty (37.3%) were placed without the use of the endoscope. Neuroendoscopy did not independently affect the risk of subsequent shunt failure [Hazard Ratio (95% Confidence Interval) = 1.08 (0.84-1.41)]. Endoscopic placement independently decreased the odds [Odds Ratio (95% Confidence Interval) = 0.56 (0.32-0.93)] of proximal obstruction, increased the odds of distal malfunction [1.52 (1.02-2.72)], and was not associated with infection [1.42 (0.78-2.61)]. CONCLUSIONS: Endoscopic assisted ventricular catheter placement decreased the odds of proximal obstruction but failed to improve overall shunt survival in this 6 year experience.     

Laparoscopic guidance or revision of ventriculoperitoneal shunts in children.

BACKGROUND: Ventriculoperitoneal shunt is the preferred treatment for hydrocephalus. Known complications include infection, obstruction, and disconnection with the fractured fragment migrating in the peritoneal cavity. We report 17 cases of laparoscopic evaluation and revision of ventriculoperitoneal shunts in children. METHODS: From January 2000 through October 2002, we retrospectively reviewed our experience with laparoscopy and ventriculoperitoneal shunts. RESULTS: Laparoscopy was performed in 17 children with a malfunctioning shunt, presumed shunt dislodgment or disconnection, reinsertion of a shunt after externalization, and primary shunt placement. Six patients (35%) were converted to an open laparotomy due to dense adhesions. Eleven patients (65%) underwent successful laparoscopic-assisted ventriculoperitoneal shunt placement: 5/11 (45%) had lysis of adhesions or pseudocyst marsupialization with repositioning of a functional shunt, or both; 3/11 (27%) had successful retrieval of a disconnected catheter with reinsertion of a new catheter; 2/11 (18%) had laparoscopic confirmation of satisfactory placement and function, requiring no revision; 1/11 (9%) had an initial shunt placed with laparoscopic guidance due to the obesity. Operative time for the laparoscopic procedure ranged from 30 minutes to 60 minutes. All laparoscopic procedures used 1-mm or two 5-mm ports. Perioperatively, no adverse neurological sequelae occurred due to the pneumoperitoneum. CONCLUSIONS: Laparoscopic guidance or revision of ventriculoperitoneal shunts permits (1) direct visualization of catheter insertion within the peritoneal cavity, (2) satisfactory positioning, (3) lysis of adhesions or marsupialization with catheter repositioning, or both, and (4) retrieval of fractured catheters.     

Laparoscopic revision of a ventriculoperitoneal shunt

Ventriculoperitoneal (VP) shunts are the most common treatment modality for hydrocephalus. Distal catheter malfunction represents a surgical emergency and a significant cause of procedural morbidity. We report the case of a patient with acute abdominal pain following VP shunt insertion. On examination she had a tender, irreducible bulge at the abdominal laparotomy site. Exploratory laparoscopy of the abdomen yielded no abdominal wall abnormalities. At the same time, the distal catheter was noted to be absent. The abdominal bulge was incised along the laparotomy scar and clear cerebrospinal fluid was encountered. The incision was explored and the distal catheter was coiled and knotted within the preperitoneal space. The catheter was laparoscopically returned to the peritoneal cavity. This case exemplifies the utility of laparoscopy for VP shunt revision and we present a review of laparoscopic shunt revision.     

Minimally invasive implantation of the peritoneal catheter in ventriculoperitoneal shunt placement for hydrocephalus: analysis of data in 151 consecutive adult patients

OBJECT: The authors report on their experience with laparoscopy-guided implantation of a peritoneal catheter in ventriculoperitoneal shunt placement procedures in adults. METHODS: In performing the conventional method of shunt placement in 2001, 8% of the cases resulted in malposition and dislocation of the distal catheter; therefore, the authors together with personnel from the Department of General Surgery decided to utilize an interdisciplinary approach involving laparoscopy-guided implantation of the catheter. Between October 2001 and January 2005, 202 ventriculoperitoneal shunt placement procedures were conducted in adult patients for hydrocephalus of various origins. In 152 patients, laparoscopy-guided implantation of the distal catheter was performed. In all except one of these patients, implantation was successful. Laparoscopy and the cranial part of the surgery were performed simultaneously. There was an 8% rate of malposition of the distal catheter in the nonlaparoscopy group. In contrast, there was no dislocation or malposition of the distal catheter in the laparoscopy group. Two cases (1.3%) of shunt infection occurred in the laparoscopy group. CONCLUSIONS: Laparoscopic implantation of a distal catheter is a simple, minimally invasive, and easy procedure to perform and allows exact localization of the peritoneal catheter and confirmation of its patency.     

Unusual migration of the distal catheter of a ventriculoperitoneal shunt into the heart: case report

OBJECTIVE AND IMPORTANCE: Placement of a ventriculoperitoneal (VP) shunt is the most common form of treatment for hydrocephalus. Thoracic complications with VP shunts are rare, but we present the second documented case of the distal migration of the distal catheter of a VP shunt into the heart. CLINICAL PRESENTATION: A 14-year-old boy, who underwent placement of a right occipital VP shunt at another institution after closed-head injury, presented with hypertension. Plain chest x-rays and computed tomography revealed the distal catheter to be in the right ventricle of the heart. INTERVENTION: A joint surgical procedure was performed with the cardiac surgery team. The cardiac surgeons created a pericardial window through a subxyphoid incision. Simultaneously, a right occipital incision was made to access the distal catheter, which was then slowly pulled out with the pericardium under direct visualization. No hemorrhage or change in the pericardium was observed, and, therefore, the need for a thoracotomy was eliminated. A new distal catheter was placed into the peritoneal cavity. CONCLUSION: The migration of the distal catheter probably occurred during the initial VP shunt placement. The internal jugular vein probably was perforated by the tunneler during the creation of the distal catheter tract. Slow venous flow and negative inspiratory pressure may have gradually pulled the catheter up into the right atria and ventricle. As demonstrated by our case report, the catheter can be extracted safely in a joint procedure with cardiac surgeons, and a thoracotomy is not always necessary. The patient did not experience postoperative complications, and his hypertension was alleviated.     

Ventriculopleural shunting used as a temporary diversion

Summary Due to the limited absorptive capacity of the pleural cavity, infants and young children are not generally ideal candidates for ventriculopleural shunts. We report using chest cavities as alternate for temporary diversion of CSF in a young child. Venous access to the cervical region could not be utilized because of scarring from previous procedures, while peritoneal access was contraindicated due to repeated pseudocyst formation. Pleural effusions were removed by thoracentesis when necessary, and the shunt catheter was changed to the opposite side of the chest when the effusions reaccumulated within one week. Utilizing the ventriculopleural shunts allowed us to temporize her non-communicating hydrocephalus for a period of one year, until a definitve CSF procedure by direct intracardiac placement of the distal catheter could be performed.     

A laparoscopic approach to ventriculoperitoneal shunt placement in adults

Background: Ventriculoperitoneal shunts have been used for the treatment of hydrocephalus for years. In the past, the abdominal portion of this technique has required mini-laparotomy. We present a series of 10 consecutive patients in which ventriculoperitoneal (VP) shunts were placed with laparoscopic assistance. Materials and methods: At Lankenau Medical Center for July 1996 to January 1998, 10 patients (aged 22–81) with normopressure hydrocephalus underwent laparoscopic VP shunt placement. The neurologic portion of the procedure is begun simultaneously with the abdominal procedure. After pneumoperitoneum is established using a miniport disposable 2-mm introducer at the umbilicus, a 2-mm camera is introduced into the peritoneal cavity through the same port. A needle is introduced into the peritoneal cavity under direct visualization. Once the catheter is placed ventricularly, it is tunneled subcutaneously to the abdomen. Using the Seldinger technique, the VP catheter is introduced under direct visualization through a sheath into the peritoneal cavity toward the pelvis. Positioning and function are also confirmed under direct visualization. Results: All patients tolerated this procedure well, and there were no complications. The benefits of this procedure include direct visualization of catheter placement and smaller incisions than necessary for an open procedure. Conclusion: We recommend laparoscopic-assisted placement of the VP shunt in normopressure hydrocephalus patients as a good alternative to the open technique. Received: 30 June 1998/Accepted: 25 November 1998     

Laparoscopic management of abdominal complications in ventriculoperitoneal shunt surgery.

Ventriculoperitoneal (VP) shunts are among the most frequently performed operations in the management of hydrocephalus. Abdominal complications, though rare, are reported to occur in 5-47%. VP shunt obstruction or malfunction leads to raised intracranial pressure, which requires immediate intervention. Recently we have used the laparoscope to manage abdominal complications of VP shunt in two patients. The first patient had hydrocephalus secondary to tubercular meningitis. She developed recurrent intraabdominal cerebrospinal fluid (CSF) pseudocysts, possibly due to subtle peritoneal infection. In the second patient, who developed hydrocephalus following subarachnoid haemorrhage, the lower end of the shunt was malfunctioning due to retraction into the extraperitoneal tissues. The distal end of the VP shunt was revised in both patients with the help of a laparoscopically assisted technique. Thus, a conventional laparotomy, along with its various associated postoperative problems, was avoided without compromising the quality of surgery.     

Extrusion of the peritoneal catheter of a VP shunt system through a gastrostomy wound

BACKGROUND: A variety of complications can occur following ventriculoperitoneal shunt. We report a case of extrusion of the catheter tip through the old scar of the percutaneous endoscopic gastrostomy (PEG) wound. CASE DESCRIPTION: A 70-year-old male suffered from an intracerebral hemorrhage and then developed hydrocephalus. He required a ventriculoperitoneal shunt. This patient required a PEG for gastroenteric feeding. The PEG was removed 4 years after the insertion because of infection. The tip of the distal shunt tube extruded through the scar of the PEG wound 2 years later. CONCLUSION: The catheter end of VP shunt can extrude through the weak point of an old PEG scar. This kind of complication should be brought to mind while performing abdominal surgery in patients with VP shunts.     

Ventriculosagittal sinus shunt placement: technical case report

OBJECTIVE AND IMPORTANCE: Determining an appropriate site for distal catheter placement for ventricular shunting for some hydrocephalic patients can be difficult. We describe a simplification of the technique for sagittal sinus shunt placement using a guidewire. CLINICAL PRESENTATION: A 20-month-old infant with hydrocephalus secondary to Alexander's disease developed erosion of her parieto-occipital ventriculoperitoneal shunt reservoir through an occipital decubitus scalp ulceration. Her hydrocephalus was temporarily treated with a ventriculostomy; however, she developed pneumatosis intestinalis while in the hospital. TECHNIQUE: The patient underwent placement of a ventriculosagittal sinus shunt. The ventricular catheter and shunt valve were placed through a burr hole at Kocher's point, and the distal end of the catheter was placed in the superior sagittal sinus by using the Seldinger technique. CONCLUSION: Ventriculosagittal sinus shunting may be used as an alternative to traditional methods for patients for whom distal shunt placement is problematic. Our technique has the theoretical advantage of reducing the risks of blood loss or air embolism by not requiring a scalpel incision into the sinus.     

Migration of a distal ventriculoperitoneal shunt catheter into the internal jugular vein and heart through the external jugular vein: case report

A 6-year-old boy had undergone ventriculoperitoneal (VP) shunt for acute hydrocephalus because of a brain tumor at the age of 11 months, and presented with vomiting and somnolence after the shunt malfunctioned 6 days after VP shunt reconstruction, during which the right external jugular vein was injured during the tunneling process and the peritoneal catheter was not fixed to the peritoneum with a purse string suture. Radiography revealed an abnormal route of the peritoneal catheter, suggesting that the distal VP shunt catheter had migrated into venous vasculature through the right external jugular vein. Computed tomography revealed that the peritoneal catheter had migrated into the internal jugular vein and the right atrium. At surgery, the peritoneal catheter was exposed through a small incision on the subclavicular region, was easily extracted from the internal jugular vein and the heart as there was no coiling or adhesion of the distal catheter to the vascular tissues, and was repositioned into the peritoneum with weak fixing between the subcutaneous tissues of the right subclavicular region and the right abdominal rectus muscle fascia as a temporary emergency measure. Peritoneal shunt migration into the internal jugular vein and the heart through the external jugular vein can be lethal because of pulmonary infarction or arrhythmia, and must be detected as soon as possible. Periodic follow-up radiography should be scheduled after VP shunt placement, even in the absence of symptoms.     

Factors causing acute shunt infection. Computer analysis of 1174 operations

A series of 1174 operations performed on 802 hydrocephalic children was analyzed in an effort to find the factors causing acute postoperative infection. Culture of the cerebrospinal fluid (CSF) samples during the operation was positive in 33 cases. These cases were excluded from the series. Ninety infections were observed in the remaining 1141 operations, an overall rate of 7.9%. Most of these infections were meningitis (56 cases). Staphylococcus epidermidis was the bacterium most frequent identified (44%). Statistically significant relationships were found between shunt infection and the following factors: 1) age: infection was 2.6 times as frequent before 6 months than after 1 year of age (p = 0.03); 2) poor condition of the skin; 3) presence of intercurrent seats of infection at the time of surgery; 4) type of operation: the rate of infection was 8.4% in primary shunt insertions, 5% in shunt revisions, and 17.5% in reinsertions following shunt removal for infection (p = 0.0001); 5) end of the shunt requiring revision: an infection rate of 7.7% followed revision of the ventricular catheter alone, and 2.6% followed revision of the other end alone (p = 0.012); and 6) postoperative wound dehiscence or scalp necrosis. The surgical team involved was poorly correlated with the rate of infection (p = 0.12). No statistically significant relationships have been found between infection and 1) etiology of hydrocephalus: 2) sex; 3) recent neurosurgical operation before the shunt procedure; 4) preoperative presence of an external drainage tube or CSF fistula; 5) lumbar or ventricular taps, or ventriculography; 6) number of previous operations performed on the shunt; 7) time (month and year) of operation; or 8) sugar level and cell count in the CSF.