Revision and complication rates in adult shunt surgery: a single-institution study

We retrospectively reviewed all adults aged 18 years and older, who underwent primary shunt insertion at St. Olavs University Hospital, Trondheim, Norway, from January 2008 through December 2017. All patients were followed for at least 1 year (through 31st of December 2018), range 1–11 years. Electronic medical records from all seven hospitals in our geographical catchment area were reviewed.

We used the Nomesco Classification of Surgical Procedures to retrieve records of all patients who had undergone any form of CSF diversion surgery (AAF 00, AAF 05, AAF 15, AAF 20, AAF 25, AAF 40, AAF99, JAL 50, JAL 51) in the given time period. Patients were then reviewed individually, and only patients who underwent primary ventriculoperitoneal, ventriculoatrial, or cystoperitoneal shunt operations in the given time period were included. Patients who underwent revision surgery in the given time period, but with primary shunt insertion outside the given time period, were excluded.

We extracted baseline data for all patients including gender, age at shunt surgery, indication, comorbidities, ASA risk group and status at follow-up (alive or dead). We also extracted data on the surgical procedure itself; surgery duration, type of shunt and valve inserted, whether antibiotic prophylaxis was given, whether the patient had previous external ventricular drain prior to the shunt procedure, and the postoperative Kakarla score [8]. We extracted data on all shunt revisions performed on these patients throughout the follow-up period, as well as complications occurring within 30 days of shunt surgery. Shunt infection was defined by the finding of significantly increased leukocytes in CSF specimen with or without evidence of microbes (microscopy), together with lab findings (elevated leukocytes and C-reactive protein in serum) and clinical finding (fever, headache, reduced GCS) in awake patients. If any of these were present and resulted in either complete removal of shunt or temporary externalisation of the shunt together with intravenous use of antibiotics, this was registered as a shunt infection. The occurrence of superficial wound infection requiring oral antibiotics only, and where no surgical measures were taken, was not registered as shunt/CNS infection. Complications were classified according to the classification of neurosurgical complications defined by Landriel Ibañez et al. [6]. If patients had more than one complication, the complication with the highest grade was noted.

Statistical analyses were performed using SPSS version 25 (IBM corporation). The p value for significance was set to 0.05. Calculation of frequencies was performed for all categorical data. To establish whether there were any differences between the patients who underwent revision(s) and the non-revision group, we used the chi-square or Fischer exact test for all categorical data and the independent t test for all continuous data. Normality for continuous data was tested using the Sapiro-Wilk test and visualised using histograms and Q-Q plots. The Mann-Whitney U test was used to compare the two groups if continuous variables were skewed. A cox regression model was developed in search of risk factors associated with the need for revision surgery, and a binary regression model was developed in the search for risk factors of occurrence of revision surgery or severe or fatal postoperative complications (Landriel Ibañez grade III or IV). Revision-free shunt survival in the revision group was estimated from a Kaplan-Meier (KM) analysis.

Patient demographics are presented in Table 1. We included 227 patients, with a mean age of 58.4 years ± 15.6 (range 18–89). The most common aetiology for primary shunt surgery was hydrocephalus following subarachnoid haemorrhage (35.7%), followed by normal pressure hydrocephalus (NPH) (24.2%), and patients with tumour and/or malignancy (18.9%). Severe comorbidity, defined as ASA > 2 at the time of index surgery, was present in 50.3% of the patients. Patients who underwent shunt revisions were younger (mean age 53.0 vs. 59.8 years, p = 0.014) and fewer were deceased at the last follow-up (19.1% vs. 34.4%, p = 0.044). There were also fewer patients with ASA > 2 in the revision group (29.6% vs. 55.1%, p = 0.017). In the revision group, there were fewer patients with NPH and a greater proportion of patients with Chiari I malformation or unspecific hydrocephalus compared with the non-revised group.

Surgical characteristics are presented in Table 2. Mean surgery duration was 61.0 min ± 30.5, with no significant differences detected between the two groups (p = 0.133). The vast majority of implanted shunts were ventriculoperitoneal shunts (97.3%) with a strata (Medtronic) valve (89.8%), and there were no significant differences in the two groups in terms of shunt type or valve.

The accuracy of the intraventricular drain placement was determined by reviewing postoperative imaging and categorised in accordance with the Kakarla scoring system; 89.8% were characterised as Kakarla 1 or 2 score.

We found no significant differences between groups in terms of the Kakarla scores (1, 2 or 3), the number of primary shunt surgeries with a duration of less than 45 min or patients having received prior EVD to shunt surgery between the two groups.

The revision rates of surgery are presented in Table 3. A total of 47 patients (20.7%) underwent a revision surgery at some point during the follow-up period. Thirty-two patients (14.1%) required their first revision surgery within 1 year from index surgery. Twenty patients (8.8%) underwent revision surgery more than 1 year after index surgery, either as a first revision or subsequent revision (revision surgery falling between > 1 year from index surgery and through 2018).

The total number of procedures performed in the study period (including primary shunt insertion and shunt revisions) was 317. A total of 90 of these procedures were shunt revisions (28.3%), distributed among 47 patients with median 1.0 ± 2.0 and range 1–12. Fourteen out of 227 patients underwent ≥ 2 revisions (6.2%). The most common cause for the first revision was infection, occurring in 5.7%, followed by proximal failure/occlusion and misplacement, both occurring in 4.8% each. The most common cause of overall revision surgery was due to proximal failure/occlusion, accounting for 30.0% of revisions. Infection was the second most common cause for overall revisions, accounting for 21.1%. Misplacement accounted for the third most common cause for overall revisions with 14.4%.

Mean time from index surgery until the first revision in the 47 patients who required revision was 54.7 weeks ± 80.0 (median 11.0, range 0–257). The mean follow-up for all patients was 231.7 weeks ± 155.9 (median 217.0, range 0–561). Seventy-one out of 227 patients (31.3%) died during the follow-up period.

Figure 1 demonstrates the revision-free survival probability (time from index surgery until first revision) with mean 54.7 weeks (95% CI 31.9, 77.6, median 11 weeks, 95% CI 1.3, 20.7). The initial steep slope indicates a high probability of revision occurring within the first year (52 weeks). Progressive flattening of the slope indicates the reduced probability for revision after 1 year, and no first revisions being performed after 250 weeks.

An overview of perioperative complications classified with the Landriel Ibañez classification for all shunt procedures (combined primary shunt insertion and revision surgery) is provided in Table 4. A total of 103 patients (45.4%) experienced ≥ 1 complication(s). In total, 137 complications occurred (total 43.2%; medical 29.0%, surgical 14.2%) and were distributed among these 103 patients. Mild to moderate complications (grade I and II) were detected in 111 of the 317 procedures (35.0%). Severe or fatal complications (grade III and IV) were detected in 26 out of 317 (8.2%) procedures. UTI and pneumonia were the most common complications, occurring in 13.9% and 7.3% procedures, respectively.

The Ia medical complications were exclusively cases of urinary retention. Surgical Ia complications consisted mainly of subdural effusion/subdural haematoma, managed conservatively, and two cases of new transient neurological deficits. UTI and pneumonia accounted for most of the Ib medical complications. Surgical Ib complications consisted of one wound infection requiring antibiotics only, and one patient with post-surgical seizures requiring anticonvulsants. The medical IIa complications were mainly patients with pleural effusions, requiring drainage. The surgical IIa complications consisted of one case of a dehiscent wound, requiring surgical closure under local anaesthesia, one patient requiring additional lumbar drainage and one case requiring temporary external drainage. Three cases of medical IIb complications were detected—pneumonia-causing atelectasis and requiring bronchoscopy in two patients and one patient suffering from an acute haemorrhage after undergoing tracheostomy, requiring intervention. The most common cause of surgical IIb complications was hardware misplacement (either proximally or distally), requiring reoperation. There were also five cases of track haematomas causing dysfunctional ventricular catheters, requiring revisions surgeries. Grade IIIa surgical complications consisted mainly of patients with CSF infection, verified by CSF specimens, requiring surgery with either externalisation or removal of the shunt. Four patients were re-intubated after surgery due to respiratory distress and respiratory failure and were classified as medical IIIa complications. Grade IV complications were classified as death occurring within 30 days of surgery regardless of cause. This was the case for fourteen patients; two patients died as a direct result of surgery/complication to surgery, and both died within a week of surgery (one instance of bowel perforation and one instance of acute aggressive meningitis). The remaining twelve patients died due to their underlying primary illness (acute subarachnoid haemorrhage, traumatic brain injury and primary extracranial malignancy) and one patient died of acquired illness/injury postoperatively. This latter case was a patient who received a shunt for NPH. The patient suffered a severe head trauma shortly after discharge, resulting in an acute subdural haematoma; due to severe clinical presentation, the patient was deemed not fit for surgical intervention and subsequently died within 30 days of shunt implantation.

Comparing index surgery procedures with revision surgery procedures, there was a higher occurrence of medical Ib complications in the index surgeries (p = 0.003). The rate of surgical IIb complications was significantly higher in the revision surgeries (p = 0.001).

A cox regression analysis failed to find a statistically significant association between the occurrence of shunt revision and underlying aetiology/indication, age or gender but found that cerebrovascular disease and hypertension increased the probability of shunt revision (p = 0.000 and p = 0.022 for cerebrovascular disease and hypertension, respectively). In a binary univariate analysis (complete case analysis, 145/227 patients included), age was inversely associated with the occurrence of revision or a grade III or IV complication (OR 0.972 for an additional year in age) but failed to show significance in a multivariate analysis. The cardiovascular and cerebrovascular disease were however found to increase the probability of revision surgery or a grade III or IV complication (p = 0.042, OR 6.1 and p = 0.04, OR 5.4 for cardiovascular and cerebrovascular disease, respectively), whilst other comorbidities, aetiology/indication and gender did not.