Fig. 10.1
An ex-premature infant who developed grade 4 IVH and PHH and was treated with a VSGS
Table 10.1
Rates of infection and permanent shunting in VSGS patients as reported in the literature
Series | Number of patients with PHH treated with VSGS | Rate of device infection (%) | Rate of shunting (%) |
---|---|---|---|
Fulmer et al. (2000) [26] | 20 | 0 | 100 |
Tubbs et al. (2005) [25] | 71 | 5.9 | NR |
Wellons et al. (2009) [27] | 36 | 14 | 86 |
Lam et al. (2009) [29] | 16 | 6.3 | 71.4 |
Limbrick et al. (2010) [28] | 30 | 3.3 | 66.7 |
Although efforts are made to avoid permanent shunting in infants with PHH to prevent long-term shunt dependence, the overall rate of permanent shunt insertion ranges from 0 to 20 % in patients with IVH [15, 28, 33, 34]. The majority of patients initially treated with temporizing devices ultimately undergo permanent shunt placement. The most commonly inserted device is the VP shunt, although selected individuals require CSF diversion to other locations. Even after a temporizing device has been initially inserted, timing of permanent shunting is controversial and relies on clinical judgment of a patient’s surgical candidacy and evaluation of factors including infant weight, medical stability, and CSF profile [9]. Several studies have found that compared to infants with hydrocephalus of other etiologies, those with PHH are at increased risk of complications including shunt infection and occlusion requiring revision, slit-ventricle syndrome, and loculated hydrocephalus (Fig. 10.2) [35]. Rates of VP shunt infection in PHH patients have been reported at approximately 13 %, compared to 4–8.5 % overall in shunted populations [2, 5, 36–39]. The high rates of shunt infection seen in this population have been hypothesized to be in part due to an immature and dysregulated immune system. The use of antibiotic-impregnated shunt catheters has been proposed, and a prospective study of these devices reported an infection rate of 6.8 % [40]. IVH and PHH are also associated with a need for multiple shunt revisions, for which the most common indication is shunt failure secondary to obstruction [41]. A recent retrospective study reported a revision rate of 71.6 % and a multiple revision rate of 55 % for complications including obstruction and overdrainage; lower birth weight and EGA were found to be risk factors for multiple revisions [42].


Fig. 10.2
T2-weighted MRI of a 16-month-old patient with a history of prematurity and PHH and multiple CSF infections. There is a loculated fourth ventricle with outlet obstruction with considerable mass effect on the brainstem and cerebellum. There is also supratentorial extension
10.1.4 Alternatives to Shunting and Adjunctive Therapies
VP shunting is currently the mainstay of treatment in PHH, but several alternative medical and surgical treatment methods have been proposed. Trials of diuretic therapy with acetazolamide or furosemide have found that drug treatment with CSF tapping is associated with higher rates of eventual permanent shunt insertion and increased risk for motor impairment and nephrocalcinosis compared to management with CSF removal alone [43, 44]. Currently, there is no evidence to support the use of diuretic therapy in PHH. The use of fibrinolytics in preventing the development of hydrocephalus in IVH has also been suggested, but two randomized trials investigating the effects of intraventricular streptokinase in PHVD have not shown any benefit with respect to rates of permanent shunting or neurodevelopmental outcomes [45]. A multicenter randomized trial on PHH prevention with intraventricular tissue plasminogen activator (tPA) with a procedure involving drainage, irrigation, and fibrinolytic therapy (DRIFT) also did not find an effect of this management protocol on the rates of permanent shunting. However, although DRIFT was found to be associated with an increased risk for secondary hemorrhage, patients in the treatment group experienced better neurodevelopmental outcomes compared to the control group, with lower rates of mortality and cognitive disability [46, 47].
A promising surgical approach for PHH is endoscopic third ventriculostomy (ETV). Though outcomes of cases managed with ETV alone are inconsistent, recent studies of ETV with choroid plexus coagulation (CPC) are encouraging. In selected PHH patients, ETV with CPC may offer a means of continued CSF diversion without long-term shunt dependence [2, 48].
10.1.5 Long-Term Outcomes of PHH and Shunting
Improvement in neurodevelopmental outcomes after IVH and PHH has been largely attributed to improvements in neonatal care. Early studies from 1970 to 1980 reported significant cognitive disability and mortality associated with grade IV IVH [49]. Later reports detailed high rates of neurodevelopmental problems including sensory and motor deficits, visual impairment, hearing loss, seizures, and cognitive and behavioral disturbances in patients with severe IVH [50–52]. As these patients typically also suffer from an extensive array of medical comorbidities, poor outcomes are unlikely to be due to IVH and PHH alone. However, the effect of permanent shunting on long-term outcomes is incompletely understood. Although some studies have found that shunt insertion and complications are risk factors for poor outcomes, a study of functional outcomes in PHH patients did not find differences in the rates of functional independence in shunted and non-shunted patients [53–55]. The most critical determinant of neurologic outcome appears to be IVH severity, with patients who develop periventricular hemorrhagic infarction are at highest risk for the development of complications including cerebral palsy [33].
10.2 Postinflammatory Hydrocephalus
10.2.1 Introduction
Hydrocephalus which results from CNS infection poses a unique set of challenges with respect to treatment. The pathophysiologic mechanisms of hydrocephalus development are incompletely understood, but obstruction of CSF flow is thought to result from the inflammatory debris within the subarachnoid space and meningeal scarring. Patients with persistent hydrocephalus despite infection resolution are typically treated with permanent shunt insertion. Studies have demonstrated that patients with postinflammatory hydrocephalus (PIH) are at increased risk for shunt complications, including shunt infection and obstruction requiring surgical revision, compared to patients with hydrocephalus of other etiologies. Although there have been few reports on long-term outcomes of shunting in this population, avoidance of shunt dependence remains an important goal of management. Alternative interventions including ETV have demonstrated promise in selected patients with favorable ventricular anatomy.
10.2.2 Pathophysiology of PIH
The mechanism of PIH is believed to be secondary to obstruction of the basal cisterns and blockage of CSF outflow secondary to inflammation and meningeal fibrosis and scarring [56]. Neonatal meningitis is also considered a risk factor for the development of multiloculated hydrocephalus [56–59]. However, the mechanism of hydrocephalus often varies by pathogen. With Toxoplasmosis gondii, the parasites are thought to cause obstruction of the ventricular system via damage to the ependymal linings of the lateral ventricles. Other studies have suggested that hydrocephalus develops as a result of leptomeningeal inflammation in reaction to the parasite. Acquisition of CMV during the in utero period is associated with the development of hydrocephalus ex vacuo secondary to cortical atrophy as well as obstructive hydrocephalus from periventricular inflammation [5].
In the postnatal period, the most common cause of PIH is bacterial infection. Studies performed in the 1980s of children afflicted with bacterial meningitis have reported PIH rates at approximately 30 % [5, 57, 60]. However, the incidence of post-meningitic hydrocephalus in the pediatric population has not been well established since advancements in neonatal care. Brain abscesses can also result in obstructive hydrocephalus from mass effect and ventricular compression. Additionally, abscesses can lead to the development of loculated hydrocephalus, thought to be due to subependymal inflammation and infarction resulting in cyst formation. The pathogenesis of hydrocephalus from viral infections varies by virus; viruses often have specific tropisms for ependymal or meningeal cells.
Special consideration should be given to hydrocephalus in patients with tuberculosis with CNS involvement. Tuberculous meningitis typically favors the base of the brain, where infection results in exudate that obstructs the basal cisterns, preventing CSF outflow from the foramina of the fourth ventricle. Less commonly, intracerebral tuberculomas can cause hydrocephalus by compression of the ventricular system. Fungal pathogens including Cryptococcus neoformans and Coccidioides immitis can cause post-meningitic hydrocephalus; however, the pathogenesis of hydrocephalus in these cases is less well understood [5].
10.2.3 Management of PIH and Complications
An active infection and progressive hydrocephalus presents a therapeutic challenge, as insertion of a foreign device to divert CSF may exacerbate the infection. In the acute setting, repeated lumbar or ventricular taps may be required for management. Studies from the 1960s and 1970s of post-meningitic hydrocephalus reported high mortality rates with placement of a ventricular reservoir or with EVD [61]. Persistent hydrocephalus is typically managed by VP shunt insertion, though there is considerable variability in practice depending on patient and pathogen. Depending on the pathogen, CNS infection can result in a wide range of other sequelae and complications not causally related to the development of hydrocephalus. Regardless, studies have shown that patients with PIH are at increased risk for shunt complications including shunt infection, occlusion, and multiple shunt failures and are also at risk for development of loculated hydrocephalus (Fig. 10.3) [41, 62]. Preexisting multiloculated hydrocephalus appears to increase the risk for shunt complications, especially device infection, and for poor outcomes overall. Management options include placement of multiple shunts and fenestration of intraventricular septations, but there are no evidence-based guidelines regarding treatment choice [57].


Fig. 10.3
MRI of a 4-month-old patient with a history of multiple intracranial abscesses secondary to S. aureus meningitis who developed loculated hydrocephalus requiring multiple shunt placements with endoscopic fenestrations
There is a dearth of literature on methods for reducing shunt complications and alternatives to shunting for PIH. A study of the use of VSGS in PIH found that compared to patients with PHH, VSGS complication rates are comparable between the two groups except with device infection, for which PIH patients experienced higher rates [63]. ETV has had encouraging results in patients with PIH, though patients need to be carefully selected based on ventricular system anatomy. In a study of non-shunted and shunt-dependent patients with PHH or PIH, the success rate of ETV in causing durable resolution of hydrocephalus was 60 % in PIH patients [64].
Recently, ETV has received attention for its promise as a cost-effective therapy for PIH in the developing world. A study of long-term outcomes in 149 Ugandan infants with PIH compared treatment with ETV with or without CPC and those treated with permanent shunt insertion and found no significant differences in survival between the two groups. Though ETV patients experienced a lower incidence of functional dependence and disability, this was attributed mostly to treatment selection and shunting of infants with the most severe cases of PIH. The authors cited that ETV success was dependent on the absence of scarring within the prepontine cistern [65].
10.2.4 Long-Term Outcomes of PIH
The neurodevelopmental outcomes of patients with PIH vary widely, but studies have found that these patients experience higher rates of epilepsy and cognitive and functional impairment and experience lower quality of life compared to pediatric patients with hydrocephalus of other etiologies [38, 66–71]. Most of these studies only include a small number of PIH patients; in a 2007 questionnaire-based study with four PIH patients, one patient attended normal primary school, two patients were without motor disability, and one patient eventually developed epilepsy. Outcomes were assessed with the Hydrocephalus Outcomes Questionnaire; overall, there were no significant differences between PIH patients and other hydrocephalus patients in the cognitive, physical, and social-emotional health domains [66, 72]. A study of hydrocephalus outcomes in adulthood found that patients with childhood post-meningitic hydrocephalus were at higher risk for developing cognitive impairment compared to those patients who developed hydrocephalus at older ages or as a result of a focal brain lesion. Though many studies support the idea that PIH itself is associated with poor functional outcomes, few studies have examined the impact of PIH on long-term shunt outcomes and the effects of shunting and shunt complications on neurodevelopment.
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