Minimally invasive approaches for the management of intraventricular hemorrhage

Treatment of cerebral ventriculitis with a new self-irrigating catheter system: narrative review and case series

Cerebral ventriculitis is a life-threatening condition that requires prompt and effective pharmacological intervention. The continuous irrigation of the cerebral ventricles with fluid and its drainage is a system to remove toxic substances and infectious residues in the ventricles; this system is called IRRAflow®. We used this kind of ventricular irrigation/drainage system to treat two patients with post-surgical cerebral ventriculitis and a patient with bacterial meningitis complicated with ventriculitis. In this case series, we discuss the management of these three cases of cerebral ventriculitis: we monitored cytochemical parameters and cultures of the cerebrospinal fluid of patients during their ICU stay and we observed a marked improvement after irrigation and drainage with IRRAflow® system. Irrigation/drainage catheter stay, mode settings, and antibiotic therapies were different among these three patients, and neurological outcomes were variable, according to their underlying pathologies. IRRAflow® system can be applied also in other types of brain injury, such as intraventricular hemorrhage, intracranial abscess, subdural hematomas, and intracerebral hemorrhage, with the aim to remove the hematic residues and enhance the functional recovery of the patients. IRRAflow® seems a promising and useful tool to treat infectious and hemorrhagic diseases in neuro-intensive care unit.

Use of emerging technologies to enhance the treatment paradigm for spontaneous intraventricular hemorrhage

The presence of intraventricular hemorrhage (IVH) portends a worse prognosis in patients presenting with spontaneous intracerebral hemorrhage (ICH). Intraventricular hemorrhage increases the rates of hydrocephalus, ventriculitis, and long-term shunt dependence. Over the past decade, novel medical devices and protocols have emerged to directly treat IVH. Presently, we review new technological adaptations to treating intraventricular hemorrhage in an effort to focus further innovation in treating this morbid neurosurgical pathology. We summarize current and historical treatments as well as innovations in IVH including novel procedural techniques, use of the Integra Surgiscope, use of the Artemis evacuator, use of BrainPath, novel catheter technology, large bore external ventricular drains, the IRRAflow, the CerebroFlo, and the future directions of the field. Technology and medical devices for both surgical and nonsurgical methods are advancing the treatment of IVH. With many promising new technologies on the horizon, prospects for improved clinical care for IVH and its etiologies remain hopeful.

Heron-mouth neuroendoscopic sheath-assisted neuroendoscopy plays critical roles in treating hypertensive intraventricular hemorrhage

Introduction

Neuroendoscopy is widely applied for treating hypertensive intracerebral hemorrhage.

Aim

To explore the effects of heron-mouth neuroendoscopic sheath-assisted neuroendoscopy on treatment of hypertensive intraventricular hemorrhage.

Material and methods

A type of heron-mouth neuroendoscopic sheath combining the advantages of minimally invasive columnar endoscopic sheath and open operation methods was designed. The end of sheath catheter could be dilated if necessary, without increasing risk of cortex injury. Heron-mouth neuroendoscopic sheath-assisted neuroendoscopy was applied in treatment of hypertensive intraventricular hemorrhage. A total of 19 patients with hypertensive intraventricular hemorrhage were selected and divided into an external ventricular drainage + urokinase group and a neuroendoscopy group. Hematoma clearance rate, surgical time, ventricular drainage time, intracranial infection, hydrocephalus and Glasgow Outcome Score (GOS) at 3 months after the operation were compared between two groups.

Results

Hematoma clearance rate, ventricular drainage time, mortality rate and GOS at 3 months after surgery in the neuroendoscopy group were significantly better compared to those in the external ventricular drainage + urokinase group (p < 0.05). Postoperative complications, including intracranial infection hydrocephalus and pulmonary infection in the neuroendoscopy group, were less numerous compared to those in the external ventricular drainage + urokinase group, but without statistical significance (p > 0.05). However, surgical time was significantly longer in the neuroendoscopy group compared to that in the external ventricular drainage + urokinase group (p < 0.05). There was no significant difference in incidence rate of hydrocephalus between the two groups (p > 0.05).

Conclusions

Clinical effects of heron-mouth neuroendoscopic sheath-assisted neuroendoscopy were better than those of external ventricular drainage combining urokinase dissolution in treating hypertensive intraventricular hemorrhage.