Remote cerebellar hemorrhages (RCHs) are rare complications of intracranial or spinal interventions. We describe a patient with an RCH that occurred after a frontal lobectomy for an intracranial tumor. A 41-year-old female patient with a headache and partial seizures underwent a right frontal lobectomy upon detection of a right frontal mass. An RCH (zebra sign) was detected on a control cranial computed tomography (CT), which was performed upon detection of frontal lobe syndrome and mild ataxia in the patient postoperatively. Although the mechanism underlying the occurrence of RCHs after intracranial procedures is not clear, they have been attributed to an imbalance between intravascular pressure and cerebrospinal fluid (CSF) due to rapid drainage of the fluid, causing bleeding in the cerebellar parenchyma. Generally, bilateral superior cerebellar injury produces parallel flat hyperdense areas known as the zebra sign on CT. The prognosis of a cerebellar hemorrhage is generally good, and it can be treated with a conservative approach. Controlled drainage of CSF during surgery and selecting an appropriate surgical position perioperatively will reduce the risk of RCHs.
Intracranial hemorrhages in different intracranial regions after intracranial procedures are extremely rare and usually fatal. The incidence of hemorrhages after intracranial surgery is 0.2% - 4.9% [
We describe a patient who underwent surgery for an intracranial tumor and developed a remote cerebellar hemorrhage (RCH) in the postoperative period.
A 41-year-old female patient was admitted to our outpatient clinic due to partial seizures, which had started 3 months earlier. The seizures had abrupt onset and termination, and they usually occurred at night, causing the patient to shout out. They also caused oral paralysis, tonic contractions in the upper limbs, and headaches, which had begun 8 months earlier and gradually increased. The patient’s medical history was unremarkable, and a neurological examination was normal. Laboratory tests were normal, except for the presence of hypercholesterolemia. Scalp electroencephalography (EEG) was performed as anamnesis obtained from the family suggested that she was prone to epileptic seizures. The scalp EEG revealed sharp waves, indicating frontal lobe epilepsy. The patient was hospitalized due to the presence of a mass lesion in the right frontal region observed on cranial magnetic resonance imaging (MRI) and CT of the brain obtained for investigating the etiology of the new onset epileptic focus (
After craniotomy, bleeding in the surgical field and nearby areas are common complications. However, RCHs are quite rare. RCHs are usually seen in patients aged between 30 and 60 years and are quite rare in children [
RCHs are seen in 0.6% of cases following supratentorial interventions and 0.15% - 4.9% of cases following temporal lobectomy surgeries [
The exact mechanism of RCH is not known, but several possibilities have been proposed. Antiagregan and aspirin use are possible risk factors, in addition to age, gender, transient hypertensive episodes, coagulation disorders, arterial malformations, and sinus thrombosis. However, Marquardt et al. [
Most theories relating to the cause of RCHs link them to venous systemic pathology. Chadduck reported that an imbalance between intravascular pressure and CSF could lead to a cerebellar parenchymal hemorrhage. Many authors have attributed the sagging of the cerebellum following spinal surgery to CSF discharge and to injury that occurred during the surgery [
Bleeding usually extends to the tentorium and the neck of the vermis, at the top of the cerebellum. Characteristically, it is caused by bilateral injury of the superior cerebellar vein. RCHs mostly occur in the tentorium wall of cerebellar parenchyma and in the dentate nucleus region [
The treatment of patients with a RCH should be planned according to the severity of the cerebellar hemorrhage and the types of complications present. A cerebellar hemorrhage often has a good prognosis. Small cerebellar hemorrhages can be treated with a conservative approach and followed up with radiological methods. In 10% - 15% of patients, severe bleeding occurs and causes mortality. In such cases, the evacuation of the hematoma, external drainage to prevent the development of hydrocephalus due to compression of the fourth ventricle, and brain stem compression may be required [
In conclusion, a conservative approach is appropriate for a clinically stable patient with an RCH if obstructive hydrocephaly is not present. CSF pressure should be reduced with an external ventricular drainage system if there is pressure on the fourth ventricle and obstructive hydrocephaly and clinical deterioration are present. The hematoma should be evacuated with craniectomy if the brain is directly under pressure [
Although RCHs are well-defined hemorrhages, their underlying mechanisms are not clear, with no one predisposing factor know to be responsible. In common with most current opinions, we believe that they are the result of stress that develops in the veins after the drainage of CSF. We consider that slow discharge of CSF during surgery and the selection of an appropriate surgical position in the perioperative period can reduce the risk of RCHs.