Canine and Feline Epilepsy. Luisa De Risio
Читать онлайн книгу.
angiography improve the sensitivity and specificity of the diagnosis of peracute and acute CVA (Garosi, 2010; Cervera et al., 2011).
The MRI features of ischaemic CVA include an intraparenchymal lesion within a vascular territory which:
• is well demarcated from the surrounding normal brain tissue;
• involves primarily the grey matter;
• causes minimal or no mass effect;
• compared to normal grey matter, appears:
• hyperintense on T2-weighted, fluid-attenuated inversion recovery (FLAIR) and diffusion-weighted images (DWIs) (Fig. 5.1a, b, e; 5.2a, b, e);
• hypointense on a synthesized apparent diffusion coefficient (ADC) map derived from two or more diffusion-weighted images;
• iso- to hypointense on T1-weighted images (Fig. 5.1c; 5.2c);
• shows variable contrast-enhancement (usually minimal, peripheral or heterogeneous) 7 to 10 days after onset of neurological signs.
The MRI features of haemorrhagic CVA vary depending on several intrinsic (time from ictus, oxygenation state of haemoglobin, source, size and location of haemorrhage) and extrinsic (pulse sequence and field strength) factors (Table 5.1) (Bradley, 1993; Thomas et al., 1997). Haemorrhage in areas with high ambient oxygen (ventricles; epidural, subdural and subarachnoid space) ‘ages’ more slowly than parenchymal haemorrhage, with a resultant change in time course of haemoglobin degradation. Contrast enhancement due to neovascularization in the surrounding brain tissue can occur 7–14 days after intraparenchymal haemorrhagic CVA and may be minimal, heterogenous or peripheral to ring-like.
Cerebrospinal fluid (CSF) analysis in animals with CVA is either normal, or shows aspecific changes such as mild mononuclear or neutrophilic pleocytosis, elevated protein concentration and xanthocromia. CSF should not be collected in animals with coagulopathy or increased ICP.
Once a probable diagnosis of CVA has been achieved (based on clinical presentation, MRI of the brain, and, if possible, CSF analysis), further diagnostic investigations should be performed in attempt to identify an underlying cause of ischaemic or haemorrhagic CVA (Box 5.2).
A definitive diagnosis of CVA can be reached histopathologically (Plate 3).
Treatment
Treatment of CVA focuses on prevention of secondary brain injury or complications, such as increased ICP (see management of traumatic brain injury) or seizures, and on the underlying disease. For further details on all the aspects of CVA treatment the reader is directed to more comprehensive descriptions (Garosi, 2010). Anti-epileptic treatment is performed as for other types of structural brain disorders (see section on post-stroke seizures and epilepsy, introduction to this chapter and Chapters 12–24).
Prognosis
Most dogs recover within weeks after the onset of ischaemic CVA with only supportive care (Garosi et al., 2005a). Prognosis depends on the severity of the neurological dysfunction, occurrence of complications and the underlying cause of CVA, if identified. In a retrospective study on 33 dogs with MRI or histologic diagnosis of ischaemic CVA, no association was identified between type (lacunar or territorial) or location (telencephalic, thalamic/midbrain, cerebellar) of infarct and patient outcome. Dogs with concurrent medical conditions had significantly shorter survival times than those with no identifiable medical condition and were significantly more likely to suffer from recurrent neurologic signs because of subsequent infarcts. In a retrospective study on 75 dogs with an MRI diagnosis of nontraumatic intracranial haemorrhage, outcome was poor in the majority of dogs with hypertension (Lowrie et al., 2012).
Table 5.1. Change of appearance of intracranial haemorrhage over time (Bradley, 1993; Thomas et al., 1997).
Box 5.2. Diagnostic investigations to identify the underlying aetiology of ischaemic or haemorrhagic CVA.
Diagnostic investigations to identify the underlying aetiology of ischaemic CVA:
• Serial blood pressure measurements;
• Haematology;
• Serum biochemistry profile;
• Urinalysis;
• Urine protein/creatinine ratio;
• Serum antithrombin III activity;
• D-dimers;
• Thromboelestography;
• Infectious disease testing (e.g. serology, PCR);
• Endocrine testing for hyperadrenocorticism, thyroid diseases, diabetes mellitus and pheochromocytoma;
• Thoracic radiographs;
• Abdominal ultrasound;
• Echocardiography and electrocardiography.
Diagnostic investigations to identify the underlying aetiology of haemorrhagic CVA:
• Serial blood pressure measurements;
• Haematology;
• Serum biochemistry profile;
• Buccal mucosa bleeding time;
• Prothrombin time (PT);
• Activated partial thromboplastin time (APTT);
• Infectious disease testing (e.g. serology, PCR);
• Thoracic radiographs;
• Abdominal ultrasound;
• Faecal analysis to investigate parasitic infestation (such as A. vasorum).
Post-stroke epilepsy has a negative effect on stroke recovery and quality of life in people (Arntz, 2013).
Inflammatory/infectious
Inflammatory disease of the CNS can be classified as infectious (when caused by a known or suspected infectious agent) or immune-mediated (when the underlying aetiology is unknown and an immune-mediated process is suspected). A degree of CNS inflammation may occur also with brain neoplasia, infarction or trauma. This section will focus on infectious and presumed immune-mediated disorders. Inflammatory disease of the CNS may affect the brain parenchyma (encephalitis), the meninges (meningitis) and the spinal cord (myelitis). Inflammatory CNS disorders commonly affect young to middle-aged animals, although animals of any age and gender can be affected. Certain infectious disorders occur exclusively or predominately in certain geographic areas (Nghiem and Schatzberg, 2010). The majority of reported inflammatory CNS diseases in dogs and cats are outlined in Tables 5.3,