Neural injury of the Papez circuit following hypoxic–ischemic brain injury : A case report

Recently developed methods to extract the persistent angular structure (PAS) of axonal fibre bundles from diffusion-weighted magnetic resonance imaging (MRI) data are applied to drive probabilistic fibre tracking, designed to provide estimates of anatomical cerebral connectivity. The behaviour of the PAS function in the presence of realistic data noise is modelled for a range of single and multiple fibre configurations. This allows probability density functions (PDFs) to be generated that are parametrized according to the anisotropy of individual fibre populations. The PDFs are incorporated in a probabilistic fibre-tracking method to allow the estimation of whole-brain maps of anatomical connection probability. These methods are applied in two exemplar experiments in the corticospinal tract to show that it is possible to connect the entire primary motor cortex (M1) when tracing from the cerebral peduncles, and that the reverse experiment of tracking from M1 successfully identifies high probability connection via the pyramidal tracts. Using the extracted PAS in probabilistic fibre tracking allows higher specificity and sensitivity than previously reported fibre tracking using diffusion-weighted MRI in the corticospinal tract.

The fornix is a discrete white matter tract bundle that is critical for normal cognitive functioning. Although clearly visualized at magnetic resonance imaging, its involvement in pathologic processes is often overlooked. Certain disease processes show a predilection for involvement of the fornix; in other pathologic conditions, its involvement is a rare but recognized finding. As part of the Papez circuit, it is critical in formation of memory, with damage or disease resulting in anterograde amnesia. Many different pathologic conditions can affect the fornix. Midline tumors such as gliomas or lymphoma can infiltrate it. As part of the limbic system, it may be affected by herpes simplex encephalitis. Involvement by inflammatory conditions such as multiple sclerosis may illustrate its importance in global cognitive function. An appreciation of forniceal atrophy may aid in assessment of mesial temporal sclerosis. Metabolic conditions such as Wernicke encephalopathy have been reported to involve it. The original discoveries of its role in memory arose from surgical trauma, but as a midline structure, it is susceptible to the shearing forces of diffuse axonal injury. Infarction of the fornix is rare but can result in acute amnesic syndromes. Its role in degenerative conditions such as Alzheimer disease and psychiatric conditions such as schizophrenia is a topic of research interest. Recognition of involvement of the fornix by various pathologic processes may aid in explaining the troubling clinical symptoms of amnesia.

Although cardiac arrest (CA) is commonly cited as a cause of amnesia, patients referred to the authors' center with a diagnosis of "amnesia" after CA rarely have isolated memory deficits. To determine whether CA is a cause of pure amnesia and to assess patterns of cognitive deficits after CA. The authors used cognitive assessment of 11 consecutive patients referred for memory deficits after CA, targeted at deficit domains identified in the literature reviews, and analysis of specific case reports and prospective studies of cognition after CA. The most common pattern of impairment in their patients was a combination of memory and motor deficits with variable executive impairment. No patient had isolated memory impairment. The case reports do not support the claim that isolated amnesia is a residual of CA; most cases of isolated amnesia are caused by subacute episodes of anoxia or excitotoxic injury. The prospective reports identify highly variable patterns of impairment, but isolated amnesia remains rare. Diffuse, sudden ischemic-hypoxic injury caused by cardiac arrest (CA) does not preferentially damage memory systems. Subacute or stepwise hypoxic or excitotoxic injury may cause isolated hippocampal injury and amnesia. The common pattern of impairment in the postacute phase after CA is a combination of memory, subtle motor, and variable executive deficits.