Contralateral dissociation between neural activity and cerebral blood volume during recurrent acute focal neocortical seizures

AbstractObjectiveAtherosclerosis is a major risk factor for dementia. The aims of this study were to determine if experimental atherosclerosis leads to altered neurovascular function and causes neurovascular damage.Approach and ResultsWe analysed cerebral blood volume in male C57BL6/J mice injected with an adeno-associated virus (AAV) vector for mutated proprotein convertase subtilisin/kexin type 9 (PCSK9D377Y) fed a Western diet for 35 weeks to induce atherosclerosis (ATH) and 9-12m male wild-type (WT) C57BL/6J. We imaged blood volume responses to sensory stimulation and vascular reactivity gas challenges in the cortex of the brain through a thinned cranial window using 2D-optical imaging spectroscopy (2D-OIS). Neural activity was also recorded with multi-channel electrodes. Stimulation-evoked cortical haemodynamics, in terms of cerebral blood volume, were significantly reduced in ATH mice compared to WT and evoked neural activity was also significantly lower. However, vascular reactivity as assessed by 10% hypercapnia, remained intact in ATH mice. Immunohistochemistry in ATH mice revealed a reduced number of cortical neurons and pericytes in the cortex, but increased astrogliosis. qRT-PCR revealed significantly enhanced TNFα & IL1β in ATH mice compared to WT as well as significant upregulation of eNOS.ConclusionSystemic atherosclerosis causes significant neurovascular decline by 9m in atherosclerotic mice characterised by reduced neural activity, associated with loss of neurons and subsequent reduced cortical haemodynamics in response to physiological stimulations. The altered neurovascular function in ATH mice is chiefly mediated by TNFα.HighlightsSystemic atherosclerosis leads to significantly reduced stimulus-evoked hemodynamic responses in the cortex by 9m of age in the rAAV8-mPCSK9-D377Y mouse model of atherosclerosis compared to wild-type controls.Reduced cerebral haemodynamics are related to reduced neural activity in the cortex that could be due to a loss of cortical neurons potentially caused by significant TNFa-mediated neuroinflammation.

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Enhanced Cerebral Blood Volume under Normobaric Hyperoxia in the J20-hAPP Mouse Model of Alzheimer’s Disease

10.1101/848713 ◽

2019 ◽

Author(s):

Osman Shabir ◽

Paul Sharp ◽

Monica A Rebollar ◽

Luke Boorman ◽

Clare Howarth ◽

...

Keyword(s):

Alzheimer’S Disease ◽

Alzheimer's Disease ◽

Mouse Model ◽

Blood Volume ◽

Neural Activity ◽

Cerebral Blood Volume ◽

Neurovascular Coupling ◽

Cranial Window ◽

Model Of Alzheimer’S Disease ◽

The Brain

AbstractEarly impairments to neurovascular coupling have been proposed to be a key pathogenic factor in the onset and progression of Alzheimer’s disease (AD). Studies have shown impaired neurovascular function in several mouse models of AD, including the J20-hAPP mouse. In this study, we aimed to investigate early neurovascular changes using wild-type (WT) controls and J20-hAPP mice at 6-9 months of age, by measuring cerebral haemodynamics and neural activity to physiological sensory stimulations. A thinned cranial window was prepared to allow access to cortical vasculature and imaged using 2D-optical imaging spectroscopy (2D-OIS). After chronic imaging sessions where the skull was intact, a terminal acute imaging session was performed where an electrode was inserted into the brain to record simultaneous neural activity. We found that cerebral haemodynamic changes were significantly enhanced in J20-hAPP mice compared with controls in response to physiological stimulations, potentially due to the significantly higher neural activity (hyperexcitability) seen in the J20-hAPP mice. Thus, neurovascular coupling remained preserved under a chronic imaging preparation. Further, under hyperoxia, the baseline blood volume and saturation of all vascular compartments in the brains of J20-hAPP mice were substantially enhanced compared to WT controls, but this effect disappeared under normoxic conditions. This study highlights novel findings not previously seen in the J20-hAPP mouse model, and may point towards a potential therapeutic strategy by driving an increased baseline blood flow to the brain, thereby potentially enhancing the clearance of beta-amyloid.

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