April 14th, 2023
This protocol demonstrates a unique mouse model of asphyxia cardiac arrest that does not require chest compression for resuscitation. This model is useful for monitoring and imaging the dynamics of brain physiology during cardiac arrest and resuscitation.
Cardiac arrest affects over half a million people in the US every year, leading to impaired neurological function primarily caused by hypoxic-ischemic brain injury. To develop better treatments, we aim to understand how cardiac arrest affects brain physiology, including microcirculatory blood flow and oxygen use, through experimental research. Advanced imaging and the monitoring methods have been established to investigate the cerebral blood flow after cardiac arrest.
However, obtaining a complete image of cerebral circulation during cardiac arrest and early resuscitation remains challenging. Our protocol involves simulating clinical asphyxia-induced cardiac arrest in mice, followed by recitation without chest compressions. This model enables the use of advanced imaging methods to study brain physiology in mice throughout the cardiac arrest process.
This model does not require complex surgical interventions, and is relatively easier to perform. More importantly, during cardiac arrest and resuscitation, animals can be kept in prone proposition with minimal animal movement, which greatly facilitates the use of various imaging modalities. The impact of cardiac arrest and its treatment strategies, such as epinephrine administration, brain hemodynamics and the neurological function, is not yet fully understood.
Our mouse model is ideal for investigating the dynamic alterations in brain circulation, vascular responses, and brain tissue oxygenation that occur during a cardiac arrest and resuscitation.
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This study presents a mouse model of asphyxia cardiac arrest that facilitates the monitoring of brain physiology without the need for chest compressions. It enables advanced imaging techniques to explore cerebral dynamics during cardiac arrest and subsequent resuscitation.
Reliable preclinical models that enable real-time brain imaging during cardiac arrest and resuscitation are critical for de-risking neuroprotective strategies in biopharma R&D. This mouse asphyxia cardiac arrest model supports mechanistic interrogation of cerebral blood flow, vascular dynamics, and oxygenation, directly informing target validation and translational biomarker development. Its streamlined workflow and compatibility with advanced imaging position it as a reusable platform for early discovery and preclinical pipeline integration.
This model bridges early discovery and preclinical validation by enabling real-time, quantitative assessment of brain physiology during cardiac arrest and resuscitation.