Brief update on hemodynamic responses in animal models of neonatal stroke and hypoxia–ischemia

AbstractNeurovascular coupling is the process by which neural activity causes localised changes in cerebral blood flow. Impaired neurovascular coupling has been suggested as an early pathogenic factor in Alzheimer’s disease (AD), and if so, could serve as an early biomarker of cerebral pathology. We have established an anaesthetic regime in which evoked hemodynamic responses are comparable to those in awake mice. This protocol was adapted to allow repeated measurements of neurovascular function over three months in the hAPP-J20 mouse model of AD (J20-AD) and wild-type (WT) controls. Animals were 9-12 months old at the start of the experiment, which is when deficits due to the disease condition would be expected. Mice were chronically prepared with a cranial window through which optical imaging spectroscopy (OIS) was used to generate functional maps of the cerebral blood volume and saturation changes evoked by whisker stimulation and vascular reactivity challenges. Unexpectedly, the hemodynamic responses were largely preserved in the J20-AD group. This result failed to confirm previous investigations using the J20-AD model. However, a final acute electrophysiology and OIS experiment was performed to measure both neural and hemodynamic responses concurrently. In this experiment, previously reported deficits in neurovascular coupling in the J20-AD model were observed. This suggests that J20-AD mice may be more susceptible to the physiologically stressing conditions of an acute experimental procedure compared to WT animals. These results therefore highlight the importance of experimental procedure when determining the characteristics of animal models of human disease.Significance StatementUsing a chronic anaesthetised preparation, we measured hemodynamic responses evoked by sensory stimulation and respiratory gases in the J20-AD mouse model of Alzheimer’s Disease over a period of 3 months. We showed that neurovascular responses were preserved compared to age matched wildtype controls. These results failed to confirm previous investigations reporting a marked reduction of neurovascular coupling in the J20-AD mouse model. However, when our procedure involved acute surgical procedures, previously reported neurovascular deficits were observed. The effects of acute electrode implantation were caused by disturbances to baseline physiology rather than a consequence of the disease condition. These results highlight the importance of experimental procedure when determining the characteristics of animal models of human disease.

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Mechanisms of brain damage in animal models of hypoxia–ischemia in newborns

Fetal and Neonatal Brain Injury ◽

10.1017/cbo9780511544774.004 ◽

2003 ◽

pp. 30-57 ◽

Cited By ~ 3

Author(s):

Lee J. Martin

Keyword(s):

Animal Models ◽

Brain Damage ◽

Hypoxia Ischemia

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Perinatal hypoxic-ischemic brain injury in large animal models: Relevance to human neonatal encephalopathy

Journal of Cerebral Blood Flow & Metabolism ◽

10.1177/0271678x18797328 ◽

2018 ◽

Vol 38 (12) ◽

pp. 2092-2111 ◽

Cited By ~ 17

Author(s):

Raymond C Koehler ◽

Zeng-Jin Yang ◽

Jennifer K Lee ◽

Lee J Martin

Keyword(s):

Brain Injury ◽

Animal Models ◽

Cerebral Hypoperfusion ◽

Large Animal ◽

Perinatal Hypoxia ◽

Cellular Mechanisms ◽

Fetal Sheep ◽

Newborn Piglets ◽

Large Animal Models ◽

Hypoxia Ischemia

Perinatal hypoxia-ischemia resulting in death or lifelong disabilities remains a major clinical disorder. Neonatal models of hypoxia-ischemia in rodents have enhanced our understanding of cellular mechanisms of neural injury in developing brain, but have limitations in simulating the range, accuracy, and physiology of clinical hypoxia-ischemia and the relevant systems neuropathology that contribute to the human brain injury pattern. Large animal models of perinatal hypoxia-ischemia, such as partial or complete asphyxia at the time of delivery of fetal monkeys, umbilical cord occlusion and cerebral hypoperfusion at different stages of gestation in fetal sheep, and severe hypoxia and hypoperfusion in newborn piglets, have largely overcome these limitations. In monkey, complete asphyxia produces preferential injury to cerebellum and primary sensory nuclei in brainstem and thalamus, whereas partial asphyxia produces preferential injury to somatosensory and motor cortex, basal ganglia, and thalamus. Mid-gestational fetal sheep provide a valuable model for studying vulnerability of progenitor oligodendrocytes. Hypoxia followed by asphyxia in newborn piglets replicates the systems injury seen in term newborns. Efficacy of post-insult hypothermia in animal models led to the success of clinical trials in term human neonates. Large animal models are now being used to explore adjunct therapy to augment hypothermic neuroprotection.

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