Fluid-percussion model of mechanical brain injury in the cat

Sullivan, Humbert G.; Martinez, Jullo; Becker, Donald P.; Miller, J. D.; Griffith, R. V.; Wist, Abund O.

doi:10.3171/jns.1976.45.5.0520

Cited by 322 publications

(116 citation statements)

References 18 publications

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“…The main advantages of the fluid percussion model are similar to that described for the CCI model in that it induces graded levels of brain injury and produces axonal injuries and contusions, as well as impaired neurologic motor function and cognitive deficits (Dixon et al, 1987;McIntosh et al, 1987;Yaghmai and Povlishock, 1992). It has also been modified and widely applied (Sullivan et al, 1976;Povlishock et al, 1983;Dixon et al, 1987;McIntosh et al, 1989;Yamaki et al, (1994) to other animal species including the rat, dog, rabbit, cat and swine and has been used in combination with microdialysis in the rat Busto et al, 1987;Kawamata et al, 1995;Katayama et al, 1990). Also, fluid flow characteristics (i.e.…”

Section: Fluid Percussion Injurymentioning

confidence: 95%

Animal models of traumatic brain injury: A critical evaluation

O’Connor

Smyth

Gilchrist

2011

Pharmacology & Therapeutics

142

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Section: Fluid Percussion Injurymentioning

confidence: 95%

Animal models of traumatic brain injury: A critical evaluation

O’Connor

Smyth

Gilchrist

2011

Pharmacology & Therapeutics

142

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“…Adult rats were infused with extracellular tracers and subjected to moderate central (midline) fluid percussion injury (FPI) consistent with previously described protocols (Sullivan et al, 1976;Dixon et al, 1987). Briefly, 23 male Sprague Dawley rats weighing 390 Ϯ 22 gm (mean Ϯ SD) were surgically prepared for the induction of FPI.…”

Section: Methodsmentioning

confidence: 99%

Identification and Characterization of Heterogeneous Neuronal Injury and Death in Regions of Diffuse Brain Injury: Evidence for Multiple Independent Injury Phenotypes

Singleton¹,

Povlishock²

2004

J. Neurosci.

109

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Diffuse brain injury (DBI) is a consequence of traumatic brain injury evoked via rapid acceleration-deceleration of the cranium, givingrise to subtle pathological changes appreciated best at the microscopic level. DBI is believed to be comprised by diffuse axonal injury and other forms of diffuse vascular change. The potential, however, that the same forces can also directly injure neuronal somata in vivo has not been considered. Recently, while investigating DBI-mediated perisomatic axonal injury, we identified scattered, rapid neuronal somatic necrosis occurring within the same domains. Moving on the premise that these cells sustained direct somatic injury as a result of DBI, we initiated the current study, in which rats were intracerebroventricularly infused with various high-molecular weight tracers (HMWTs) to identify injury-induced neuronal somatic plasmalemmal disruption. These studies revealed that DBI caused immediate, scattered neuronal somatic plasmalemmal injury to all of the extracellular HMWTs used. Through this approach, a spectrum of neuronal change was observed, ranging from rapid necrosis of the tracer-laden neurons to little or no pathological change at the light and electron microscopic level. Parallel double and triple studies using markers of neuronal degeneration, stress, and axonal injury identified additional injured neuronal phenotypes arising in close proximity to, but independent of, neurons demonstrating plasmalemmal disruption. These findings reveal that direct neuronal somatic injury is a component of DBI, and diffuse trauma elicits a heretofore-unrecognized multifaceted neuronal pathological change within the CNS, generating heterogeneous injury and reactive alteration within both axons and neuronal somata in the same domains.

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“…They have been essential for understanding the function of astrocytes in health including their function in metabolism, neurotransmitter recycling, and calcium signaling and to mimic various disease situations such as injury, hypoxia, or neurodegenerative diseases (2,3,51,65,76,128,157,206,230,265). Traditional two-dimensional culture systems for astrocytes, however, have a number of limitations that include highly reduced morphological complexity of astrocytes upon their transfer in vitro and undesired baseline reactivity of astrocytes upon in vitro culture (128,186).…”

Section: Starting With a Healthy Brainmentioning

confidence: 99%

Astrocyte Reactivity and Reactive Astrogliosis: Costs and Benefits

Pekny

Pekna

2014

Physiological Reviews

720

576

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Astrocytes are the most abundant cells in the central nervous system (CNS) that provide nutrients, recycle neurotransmitters, as well as fulfill a wide range of other homeostasis maintaining functions. During the past two decades, astrocytes emerged also as increasingly important regulators of neuronal functions including the generation of new nerve cells and structural as well as functional synapse remodeling. Reactive gliosis or reactive astrogliosis is a term coined for the morphological and functional changes seen in astroglial cells/astrocytes responding to CNS injury and other neurological diseases. Whereas this defensive reaction of astrocytes is conceivably aimed at handling the acute stress, limiting tissue damage, and restoring homeostasis, it may also inhibit adaptive neural plasticity mechanisms underlying recovery of function. Understanding the multifaceted roles of astrocytes in the healthy and diseased CNS will undoubtedly contribute to the development of treatment strategies that will, in a context-dependent manner and at appropriate time points, modulate reactive astrogliosis to promote brain repair and reduce the neurological impairment.

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Fluid-percussion model of mechanical brain injury in the cat

Cited by 322 publications

References 18 publications

Animal models of traumatic brain injury: A critical evaluation

Animal models of traumatic brain injury: A critical evaluation

Identification and Characterization of Heterogeneous Neuronal Injury and Death in Regions of Diffuse Brain Injury: Evidence for Multiple Independent Injury Phenotypes

Astrocyte Reactivity and Reactive Astrogliosis: Costs and Benefits

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