Intracerebral Hemorrhage Models in Rat: Comparing Collagenase to Blood Infusion

MacLellan, Crystal L.; Silasi, Gergely; Poon, Candice C.; Edmundson, Carmen Lynne; Buist, Richard; Peeling, James; Colbourne, Frederick

doi:10.1038/sj.jcbfm.9600548

Cited by 314 publications

(391 citation statements)

References 37 publications

(66 reference statements)

Supporting

Mentioning

358

Contrasting

Unclassified

Order By: Relevance

“…29 Some of the effects of bICH and cICH in the mouse are distinct to that seen in the rat. Behavioral deficits persist for a greater period in rat cICH 26,30 than in the mouse. Unlike in rat, sensorimotor deficits as measured by gait in the mouse resolve sooner in cICH than bICH.…”

Section: Discussionmentioning

confidence: 99%

“…In rat cICH, there is loss of connections to the striatum with a modest reduction in neurons that project from the substantia nigra to the striatum, 31 a decrease in cortical projections from the ipsilateral motor cortex 32 and thinning of ipsilateral cortex. 26 There are no reports of axonal loss in the rat in bICH. This greater loss of axonal projections to the striatum in cICH in the mouse could be due to greater local tissue damage after the hemorrhage.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Mouse Intracerebral Hemorrhage Models Produce Different Degrees of Initial and Delayed Damage, Axonal Sprouting, and Recovery

Barratt

Lanman

Carmichael

2014

J Cereb Blood Flow Metab

View full text Add to dashboard Cite

The mechanisms of delayed damage and recovery after intracerebral hemorrhage (ICH) remain poorly defined. Two rodent models of ICH are commonly used: injection of the enzyme collagenase (cICH) and injection of autologous blood (bICH). In mice, we compared the effects of these two models on initial and delayed tissue damage, motor system connections, and behavioral recovery. There is no difference in lesion size between models. Injection of autologous blood causes greater mass effect and early mortality. However, cICH produces greater edema, inflammation, and cell death. Injection of the enzyme collagenase causes greater loss of cortical connections and secondary shrinkage of the striatum. Intracerebral hemorrhage occurs within the motor system connections of the striatum. Mapping of the projections of the forelimb motor area shows a significant sprouting in motor cortex projections only in cICH. Both models of ICH produce deficits in forelimb motor control. Behavioral recovery occurs by 5 weeks in cICH and 9 weeks in bICH. In summary, cICH and bICH differ in almost every facet of initial and delayed stroke pathophysiology, with cICH producing greater initial and secondary tissue damage and greater motor system axonal sprouting than bICH. Motor recovery occurs in both models, suggesting that motor system axonal sprouting in cICH is not causally associated with recovery.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Mouse Intracerebral Hemorrhage Models Produce Different Degrees of Initial and Delayed Damage, Axonal Sprouting, and Recovery

Barratt

Lanman

Carmichael

2014

J Cereb Blood Flow Metab

View full text Add to dashboard Cite

show abstract

“…The development of cerebral edema has a stronger temporal association with neurologic deterioration in the autologous blood injection model compared with the collagenase model, and is slower and more protracted in human compared with experimental ICH (Butcher et al, 2004;Gebel et al, 2002a;Hua et al, 2003;Qureshi et al, 2009;Rosenberg et al, 1990;Yang et al, 1994)-as is red cell resorption (Butcher et al, 2004;MacLellan et al, 2008;Xi et al, 2006). Further, when matched for hematoma size, the total loss of brain tissue can be twice as much in the collagenase model compared with the blood injection model (MacLellan et al, 2008). All of these differences suggest the need for the trialing of putative neuroprotectants with multiple models and outcome measures.…”

Section: Pathophysiologymentioning

confidence: 99%

Experimental Intracerebral Hemorrhage: Avoiding Pitfalls in Translational Research

Kirkman

Allan

Parry‐Jones

2011

J Cereb Blood Flow Metab

View full text Add to dashboard Cite

Intracerebral hemorrhage (ICH) has the highest mortality of all stroke subtypes, yet treatments are mainly limited to supportive management, and surgery remains controversial. Despite significant advances in our understanding of ICH pathophysiology, we still lack preclinical models that accurately replicate the underlying mechanisms of injury. Current experimental ICH models (including autologous blood and collagenase injection) simulate different aspects of ICH-mediated injury but lack some features of the clinical condition. Newly developed models, notably hypertension-and oral anticoagulant therapy-associated ICH models, offer added benefits but further study is needed to fully validate them. Here, we describe and discuss current approaches to experimental ICH, with suggestions for changes in how this condition is studied in the laboratory. Although advances in imaging over the past few decades have allowed greater insight into clinical ICH, there remains an important role for experimental models in furthering our understanding of the basic pathophysiologic processes underlying ICH, provided limitations of animal models are borne in mind. Owing to differences in existing models and the failed translation of benefits in experimental ICH to clinical practice, putative neuroprotectants should be trialed in multiple models using both histological and functional outcomes until a more accurate model of ICH is developed.

show abstract

“…1 and 3f-i). Although an established intracerebral hemorrhage rat model typically delivers 0.2 U of collagenase in 1 mL of saline (46,47), the smaller doses and volumes used in this study reflect an attempt to induce smaller and more focal hemorrhagic legions to better model BMB. However, it appears the collagenase injections caused bleeding that is more spatially diffuse than is characteristic of real BMB which generally originate from a single ruptured vessel (25).…”

Section: Discussionmentioning

confidence: 99%

In vivo iron quantification in collagenase‐induced microbleeds in rat brain

McAuley

Schrag

Barnes

et al. 2011

Magnetic Resonance in Med

View full text Add to dashboard Cite

Brain microbleeds (BMB) are associated with chronic and acute cerebrovascular disease. Because BMB present in the brain is a source of potentially cytotoxic iron proportional to the volume of extravasated blood, BMB iron content is a potentially valuable biomarker both to assess tissue risk and small cerebral vessel health. We recently reported methods to quantify focal iron sources using phase images that were tested in phantoms and BMB in postmortem tissue. In this study, we applied our methods to small hemorrhagic lesions induced in the in vivo rat brain using bacterial collagenase. As expected by theory, measurements of geometric features in phase images correlated with lesion iron content measured by graphite furnace atomic absorption spectrometry. Iron content estimation following BMB in an in vivo rodent model could shed light on the role and temporal evolution of ironmediated tissue damage and efficacy of potential treatments in cerebrovascular diseases associated with BMB. Magn Reson Med 67:711-717,

show abstract

Intracerebral Hemorrhage Models in Rat: Comparing Collagenase to Blood Infusion

Cited by 314 publications

References 37 publications

Mouse Intracerebral Hemorrhage Models Produce Different Degrees of Initial and Delayed Damage, Axonal Sprouting, and Recovery

Mouse Intracerebral Hemorrhage Models Produce Different Degrees of Initial and Delayed Damage, Axonal Sprouting, and Recovery

Experimental Intracerebral Hemorrhage: Avoiding Pitfalls in Translational Research

In vivo iron quantification in collagenase‐induced microbleeds in rat brain

Contact Info

Product

Resources

About