Brain regional vulnerability to anaesthesia-induced neuroapoptosis shifts with age at exposure and extends into adulthood for some regions M. Deng, R.D.

Slides:

Advertisements

Similar presentations

Biphasic Alteration of the Inhibitory Synapse Scaffold Protein Gephyrin in Early and Late Stages of an Alzheimer Disease Model Eva Kiss, Karin Gorgas,

Advertisements

Okadaic-Acid-Induced Inhibition of Protein Phosphatase 2A Produces Activation of Mitogen-Activated Protein Kinases ERK1/2, MEK1/2, and p70 S6, Similar.

K. K. Noguchi, S. A. Johnson, G. A. Dissen, L. D. Martin, F. M

H. Wang, Y. Dong, J. Zhang, Z. Xu, G. Wang, C. A. Swain, Y. Zhang, Z

Propofol-induced apoptosis of neurones and oligodendrocytes in fetal and neonatal rhesus macaque brain C. Creeley, K. Dikranian, G. Dissen, L. Martin,

Volume 77, Issue 5, Pages (March 2013)

Volume 25, Issue 7, Pages (March 2015)

Alternative technique or mitigating strategy for sevoflurane-induced neurodegeneration: a randomized controlled dose-escalation study of dexmedetomidine.

Prevention of seizures and reorganization of hippocampal functions by transplantation of bone marrow cells in the acute phase of experimental epilepsy

Volume 23, Issue 3, Pages (September 2016)

Volume 139, Issue 4, Pages (November 2009)

Depletion of primary cilia in articular chondrocytes results in reduced Gli3 repressor to activator ratio, increased Hedgehog signaling, and symptoms.

J.R. Liu, C. Baek, X.H. Han, P. Shoureshi, S.G. Soriano

Combined treatment with celecoxib and sevoflurane after global cerebral ischaemia has no additive neuroprotective effects in rats J.H. Seo, H.P. Park,

Kevin R. Duffy, Donald E. Mitchell Current Biology

Dexmedetomidine-mediated neuroprotection against sevoflurane-induced neurotoxicity extends to several brain regions in neonatal rats J.F. Perez-Zoghbi,

Volume 59, Issue 4, Pages (August 2008)

Volume 19, Issue 5, Pages (November 2016)

Volume 15, Issue 12, Pages (June 2005)

Brad K. Hulse, Evgueniy V. Lubenov, Athanassios G. Siapas Cell Reports

Isoflurane enhances the malignant potential of glioblastoma stem cells by promoting their viability, mobility in vitro and migratory capacity in vivo

Volume 71, Issue 5, Pages (September 2011)

High Plasticity of New Granule Cells in the Aging Hippocampus

Kevin R. Duffy, Donald E. Mitchell Current Biology

Lineage Tracing Using Cux2-Cre and Cux2-CreERT2 Mice

Volume 24, Issue 5, Pages (May 2016)

Single sevoflurane exposure decreases neuronal nitric oxide synthase levels in the hippocampus of developing rats X. Feng, J.J. Liu, X. Zhou, F.H. Song,

Volume 16, Issue 4, Pages (February 2006)

Yi Zuo, Aerie Lin, Paul Chang, Wen-Biao Gan Neuron

Immune Proteins in Brain Development and Synaptic Plasticity

Molecular Therapy - Methods & Clinical Development

Volume 83, Issue 3, Pages (March 2013)

Different Consequences of β1 Integrin Deletion in Neonatal and Adult Mouse Epidermis Reveal a Context-Dependent Role of Integrins in Regulating Proliferation,

Volume 16, Issue 6, Pages (August 2016)

Imaging Neural Activity Using Thy1-GCaMP Transgenic Mice

Extended Interneuronal Network of the Dentate Gyrus

Volume 3, Issue 3, Pages (September 2014)

High Plasticity of New Granule Cells in the Aging Hippocampus

Volume 2, Issue 2, Pages (February 2014)

Lauren M. Tanabe, Chun-Chi Liang, William T. Dauer Cell Reports

The Role of Polysialic Acid in Migration of Olfactory Bulb Interneuron Precursors in the Subventricular Zone Huaiyu Hu, Henry Tomasiewicz, Terry Magnuson,

Mechanisms and Functional Implications of Adult Neurogenesis

Inhibiting NADPH oxidase protects against long-term memory impairment induced by neonatal sevoflurane exposure in mice Z. Sun, M. Satomoto, Y.U. Adachi,

Impact of Swiprosin-1/Efhd2 on Adult Hippocampal Neurogenesis

Functional Integration of Adult-Born Neurons

Volume 22, Issue 4, Pages (April 2012)

The EGFR Is Required for Proper Innervation to the Skin

Volume 9, Issue 8, Pages (April 1999)

Figure 1 A B GCL NBL ED18.5 PND3 PND6 GCL

Volume 13, Issue 3, Pages (March 2006)

Evidence for an Age-Dependent Decline in Axon Regeneration in the Adult Mammalian Central Nervous System Cédric G. Geoffroy, Brett J. Hilton, Wolfram.

Cerebral oxygen saturation and cardiac output during anaesthesia in sitting position for neurosurgical procedures: a prospective observational study

Volume 57, Issue 2, Pages (January 2008)

Volume 11, Issue 11, Pages (June 2015)

Volume 13, Issue 3, Pages (March 2006)

W. Y. Lee, C. J. Park, T. J. Shin, K. W. Yum, T. G. Yoon, K. S. Seo, H

Volume 40, Issue 3, Pages (October 2003)

Dendrite Development Regulated by the Schizophrenia-Associated Gene FEZ1 Involves the Ubiquitin Proteasome System Yasuhito Watanabe, Konstantin Khodosevich,

Activation of Intrinsic Growth State Enhances Host Axonal Regeneration into Neural Progenitor Cell Grafts Hiromi Kumamaru, Paul Lu, Ephron S. Rosenzweig,

P.J. Moss, W. Huang, J. Dawes, K. Okuse, S.B. McMahon, A.S.C. Rice

Marjorie C. Gondré-Lewis, Robert McGlynn, Steven U. Walkley

Extended Interneuronal Network of the Dentate Gyrus

Vomeronasal Phenotype and Behavioral Alterations in Gαi2 Mutant Mice

Xenon improves long-term cognitive function, reduces neuronal loss and chronic neuroinflammation, and improves survival after traumatic brain injury in.

Apoptotic neurodegeneration and spatial memory are not affected by sedative and anaesthetics doses of ketamine/medetomidine combinations in adult mice

Volume 11, Issue 1, Pages (January 2005)

Francesca Cacucci, Patricia Salinas, Thomas J. Wills Current Biology

PC loss in Nhe6-null mouse cerebellum, female and male.

Figure Myelin binding of high-level MBP IgA antibodies from a patient with MS Myelin binding of high-level MBP IgA antibodies from a patient with MS (A)

Vomeronasal Phenotype and Behavioral Alterations in Gαi2 Mutant Mice

Presentation transcript:

Brain regional vulnerability to anaesthesia-induced neuroapoptosis shifts with age at exposure and extends into adulthood for some regions M. Deng, R.D. Hofacer, C. Jiang, B. Joseph, E.A. Hughes, B. Jia, S.C. Danzer, A.W. Loepke British Journal of Anaesthesia Volume 113, Issue 3, Pages 443-451 (September 2014) DOI: 10.1093/bja/aet469 Copyright © 2014 The Author(s) Terms and Conditions

Fig 1 Prolonged exposure to isoflurane triggers neuronal apoptotic cell death in several brain regions in newborn, juvenile, and young adult mice. Boxplots represent density counts of dying cells, as assessed by expression of cleaved caspase 3, a marker of apoptotic cell death. Thick horizontal lines signify respective group medians, boxes are 25th–75th percentiles, whiskers are 10th–90th percentiles, open circles and triangles depict outliers. Littermates were randomly assigned to 6 h of 1.5% isoflurane (Anaesthesia) or 6 h of room air (No Anaesthesia) at three different ages: as newborns [post-natal day (P)7], as juveniles (P21), or as young adults (P49). Density of cleaved caspase 3-positive cells was assessed in superficial layers II/III of the retrosplenial agranular cortex (RSA; a), caudoputamen (CPu; b), the pyramidal layer of cornu ammonis 1 (CA1; c), cerebellar cortex (Cb; d), and white matter (Cb wm; e), the subgranular zone and granule cell layer of dentate gyrus (DG; f), and the granule layer of the olfactory bulb (GrO; g). P7, Anaesthesia (n=10), No Anaesthesia (n=8); P21, Anaesthesia (n=8), No Anaesthesia (n=7); P49, Anaesthesia (n=16), No Anaesthesia (n=13). *P<0.05, **P<0.01, ***P<0.001, compared with the respective No Anaesthesia group. British Journal of Anaesthesia 2014 113, 443-451DOI: (10.1093/bja/aet469) Copyright © 2014 The Author(s) Terms and Conditions

Fig 2 Exposure to prolonged anaesthesia induces significant neuroapoptosis in several brain regions in newborn mice. Representative high-power magnification photomicrographs of layers II/III of the retrosplenial agranular cortex (RSA), caudoputamen (CPu), the pyramidal layer of cornu ammonis region 1 (CA1), subgranular zone and granule cell layer of dentate gyrus (DG), the granule layer of the olfactory bulb (GrO) and cerebellar cortex (Cb), and both internal granule layer (arrows) and external granule layer (arrow head) from a newborn mouse (P7) anaesthetized for 6 h with 1.5% isoflurane (Anaesthesia, a–f) and from an unanaesthetized and fasted littermate (No Anaesthesia, g–l). Sections were stained with propidium iodide (PI; red) to label all cells, for neuronal nuclei (NeuN; blue) to label post-mitotic neurones, and for activated, cleaved caspase 3 (AC3; green) to label apoptotic cells (arrows). All brain regions shown demonstrated statistically significantly increased neuroapoptosis after anaesthetic exposure, compared with unanaesthetized littermates, except for the dentate gyrus, which revealed no significantly increased cell death in newborn animals. For quantification, see Figure 1. Scale bars=50 µm. British Journal of Anaesthesia 2014 113, 443-451DOI: (10.1093/bja/aet469) Copyright © 2014 The Author(s) Terms and Conditions

Fig 3 Exposure to prolonged anaesthesia induces significant neuroapoptosis in the dentate gyrus, olfactory bulb, and cerebellum of juvenile mice. Representative high-power magnification photomicrographs of the subgranular zone and granule cell layer of dentate gyrus (DG), the granule layer of the olfactory bulb (GrO) and cerebellar white matter (Cb wm) from a juvenile mouse (P21) anaesthetized for 6 h with 1.5% isoflurane (Anaesthesia; a–c) and from an unanaesthetized, fasted littermate (No Anaesthesia; d–f). Sections were stained with propidium iodide (PI; red) to label all cells, for neuronal nuclei (NeuN; blue) to label post-mitotic neurones, and for activated, cleaved caspase 3 (AC3; green) to label apoptotic cells (arrows). Of all the brain regions examined, the dentate gyrus, olfactory bulb, and cerebellar white matter were the only regions demonstrating significantly increased neuroapoptosis in juvenile animals, compared with unanaesthetized littermates. For quantification, see Figure 1. Scale bars=50 µm. British Journal of Anaesthesia 2014 113, 443-451DOI: (10.1093/bja/aet469) Copyright © 2014 The Author(s) Terms and Conditions

Fig 4 Exposure to prolonged anaesthesia induces significant neuroapoptosis in the dentate gyrus and olfactory bulb of young adult mice. Representative high-power magnification photomicrographs of the subgranular zone and granule cell layer of the dentate gyrus (DG) and the granule layer of the olfactory bulb (GrO) from a young adult mouse (P49) anaesthetized for 6 h with 1.5% isoflurane (Anaesthesia; a and b) and from an unanaesthetized and fasted littermate (No Anaesthesia; c and d). Sections were stained with propidium iodide (PI; red) to label all cells, for neuronal nuclei (NeuN; blue) to label post-mitotic neurones, and for activated, cleaved caspase 3 (AC3; green) to label apoptotic cells (arrows). Of all the brain regions examined, the dentate gyrus and olfactory bulb were the only regions in young adult animals demonstrating significantly increased neuroapoptosis, compared with unanaesthetized littermates. For quantification, see Figure 1. Scale bars=50 µm. British Journal of Anaesthesia 2014 113, 443-451DOI: (10.1093/bja/aet469) Copyright © 2014 The Author(s) Terms and Conditions

Fig 5 Age windows of vulnerability to anaesthesia-induced neuroapoptosis differ by brain region. Graph indicates the severity of anaesthesia-induced neuroapoptosis depicted as the median fold-increase over physiological apoptotic cell death, as observed in the respective littermate controls. Apoptotic neuronal density was quantified for superficial layers II/III of the retrosplenial agranular cortex (RSA), caudoputamen (CPu), the pyramidal layer of cornu ammonis 1 (CA1), cerebellum (Cb at P7, CB wm at P21), the subgranular zone and granule cell layer of dentate gyrus (DG), and the granule layer of the olfactory bulb (GrO) after a 6 h exposure to 1.5% isoflurane in newborn (P7), juvenile (P21), and adult mice (P49), compared with fasted, unanaesthetized littermates. Maximum vulnerability was observed in the neocortex, caudoputamen, and CA1 at P7, whereas the number of vulnerable neurones peaked at P21 for the cerebellum, dentate gyrus, and olfactory bulb. British Journal of Anaesthesia 2014 113, 443-451DOI: (10.1093/bja/aet469) Copyright © 2014 The Author(s) Terms and Conditions