Quantitative ultrasound and apoptotic death in the neonatal primate brain

Ivan M. Rosado-Mendez; Kevin K. Noguchi; Laura Castañeda-Martinez; George Kirvassilis; Sophie H. Wang; Francesca Manzella; Brant S. Swiney; Kobe Masuoka; Saverio Capuano; Kevin G. Brunner; Kristin Crosno; Quinton W. Guerrero; Hayley Whitson; Ansgar Brambrink; Heather S. Simmons; Andres F. Mejia; James A. Zagzebski; Timothy J. Hall; Chrysanthy Ikonomidou

doi:10.1016/j.nbd.2019.03.032

Quantitative ultrasound and apoptotic death in the neonatal primate brain

Ivan M. Rosado-Mendez, Kevin K. Noguchi, Laura Castañeda-Martinez, George Kirvassilis, Sophie H. Wang, Francesca Manzella, Brant S. Swiney, Kobe Masuoka, Saverio Capuano, Kevin G. Brunner, Kristin Crosno, Quinton W. Guerrero, Hayley Whitson, Ansgar Brambrink, Heather S. Simmons, Andres F. Mejia, James A. Zagzebski, Timothy J. Hall, Chrysanthy Ikonomidou

Anesthesiology & Perioperative Medicine

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Apoptosis is triggered in the developing mammalian brain by sedative, anesthetic or antiepileptic drugs during late gestation and early life. Whether human children are vulnerable to this toxicity mechanism remains unknown, as there are no imaging techniques to capture it. Apoptosis is characterized by distinct structural features, which affect the way damaged tissue scatters ultrasound compared to healthy tissue. We evaluated whether apoptosis, triggered by the anesthetic sevoflurane in the brains of neonatal rhesus macaques, can be detected using quantitative ultrasound (QUS). Neonatal (n = 15) rhesus macaques underwent 5 h of sevoflurane anesthesia. QUS images were obtained through the sagittal suture at 0.5 and 6 h. Brains were collected at 8 h and examined immunohistochemically to analyze apoptotic neuronal and oligodendroglial death. Significant apoptosis was detected in white and gray matter throughout the brain, including the thalamus. We measured a change in the effective scatterer size (ESS), a QUS biomarker derived from ultrasound echo signals obtained with clinical scanners, after sevoflurane-anesthesia in the thalamus. Although initial inclusion of all measurements did not reveal a significant correlation, when outliers were excluded, the change in the ESS between the pre- and post-anesthesia measurements correlated strongly and proportionally with the severity of apoptotic death. We report for the first time in vivo changes in QUS parameters, which may reflect severity of apoptosis in the brains of infant nonhuman primates. These findings suggest that QUS may enable in vivo studies of apoptosis in the brains of human infants following exposure to anesthetics, antiepileptics and other brain injury mechanisms.

Original language	English (US)
Pages (from-to)	554-562
Number of pages	9
Journal	Neurobiology of Disease
Volume	127
DOIs	https://doi.org/10.1016/j.nbd.2019.03.032
State	Published - Jul 2019

Keywords

Apoptosis
Brain injury
Development
Imaging
Neonatal
Primate
Quantitative ultrasound
Sevoflurane
Thalamus

ASJC Scopus subject areas

Neurology

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10.1016/j.nbd.2019.03.032

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Rosado-Mendez, I. M., Noguchi, K. K., Castañeda-Martinez, L., Kirvassilis, G., Wang, S. H., Manzella, F., Swiney, B. S., Masuoka, K., Capuano, S., Brunner, K. G., Crosno, K., Guerrero, Q. W., Whitson, H., Brambrink, A., Simmons, H. S., Mejia, A. F., Zagzebski, J. A., Hall, T. J., & Ikonomidou, C. (2019). Quantitative ultrasound and apoptotic death in the neonatal primate brain. Neurobiology of Disease, 127, 554-562. https://doi.org/10.1016/j.nbd.2019.03.032

Rosado-Mendez, IM, Noguchi, KK, Castañeda-Martinez, L, Kirvassilis, G, Wang, SH, Manzella, F, Swiney, BS, Masuoka, K, Capuano, S, Brunner, KG, Crosno, K, Guerrero, QW, Whitson, H, Brambrink, A, Simmons, HS, Mejia, AF, Zagzebski, JA, Hall, TJ & Ikonomidou, C 2019, 'Quantitative ultrasound and apoptotic death in the neonatal primate brain', Neurobiology of Disease, vol. 127, pp. 554-562. https://doi.org/10.1016/j.nbd.2019.03.032

@article{cb9ca05c961040fa94d1190da4e44848,

title = "Quantitative ultrasound and apoptotic death in the neonatal primate brain",

abstract = "Apoptosis is triggered in the developing mammalian brain by sedative, anesthetic or antiepileptic drugs during late gestation and early life. Whether human children are vulnerable to this toxicity mechanism remains unknown, as there are no imaging techniques to capture it. Apoptosis is characterized by distinct structural features, which affect the way damaged tissue scatters ultrasound compared to healthy tissue. We evaluated whether apoptosis, triggered by the anesthetic sevoflurane in the brains of neonatal rhesus macaques, can be detected using quantitative ultrasound (QUS). Neonatal (n = 15) rhesus macaques underwent 5 h of sevoflurane anesthesia. QUS images were obtained through the sagittal suture at 0.5 and 6 h. Brains were collected at 8 h and examined immunohistochemically to analyze apoptotic neuronal and oligodendroglial death. Significant apoptosis was detected in white and gray matter throughout the brain, including the thalamus. We measured a change in the effective scatterer size (ESS), a QUS biomarker derived from ultrasound echo signals obtained with clinical scanners, after sevoflurane-anesthesia in the thalamus. Although initial inclusion of all measurements did not reveal a significant correlation, when outliers were excluded, the change in the ESS between the pre- and post-anesthesia measurements correlated strongly and proportionally with the severity of apoptotic death. We report for the first time in vivo changes in QUS parameters, which may reflect severity of apoptosis in the brains of infant nonhuman primates. These findings suggest that QUS may enable in vivo studies of apoptosis in the brains of human infants following exposure to anesthetics, antiepileptics and other brain injury mechanisms.",

keywords = "Apoptosis, Brain injury, Development, Imaging, Neonatal, Primate, Quantitative ultrasound, Sevoflurane, Thalamus",

author = "Rosado-Mendez, {Ivan M.} and Noguchi, {Kevin K.} and Laura Casta{\~n}eda-Martinez and George Kirvassilis and Wang, {Sophie H.} and Francesca Manzella and Swiney, {Brant S.} and Kobe Masuoka and Saverio Capuano and Brunner, {Kevin G.} and Kristin Crosno and Guerrero, {Quinton W.} and Hayley Whitson and Ansgar Brambrink and Simmons, {Heather S.} and Mejia, {Andres F.} and Zagzebski, {James A.} and Hall, {Timothy J.} and Chrysanthy Ikonomidou",

note = "Funding Information: This research was supported by pilot grant award, Office of the Director , NIH P51OD011106 to WNPRC and NIH/NICHD R01HD083001-01A1 grant to C. Ikonomidou; NIH grants HD052664 and U54-HD087011 the Intellectual and Developmental Disabilities Research Center at Washington University to K. Noguchi. This work was also supported by UNAM-PAPIIT grants IA104518 and IN107916 to I. Rosado-Mendez and L. Casta{\~n}eda-Martinez and CONACyT National Researcher (level 3) assistant support to L. Casta{\~n}eda-Martinez. Funding Information: This research was supported by pilot grant award, Office of the Director, NIH P51OD011106 to WNPRC and NIH/NICHD R01HD083001-01A1 grant to C. Ikonomidou; NIH grants HD052664 and U54-HD087011 the Intellectual and Developmental Disabilities Research Center at Washington University to K. Noguchi. This work was also supported by UNAM-PAPIIT grants IA104518 and IN107916 to I. Rosado-Mendez and L. Casta{\~n}eda-Martinez and CONACyT National Researcher (level 3) assistant support to L. Casta{\~n}eda-Martinez. I.M.R-M. contributed study design, ultrasound data acquisition and analysis, manuscript drafting; K·N contributed immunohistochemistry, stereology and manuscript drafting; L.C-M. contributed ultrasound data analysis; G.K. contributed experiment design; S.H.W. contributed immunohistochemistry; F.M. K.M. and B.S.S. contributed stereological analysis; S.C.III and K.R.B. contributed veterinary supervision for NHP experiments; K.C. contributed NHP experiment coordination and execution; H.S.S. contributed NHP perfusion; A.B. contributed immunohistochemical and stereological data; J.A.Z. contributed experimental design and manuscript drafting; T.A. contributed experimental design, ultrasound data analysis and manuscript drafting; C.I. contributed experimental design, acquisition of ultrasound data, analysis of ultrasound and histological data and manuscript drafting. The authors declare no competing interests. Publisher Copyright: {\textcopyright} 2019 Elsevier Inc.",

year = "2019",

month = jul,

doi = "10.1016/j.nbd.2019.03.032",

language = "English (US)",

volume = "127",

pages = "554--562",

journal = "Neurobiology of Disease",

issn = "0969-9961",

publisher = "Academic Press Inc.",

}

TY - JOUR

T1 - Quantitative ultrasound and apoptotic death in the neonatal primate brain

AU - Rosado-Mendez, Ivan M.

AU - Noguchi, Kevin K.

AU - Castañeda-Martinez, Laura

AU - Kirvassilis, George

AU - Wang, Sophie H.

AU - Manzella, Francesca

AU - Swiney, Brant S.

AU - Masuoka, Kobe

AU - Capuano, Saverio

AU - Brunner, Kevin G.

AU - Crosno, Kristin

AU - Guerrero, Quinton W.

AU - Whitson, Hayley

AU - Brambrink, Ansgar

AU - Simmons, Heather S.

AU - Mejia, Andres F.

AU - Zagzebski, James A.

AU - Hall, Timothy J.

AU - Ikonomidou, Chrysanthy

N1 - Funding Information: This research was supported by pilot grant award, Office of the Director , NIH P51OD011106 to WNPRC and NIH/NICHD R01HD083001-01A1 grant to C. Ikonomidou; NIH grants HD052664 and U54-HD087011 the Intellectual and Developmental Disabilities Research Center at Washington University to K. Noguchi. This work was also supported by UNAM-PAPIIT grants IA104518 and IN107916 to I. Rosado-Mendez and L. Castañeda-Martinez and CONACyT National Researcher (level 3) assistant support to L. Castañeda-Martinez. Funding Information: This research was supported by pilot grant award, Office of the Director, NIH P51OD011106 to WNPRC and NIH/NICHD R01HD083001-01A1 grant to C. Ikonomidou; NIH grants HD052664 and U54-HD087011 the Intellectual and Developmental Disabilities Research Center at Washington University to K. Noguchi. This work was also supported by UNAM-PAPIIT grants IA104518 and IN107916 to I. Rosado-Mendez and L. Castañeda-Martinez and CONACyT National Researcher (level 3) assistant support to L. Castañeda-Martinez. I.M.R-M. contributed study design, ultrasound data acquisition and analysis, manuscript drafting; K·N contributed immunohistochemistry, stereology and manuscript drafting; L.C-M. contributed ultrasound data analysis; G.K. contributed experiment design; S.H.W. contributed immunohistochemistry; F.M. K.M. and B.S.S. contributed stereological analysis; S.C.III and K.R.B. contributed veterinary supervision for NHP experiments; K.C. contributed NHP experiment coordination and execution; H.S.S. contributed NHP perfusion; A.B. contributed immunohistochemical and stereological data; J.A.Z. contributed experimental design and manuscript drafting; T.A. contributed experimental design, ultrasound data analysis and manuscript drafting; C.I. contributed experimental design, acquisition of ultrasound data, analysis of ultrasound and histological data and manuscript drafting. The authors declare no competing interests. Publisher Copyright: © 2019 Elsevier Inc.

PY - 2019/7

Y1 - 2019/7

N2 - Apoptosis is triggered in the developing mammalian brain by sedative, anesthetic or antiepileptic drugs during late gestation and early life. Whether human children are vulnerable to this toxicity mechanism remains unknown, as there are no imaging techniques to capture it. Apoptosis is characterized by distinct structural features, which affect the way damaged tissue scatters ultrasound compared to healthy tissue. We evaluated whether apoptosis, triggered by the anesthetic sevoflurane in the brains of neonatal rhesus macaques, can be detected using quantitative ultrasound (QUS). Neonatal (n = 15) rhesus macaques underwent 5 h of sevoflurane anesthesia. QUS images were obtained through the sagittal suture at 0.5 and 6 h. Brains were collected at 8 h and examined immunohistochemically to analyze apoptotic neuronal and oligodendroglial death. Significant apoptosis was detected in white and gray matter throughout the brain, including the thalamus. We measured a change in the effective scatterer size (ESS), a QUS biomarker derived from ultrasound echo signals obtained with clinical scanners, after sevoflurane-anesthesia in the thalamus. Although initial inclusion of all measurements did not reveal a significant correlation, when outliers were excluded, the change in the ESS between the pre- and post-anesthesia measurements correlated strongly and proportionally with the severity of apoptotic death. We report for the first time in vivo changes in QUS parameters, which may reflect severity of apoptosis in the brains of infant nonhuman primates. These findings suggest that QUS may enable in vivo studies of apoptosis in the brains of human infants following exposure to anesthetics, antiepileptics and other brain injury mechanisms.

AB - Apoptosis is triggered in the developing mammalian brain by sedative, anesthetic or antiepileptic drugs during late gestation and early life. Whether human children are vulnerable to this toxicity mechanism remains unknown, as there are no imaging techniques to capture it. Apoptosis is characterized by distinct structural features, which affect the way damaged tissue scatters ultrasound compared to healthy tissue. We evaluated whether apoptosis, triggered by the anesthetic sevoflurane in the brains of neonatal rhesus macaques, can be detected using quantitative ultrasound (QUS). Neonatal (n = 15) rhesus macaques underwent 5 h of sevoflurane anesthesia. QUS images were obtained through the sagittal suture at 0.5 and 6 h. Brains were collected at 8 h and examined immunohistochemically to analyze apoptotic neuronal and oligodendroglial death. Significant apoptosis was detected in white and gray matter throughout the brain, including the thalamus. We measured a change in the effective scatterer size (ESS), a QUS biomarker derived from ultrasound echo signals obtained with clinical scanners, after sevoflurane-anesthesia in the thalamus. Although initial inclusion of all measurements did not reveal a significant correlation, when outliers were excluded, the change in the ESS between the pre- and post-anesthesia measurements correlated strongly and proportionally with the severity of apoptotic death. We report for the first time in vivo changes in QUS parameters, which may reflect severity of apoptosis in the brains of infant nonhuman primates. These findings suggest that QUS may enable in vivo studies of apoptosis in the brains of human infants following exposure to anesthetics, antiepileptics and other brain injury mechanisms.

KW - Apoptosis

KW - Brain injury

KW - Development

KW - Imaging

KW - Neonatal

KW - Primate

KW - Quantitative ultrasound

KW - Sevoflurane

KW - Thalamus

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U2 - 10.1016/j.nbd.2019.03.032

DO - 10.1016/j.nbd.2019.03.032

M3 - Article

C2 - 30951850

AN - SCOPUS:85064213696

SN - 0969-9961

VL - 127

SP - 554

EP - 562

JO - Neurobiology of Disease

JF - Neurobiology of Disease

ER -

Quantitative ultrasound and apoptotic death in the neonatal primate brain

Abstract

Keywords

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