Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis

Jun He; Ji Ye Aa; Jian Guo Sun; Paul F. Smith; Dirk De Ridder; Guang Ji Wang; Yiwen Zheng

doi:10.1016/bs.pbr.2020.09.002

Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis

Jun He
, Ji Ye Aa
, Jian Guo Sun
, Paul F. Smith
, Dirk De Ridder
, Guang Ji Wang
, Yiwen Zheng

China Pharmaceutical University
Nanjing University of Chinese Medicine
University of Otago
Brain Research New Zealand
The University of Auckland

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

8 Scopus citations

Abstract

It has been increasingly recognized that tinnitus is likely to be generated by complex network changes. Acoustic trauma that causes tinnitus induces significant changes in multiple metabolic pathways in the brain. However, it is not clear whether those metabolic changes in the brain could also be reflected in blood samples and whether metabolic changes could discriminate acoustic trauma, hyperacusis and tinnitus. We analyzed brain and serum metabolic changes in rats following acoustic trauma or a sham procedure using metabolomics. Hearing levels were recorded before and after acoustic trauma and behavioral measures to quantify tinnitus and hyperacusis were conducted at 4 weeks following acoustic trauma. Tissues from 11 different brain regions and serum samples were collected at about 3 months following acoustic trauma. Among the acoustic trauma animals, eight exhibited hyperacusis-like behavior and three exhibited tinnitus-like behavior. Using Gas chromatography–mass spectrometry and multivariate statistical analysis, significant metabolic changes were found in acoustic trauma animals in both the brain and serum samples with a number of metabolic pathways significantly perturbated. Furthermore, metabolic changes in the serum were able to differentiate sham from acoustic trauma animals, as well as sham from hyperacusis animals, with high accuracy. Our results suggest that serum metabolic profiling in combination with machine learning analysis may be a promising approach for identifying biomarkers for acoustic trauma, hyperacusis and potentially, tinnitus.

Original language	English
Title of host publication	Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment
Subtitle of host publication	Towards understanding the complexity of tinnitus
Editors	Berthold Langguth, Tobias Kleinjung, Dirk De Ridder, Winfried Schlee, Sven Vanneste, Sven Vanneste
Publisher	Elsevier B.V.
Pages	399-430
Number of pages	32
ISBN (Print)	9780128223758
DOIs	https://doi.org/10.1016/bs.pbr.2020.09.002
State	Published - Jan 2021
Externally published	Yes

Publication series

Name	Progress in Brain Research
Volume	262
ISSN (Print)	0079-6123
ISSN (Electronic)	1875-7855

Keywords

Acoustic trauma
Hyperacusis
Metabolic pathways
Metabolomics
Rats
Tinnitus

Access to Document

10.1016/bs.pbr.2020.09.002

Cite this

He, J., Aa, J. Y., Sun, J. G., Smith, P. F., De Ridder, D., Wang, G. J., & Zheng, Y. (2021). Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis. In B. Langguth, T. Kleinjung, D. De Ridder, W. Schlee, S. Vanneste, & S. Vanneste (Eds.), Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment: Towards understanding the complexity of tinnitus (pp. 399-430). (Progress in Brain Research; Vol. 262). Elsevier B.V.. https://doi.org/10.1016/bs.pbr.2020.09.002

He, Jun ; Aa, Ji Ye ; Sun, Jian Guo et al. / Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis. Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment: Towards understanding the complexity of tinnitus. editor / Berthold Langguth ; Tobias Kleinjung ; Dirk De Ridder ; Winfried Schlee ; Sven Vanneste ; Sven Vanneste. Elsevier B.V., 2021. pp. 399-430 (Progress in Brain Research).

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title = "Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis",

abstract = "It has been increasingly recognized that tinnitus is likely to be generated by complex network changes. Acoustic trauma that causes tinnitus induces significant changes in multiple metabolic pathways in the brain. However, it is not clear whether those metabolic changes in the brain could also be reflected in blood samples and whether metabolic changes could discriminate acoustic trauma, hyperacusis and tinnitus. We analyzed brain and serum metabolic changes in rats following acoustic trauma or a sham procedure using metabolomics. Hearing levels were recorded before and after acoustic trauma and behavioral measures to quantify tinnitus and hyperacusis were conducted at 4 weeks following acoustic trauma. Tissues from 11 different brain regions and serum samples were collected at about 3 months following acoustic trauma. Among the acoustic trauma animals, eight exhibited hyperacusis-like behavior and three exhibited tinnitus-like behavior. Using Gas chromatography–mass spectrometry and multivariate statistical analysis, significant metabolic changes were found in acoustic trauma animals in both the brain and serum samples with a number of metabolic pathways significantly perturbated. Furthermore, metabolic changes in the serum were able to differentiate sham from acoustic trauma animals, as well as sham from hyperacusis animals, with high accuracy. Our results suggest that serum metabolic profiling in combination with machine learning analysis may be a promising approach for identifying biomarkers for acoustic trauma, hyperacusis and potentially, tinnitus.",

keywords = "Acoustic trauma, Hyperacusis, Metabolic pathways, Metabolomics, Rats, Tinnitus",

author = "Jun He and Aa, \{Ji Ye\} and Sun, \{Jian Guo\} and Smith, \{Paul F.\} and \{De Ridder\}, Dirk and Wang, \{Guang Ji\} and Yiwen Zheng",

note = "Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",

year = "2021",

month = jan,

doi = "10.1016/bs.pbr.2020.09.002",

language = "英语",

isbn = "9780128223758",

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editor = "Berthold Langguth and Tobias Kleinjung and \{De Ridder\}, Dirk and Winfried Schlee and Sven Vanneste and Sven Vanneste",

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He, J, Aa, JY, Sun, JG, Smith, PF, De Ridder, D, Wang, GJ & Zheng, Y 2021, Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis. in B Langguth, T Kleinjung, D De Ridder, W Schlee, S Vanneste & S Vanneste (eds), Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment: Towards understanding the complexity of tinnitus. Progress in Brain Research, vol. 262, Elsevier B.V., pp. 399-430. https://doi.org/10.1016/bs.pbr.2020.09.002

Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis. / He, Jun; Aa, Ji Ye; Sun, Jian Guo et al.
Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment: Towards understanding the complexity of tinnitus. ed. / Berthold Langguth; Tobias Kleinjung; Dirk De Ridder; Winfried Schlee; Sven Vanneste; Sven Vanneste. Elsevier B.V., 2021. p. 399-430 (Progress in Brain Research; Vol. 262).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

TY - CHAP

T1 - Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis

AU - He, Jun

AU - Aa, Ji Ye

AU - Sun, Jian Guo

AU - Smith, Paul F.

AU - De Ridder, Dirk

AU - Wang, Guang Ji

AU - Zheng, Yiwen

PY - 2021/1

Y1 - 2021/1

N2 - It has been increasingly recognized that tinnitus is likely to be generated by complex network changes. Acoustic trauma that causes tinnitus induces significant changes in multiple metabolic pathways in the brain. However, it is not clear whether those metabolic changes in the brain could also be reflected in blood samples and whether metabolic changes could discriminate acoustic trauma, hyperacusis and tinnitus. We analyzed brain and serum metabolic changes in rats following acoustic trauma or a sham procedure using metabolomics. Hearing levels were recorded before and after acoustic trauma and behavioral measures to quantify tinnitus and hyperacusis were conducted at 4 weeks following acoustic trauma. Tissues from 11 different brain regions and serum samples were collected at about 3 months following acoustic trauma. Among the acoustic trauma animals, eight exhibited hyperacusis-like behavior and three exhibited tinnitus-like behavior. Using Gas chromatography–mass spectrometry and multivariate statistical analysis, significant metabolic changes were found in acoustic trauma animals in both the brain and serum samples with a number of metabolic pathways significantly perturbated. Furthermore, metabolic changes in the serum were able to differentiate sham from acoustic trauma animals, as well as sham from hyperacusis animals, with high accuracy. Our results suggest that serum metabolic profiling in combination with machine learning analysis may be a promising approach for identifying biomarkers for acoustic trauma, hyperacusis and potentially, tinnitus.

AB - It has been increasingly recognized that tinnitus is likely to be generated by complex network changes. Acoustic trauma that causes tinnitus induces significant changes in multiple metabolic pathways in the brain. However, it is not clear whether those metabolic changes in the brain could also be reflected in blood samples and whether metabolic changes could discriminate acoustic trauma, hyperacusis and tinnitus. We analyzed brain and serum metabolic changes in rats following acoustic trauma or a sham procedure using metabolomics. Hearing levels were recorded before and after acoustic trauma and behavioral measures to quantify tinnitus and hyperacusis were conducted at 4 weeks following acoustic trauma. Tissues from 11 different brain regions and serum samples were collected at about 3 months following acoustic trauma. Among the acoustic trauma animals, eight exhibited hyperacusis-like behavior and three exhibited tinnitus-like behavior. Using Gas chromatography–mass spectrometry and multivariate statistical analysis, significant metabolic changes were found in acoustic trauma animals in both the brain and serum samples with a number of metabolic pathways significantly perturbated. Furthermore, metabolic changes in the serum were able to differentiate sham from acoustic trauma animals, as well as sham from hyperacusis animals, with high accuracy. Our results suggest that serum metabolic profiling in combination with machine learning analysis may be a promising approach for identifying biomarkers for acoustic trauma, hyperacusis and potentially, tinnitus.

KW - Acoustic trauma

KW - Hyperacusis

KW - Metabolic pathways

KW - Metabolomics

KW - Rats

KW - Tinnitus

UR - https://www.scopus.com/pages/publications/85099623576

U2 - 10.1016/bs.pbr.2020.09.002

DO - 10.1016/bs.pbr.2020.09.002

M3 - 章节

C2 - 33931189

AN - SCOPUS:85099623576

SN - 9780128223758

T3 - Progress in Brain Research

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BT - Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment

A2 - Langguth, Berthold

A2 - Kleinjung, Tobias

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A2 - Schlee, Winfried

A2 - Vanneste, Sven

PB - Elsevier B.V.

ER -

He J, Aa JY, Sun JG, Smith PF, De Ridder D, Wang GJ et al. Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis. In Langguth B, Kleinjung T, De Ridder D, Schlee W, Vanneste S, Vanneste S, editors, Tinnitus - An Interdisciplinary Approach Towards Individualized Treatment: Towards understanding the complexity of tinnitus. Elsevier B.V. 2021. p. 399-430. (Progress in Brain Research). doi: 10.1016/bs.pbr.2020.09.002

Metabolic changes in the brain and blood of rats following acoustic trauma, tinnitus and hyperacusis

Abstract

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Keywords

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