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Fluids and Barriers of the CNS
Published in: Fluids and Barriers of the CNS 1/2022

Open Access 01-12-2022 | Biomarkers | Research

A novel chronic dural port platform for continuous collection of cerebrospinal fluid and intrathecal drug delivery in free-moving mice

Authors: Tsuneo Nakajima, Shuko Takeda, Yuki Ito, Akane Oyama, Yoichi Takami, Yasushi Takeya, Koichi Yamamoto, Ken Sugimoto, Hideo Shimizu, Munehisa Shimamura, Hiromi Rakugi, Ryuichi Morishita

Published in: Fluids and Barriers of the CNS | Issue 1/2022

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Abstract

Background

Cerebrospinal fluid (CSF) provides a close representation of pathophysiological changes occurring in the central nervous system (CNS); therefore, it has been employed in pathogenesis research and biomarker development for CNS disorders. CSF obtained from valid mouse models relevant to CNS disorders can be an important resource for successful biomarker and drug development. However, the limited volume of CSF that can be collected from tiny intrathecal spaces and the technical difficulties involved in CSF sampling has been a bottleneck that has hindered the detailed analysis of CSF in mouse models.

Methods

We developed a novel chronic dural port (CDP) method without cannulation for CSF collection of mice. This method enables easy and repeated access to the intrathecal space in a free-moving, unanesthetized mouse, thereby enabling continuous long-term CSF collection with minimal tissue damage and providing a large volume of high-quality CSF from a single mouse. When combined with chemical biosensors, the CDP method allows for real-time monitoring of the dynamic changes in neurochemicals in the CSF at a one-second temporal resolution in free-moving mice. Moreover, the CDP can serve as a direct access point for the intrathecal injection of CSF tracers and drugs.

Results

We established a CDP implantation and continuous CSF collection protocol. The CSF collected using CDP was not contaminated with blood and maintained physiological concentrations of basic electrolytes and proteins. The CDP method did not affect mouse’s physiological behavior or induce tissue damage, thereby enabling a stable CSF collection for up to four weeks. The spatio-temporal distribution of CSF tracers delivered using CDP revealed that CSF metabolism in different brain areas is dynamic. The direct intrathecal delivery of centrally acting drugs using CDP enabled real-time behavioral assessments in free-moving mice.

Conclusions

The CDP method enables the collection of a large volume of high-quality CSF and direct intrathecal drug administration with real-time behavioral assessment in free-moving mice. Combined with animal models relevant to CNS disorders, this method provides a unique and valuable platform for biomarker and therapeutic drug research.
Appendix
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Literature
1.
Johanson CE, Duncan JA, Klinge PM, Brinker T, Stopa EG, Silverberg GD. Multiplicity of cerebrospinal fluid functions: new challenges in health and disease. Cerebrospinal Fluid Res. 2008;5:10.CrossRef
2.
Sakka L, Coll G, Chazal J. Anatomy and physiology of cerebrospinal fluid. Eur Ann Orl Head Neck Dis. 2011;128:309–16.CrossRef
3.
Olsson B, Lautner R, Andreasson U, Öhrfelt A, Portelius E, Bjerke M, et al. CSF and blood biomarkers for the diagnosis of Alzheimer’s disease: a systematic review and meta-analysis. Lancet Neurol. 2016;15:673–84.CrossRef
4.
Olsson B, Portelius E, Cullen NC, Sandelius Å, Zetterberg H, Andreasson U, et al. Association of cerebrospinal fluid neurofilament light protein levels with cognition in patients with dementia, motor neuron disease, and movement disorders. JAMA Neurol. 2019;76:318–25.CrossRef
5.
Takeda S, Commins C, DeVos SL, Nobuhara CK, Wegmann S, Roe AD, et al. Seed-competent high-molecular-weight tau species accumulates in the cerebrospinal fluid of Alzheimer’s disease mouse model and human patients. Ann Neurol. 2016;80:355–67.CrossRef
6.
Rosenthal N, Brown S. The mouse ascending: perspectives for human-disease models. Nat Cell Biol. 2007;9:993–9.CrossRef
7.
Onos KD, Uyar A, Keezer KJ, Jackson HM, Preuss C, Acklin CJ, et al. Enhancing face validity of mouse models of Alzheimer’s disease with natural genetic variation. PLOS Genet. 2019;15:e1008155.CrossRef
8.
Myers A, McGonigle P. Overview of transgenic mouse models for Alzheimer’s disease. Curr Protoc Neurosci. 2019;89:e81.CrossRef
9.
Šakić B. Cerebrospinal fluid collection in laboratory mice: literature review and modified cisternal puncture method. J Neurosci Methods. 2019;311:402–7.CrossRef
10.
Barten DM, Cadelina GW, Hoque N, DeCarr LB, Guss VL, Yang L, et al. Tau transgenic mice as models for cerebrospinal fluid tau biomarkers. J Alzheimers Dis. 2011;24:127–41.CrossRef
11.
Liu L, Duff K. A technique for serial collection of cerebrospinal fluid from the cisterna magna in mouse. JoVE. 2008;21:e960.
12.
Ineichen BV, Schnell L, Gullo M, Kaiser J, Schneider MP, Mosberger AC et al. Direct, long-term intrathecal application of therapeutics to the rodent CNS. Nat Protoc. 2017;12:104–31.CrossRef
13.
Jones LL, Tuszynski MH. Chronic intrathecal infusions after spinal cord injury cause scarring and compression. Microsc Res Tech. 2001;54:317–24.CrossRef
14.
Yaksh TL, Rudy TA. Chronic catheterization of the spinal subarachnoid space. Physiol Behav. 1976;17:1031–6.CrossRef
15.
McIntyre C, Saville J, Fuller M. Collection of cerebrospinal fluid from murine lateral ventricles for biomarker determination in mucopolysaccharidosis type IIIA. J Neurosci Methods. 2019;324:108314.CrossRef
16.
Nair KGS, Ramaiyan V, Sukumaran SK. Enhancement of drug permeability across blood brain barrier using nanoparticles in meningitis. Inflammopharmacology. 2018;26:675–84.CrossRef
17.
Yoshiyama Y, Higuchi M, Zhang B, Huang SM, Iwata N, Saido TC et al. Synapse loss and microglial activation precede tangles in a P301S tauopathy mouse model. Neuron. 2007;53:337–51.CrossRef
18.
Cirrito JR, May PC, O’Dell MA, Taylor JW, Parsadanian M, Cramer JW, et al. In vivo assessment of brain interstitial fluid with microdialysis reveals plaque-associated changes in amyloid-beta metabolism and half-life. J Neurosci. 2003;23:8844–53.CrossRef
19.
Kiyatkin EA, Wakabayashi KT. Parsing glucose entry into the brain: novel findings obtained with enzyme-based glucose biosensors. ACS Chem Neurosci. 2015;6:108–16.CrossRef
20.
Naylor E, Aillon DV, Gabbert S, Harmon H, Johnson DA, Wilson GS, et al. Simultaneous real-time measurement of EEG/EMG and L-glutamate in mice: A biosensor study of neuronal activity during sleep. J Electroanal Chem (Lausanne). 2011;656:106–13.CrossRef
21.
Shinozaki M, Yasuda A, Nori S, Saito N, Toyama Y, Okano H, Nakamura M. Novel method for analyzing locomotor ability after spinal cord injury in rats: technical note [Technical note]. Neurol Med Chir (Tokyo). 2013;53:907–13.CrossRef
22.
Fu K, Miyamoto Y, Otake K, Sumi K, Saika E, Matsumura S, et al. Involvement of the accumbal osteopontin-interacting transmembrane protein 168 in methamphetamine-induced place preference and hyperlocomotion in mice. Sci Rep. 2017;7:13084.CrossRef
23.
Lim NK, Moestrup V, Zhang X, Wang WA, Møller A, Huang FD. An improved method for collection of cerebrospinal fluid from anesthetized mice. J Vis Exp. 2018;133::e56774.
24.
Simon MJ, Iliff JJ. Regulation of cerebrospinal fluid (CSF) flow in neurodegenerative, neurovascular and neuroinflammatory disease. Biochim Biophys Acta. 2016;1862:442–51.CrossRef
25.
Oshio K, Watanabe H, Song Y, Verkman AS, Manley GT. Reduced cerebrospinal fluid production and intracranial pressure in mice lacking choroid plexus water channel Aquaporin-1. FASEB J. 2005;19:76–8.CrossRef
26.
Barkovits K, Kruse N, Linden A, Tönges L, Pfeiffer K, Mollenhauer B, Marcus K. Blood contamination in CSF and its impact on quantitative analysis of alpha-synuclein. Cells. 2020;9(2):370.CrossRef
27.
Irani DN. Cerebrospinal fluid in clinical practice. Saunders; 2009.
28.
Deisenhammer F, Sellebjerg F, Teunissen CE, Tumani H, editors. Cerebrospinal fluid in clinical neurology. Springer; 2015.
29.
Waritani T, Chang J, McKinney B, Terato K. An ELISA protocol to improve the accuracy and reliability of serological antibody assays. MethodsX. 2017;4:153–65.CrossRef
30.
Bothwell SW, Janigro D, Patabendige A. Cerebrospinal fluid dynamics and intracranial pressure elevation in neurological diseases. Fluids Barriers CNS. 2019;16:9.CrossRef
31.
Zhang L, Hussain Z, Ren Z. Recent advances in rational diagnosis and treatment of normal pressure Hydrocephalus: A critical appraisal on novel diagnostic, therapy monitoring and treatment modalities. Curr Drug Targets. 2019;20:1041–57.CrossRef
32.
Takeda S, Sato N, Rakugi H, Morishita R. Molecular mechanisms linking diabetes mellitus and Alzheimer disease: beta-amyloid peptide, insulin signaling, and neuronal function. Mol Biosyst. 2011;7:1822–7.CrossRef
33.
Takeda S, Sato N, Uchio-Yamada K, Sawada K, Kunieda T, Takeuchi D et al. Diabetes-accelerated memory dysfunction via cerebrovascular inflammation and Abeta deposition in an Alzheimer mouse model with diabetes. Proc Natl Acad Sci U S A. 2010;107:7036–41.CrossRef
34.
Garg T, Bhandari S, Rath G, Goyal AK. Current strategies for targeted delivery of bio-active drug molecules in the treatment of brain tumor. J Drug Target. 2015;23:865–87.CrossRef
35.
Dworkin RH, O’Connor AB, Kent J, Mackey SC, Raja SN, Stacey BR, et al. Interventional management of neuropathic pain: NeuPSIG recommendations. Pain. 2013;154:2249–61.CrossRef
36.
Harris VK, Stark J, Vyshkina T, Blackshear L, Joo G, Stefanova V et al. Phase I trial of intrathecal mesenchymal stem cell-derived neural progenitors in progressive multiple sclerosis. EBiomedicine. 2018;29:23–30.CrossRef
Metadata
Title
A novel chronic dural port platform for continuous collection of cerebrospinal fluid and intrathecal drug delivery in free-moving mice
Authors
Tsuneo Nakajima
Shuko Takeda
Yuki Ito
Akane Oyama
Yoichi Takami
Yasushi Takeya
Koichi Yamamoto
Ken Sugimoto
Hideo Shimizu
Munehisa Shimamura
Hiromi Rakugi
Ryuichi Morishita
Publication date
01-12-2022
Publisher
BioMed Central
Keyword
Biomarkers
Published in
Fluids and Barriers of the CNS / Issue 1/2022
Electronic ISSN: 2045-8118
DOI
https://doi.org/10.1186/s12987-022-00331-1

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