Constitutive Modeling of Brain Tissue: Current Perspectives

Rooij, Rijk de; Kuhl, Ellen

doi:10.1115/1.4032436

Cited by 120 publications

(87 citation statements)

References 87 publications

(215 reference statements)

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“…Most constitutive models of the brain require assumptions about viscosity [36], and it has been recently demonstrated that both viscous and elastic properties of hydrogels can regulate cell behavior [54]. …”

Section: Resultsmentioning

confidence: 99%

Mechanical characterization of human brain tumors from patients and comparison to potential surgical phantoms

Stewart¹,

Rubiano²,

Dyson³

et al. 2017

PLoS ONE

107

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While mechanical properties of the brain have been investigated thoroughly, the mechanical properties of human brain tumors rarely have been directly quantified due to the complexities of acquiring human tissue. Quantifying the mechanical properties of brain tumors is a necessary prerequisite, though, to identify appropriate materials for surgical tool testing and to define target parameters for cell biology and tissue engineering applications. Since characterization methods vary widely for soft biological and synthetic materials, here, we have developed a characterization method compatible with abnormally shaped human brain tumors, mouse tumors, animal tissue and common hydrogels, which enables direct comparison among samples. Samples were tested using a custom-built millimeter-scale indenter, and resulting force-displacement data is analyzed to quantify the steady-state modulus of each sample. We have directly quantified the quasi-static mechanical properties of human brain tumors with effective moduli ranging from 0.17–16.06 kPa for various pathologies. Of the readily available and inexpensive animal tissues tested, chicken liver (steady-state modulus 0.44 ± 0.13 kPa) has similar mechanical properties to normal human brain tissue while chicken crassus gizzard muscle (steady-state modulus 3.00 ± 0.65 kPa) has similar mechanical properties to human brain tumors. Other materials frequently used to mimic brain tissue in mechanical tests, like ballistic gel and chicken breast, were found to be significantly stiffer than both normal and diseased brain tissue. We have directly compared quasi-static properties of brain tissue, brain tumors, and common mechanical surrogates, though additional tests would be required to determine more complex constitutive models.

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Section: Resultsmentioning

confidence: 99%

Mechanical characterization of human brain tumors from patients and comparison to potential surgical phantoms

Stewart¹,

Rubiano²,

Dyson³

et al. 2017

PLoS ONE

107

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show abstract

“…By contrast, MRE shows fluidization with age (and that female brains are more elastic than male brains) 65 . Such discrepancies are not uncommon in this field and are widely discussed 22,47,51,65,66 . They could emanate from different preparative procedures of the tissue, time and length scales, as well as modes of deformation, and the change of properties between in vivo and in vitro measurements, among other possible factors.…”

Section: Tissue Considerationsmentioning

confidence: 97%

“…They could emanate from different preparative procedures of the tissue, time and length scales, as well as modes of deformation, and the change of properties between in vivo and in vitro measurements, among other possible factors. Improved microscopic models of brain tissue might help to resolve these differences in the future 49,66 .…”

Section: Tissue Considerationsmentioning

confidence: 99%

Materials and technologies for soft implantable neuroprostheses

2016

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| Implantable neuroprostheses are engineered systems designed to restore or substitute function for individuals with neurological deficits or disabilities. These systems involve at least one uni-or bidirectional interface between a living neural tissue and a synthetic structure, through which information in the form of electrons, ions or photons flows. Despite a few notable exceptions, the clinical dissemination of implantable neuroprostheses remains limited, because many implants display inconsistent long-term stability and performance, and are ultimately rejected by the body. Intensive research is currently being conducted to untangle the complex interplay of failure mechanisms. In this Review, we emphasize the importance of minimizing the physical and mechanical mismatch between neural tissues and implantable interfaces. We explore possible materials solutions to design and manufacture neurointegrated prostheses, and outline their immense therapeutic potential. NATURE REVIEWS | MATERIALSADVANCE ONLINE PUBLICATION | 1 REVIEWS© 2 0 1 6 M a c m i l l a n P u b l i s h e r s L i m i t e d , p a r t o f S p r i n g e r N a t u r e . A l l r i g h t s r e s e r v e d .

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“…Specifically, the mesh has all size features comparable to or smaller than neuron soma and bending stiffness values of ∼0.1 nN·m, comparable to a 150-μm-thick brain tissue slice (i.e., the same as the overall implanted open mesh diameter), ∼0.4 nN·m (27,28) and orders of magnitude smaller (more flexible) than conventional probes (14,29,30). Herein, we present systematic time-dependent histology studies of the mesh electronics/brain-tissue interface obtained from tissue sections perpendicular (horizontal slices) and parallel (sagittal slices) to the long axis of probes, as well as time-dependent measurements obtained from horizontal tissue sections containing the cross-sections Significance Seamless integration of electrical probes within neural tissue could substantially enhance their impact and open up new opportunities in neuroscience research through electronic therapeutics.…”

mentioning

confidence: 99%

Syringe-injectable mesh electronics integrate seamlessly with minimal chronic immune response in the brain

Zhou

Hong

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

193

211

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Implantation of electrical probes into the brain has been central to both neuroscience research and biomedical applications, although conventional probes induce gliosis in surrounding tissue. We recently reported ultraflexible open mesh electronics implanted into rodent brains by syringe injection that exhibit promising chronic tissue response and recording stability. Here we report time-dependent histology studies of the mesh electronics/brain-tissue interface obtained from sections perpendicular and parallel to probe long axis, as well as studies of conventional flexible thin-film probes. Confocal fluorescence microscopy images of the perpendicular and parallel brain slices containing mesh electronics showed that the distribution of astrocytes, microglia, and neurons became uniform from 2–12 wk, whereas flexible thin-film probes yield a marked accumulation of astrocytes and microglia and decrease of neurons for the same period. Quantitative analyses of 4- and 12-wk data showed that the signals for neurons, axons, astrocytes, and microglia are nearly the same from the mesh electronics surface to the baseline far from the probes, in contrast to flexible polymer probes, which show decreases in neuron and increases in astrocyte and microglia signals. Notably, images of sagittal brain slices containing nearly the entire mesh electronics probe showed that the tissue interface was uniform and neurons and neurofilaments penetrated through the mesh by 3 mo postimplantation. The minimal immune response and seamless interface with brain tissue postimplantation achieved by ultraflexible open mesh electronics probes provide substantial advantages and could enable a wide range of opportunities for in vivo chronic recording and modulation of brain activity in the future.

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Constitutive Modeling of Brain Tissue: Current Perspectives

Cited by 120 publications

References 87 publications

Mechanical characterization of human brain tumors from patients and comparison to potential surgical phantoms

Mechanical characterization of human brain tumors from patients and comparison to potential surgical phantoms

Materials and technologies for soft implantable neuroprostheses

Syringe-injectable mesh electronics integrate seamlessly with minimal chronic immune response in the brain

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