<i>In vitro</i> Verification of a 3-D Regenerative Neural Interface Design: Examination of Neurite Growth and Electrical Properties Within a Bifurcating Microchannel Structure

Wieringa, Paul; Wiertz, Remy; Weerd, Eddy L de; Rutten, Wim

doi:10.1109/jproc.2009.2038950

Cited by 14 publications

(18 citation statements)

References 16 publications

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“…However, leveraging the amplifying properties of microchannels must also be balanced with design characteristics to optimize axon ingrowth and regeneration into microchannels. Although in vitro results disagree on the optimal microchannel caliber to promote sustained axon ingrowth, in vivo experiments, demonstrating fibrous sheath micro-fascicular formation within microchannels, and our own laboratory experience suggest that larger microchannels and increased device transparency are necessary to promote and support regeneration(Lacour, Atta et al 2008, Wieringa, Wiertz et al 2010, Srinivasan, Guo et al 2011, FitzGerald, Lago et al 2012, Srinivasan, Tahilramani et al in press). …”

Section: Introductionmentioning

confidence: 83%

“…Microchannel caliber is an important consideration to promote axon regeneration, device selectivity, and amplification of microchannel potentials. Very small microchannels, as small as 5 μm, have been demonstrated in vitro to optimally amplify axon potentials(Wieringa, Wiertz et al 2010). However, there is a balance between small caliber microchannels to amplify signals and improve selectivity and larger caliber microchannels, which promote and support regeneration.…”

Section: Discussionmentioning

confidence: 99%

“…In order to facilitate highly selective recordings, recent regenerative designs have incorporated microchannels through which axons regenerate and directly contact embedded electrodes (FitzGerald, Lacour et al 2009, Wieringa, Wiertz et al 2010, FitzGerald, Lago et al 2012, Srinivasan, Tahilramani et al in press). A principle challenge in peripheral neural interfacing is the detection of small amplitude peripheral neural signals amid much larger muscle signals.…”

Section: Introductionmentioning

confidence: 99%

“…The amplification of microchannel potentials improves in vitro within smaller microchannels where limiting extracellular volume further increases extracellular resistance. Smaller microchannels may also improve recording and stimulating selectivity by mechanically separating regenerating axons(Wieringa, Wiertz et al 2010). However, leveraging the amplifying properties of microchannels must also be balanced with design characteristics to optimize axon ingrowth and regeneration into microchannels.…”

Section: Introductionmentioning

confidence: 99%

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Functional recordings from awake, behaving rodents through a microchannel based regenerative neural interface

Gore

Choi²,

Bellamkonda

et al. 2015

J. Neural Eng.

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Objective Neural interface technologies could provide controlling connections between the nervous system and external technologies, such as limb prosthetics. The recording of efferent, motor potentials is a critical requirement for a peripheral neural interface, as these signals represent the user-generated neural output intended to drive external devices. Our objective was to evaluate structural and functional neural regeneration through a microchannel neural interface and to characterize potentials recorded from electrodes placed within the microchannels in awake and behaving animals. Approach Female rats were implanted with muscle EMG electrodes and, following unilateral sciatic nerve transection, the cut nerve was repaired either across a microchannel neural interface or with end-to-end surgical repair. During a 13-week recovery period, direct muscle responses to nerve stimulation proximal to the transection were monitored weekly. In two rats repaired with the neural interface, four wire electrodes were embedded in the microchannels and recordings were obtained within microchannels during proximal stimulation experiments and treadmill locomotion. Main results In these proof-of-principle experiments, we found that axons from cut nerves were capable of functional reinnervation of distal muscle targets, whether regenerating through a microchannel device or after direct end-to-end repair. Discrete stimulation-evoked and volitional potentials were recorded within interface microchannels in a small group of awake and behaving animals and their firing patterns correlated directly with intramuscular recordings during locomotion. Of 38 potentials extracted, 19 were identified as motor axons reinnervating tibialis anterior or soleus muscles using spike triggered averaging. Significance These results are evidence for motor axon regeneration through microchannels and are the first report of in vivo recordings from regenerated motor axons within microchannels in a small group of awake and behaving animals. These unique findings provide preliminary evidence that efferent, volitional motor potentials can be recorded from the microchannel-based peripheral neural interface; a critical requirement for any neural interface intended to facilitate direct neural control of external technologies.

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Section: Introductionmentioning

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Functional recordings from awake, behaving rodents through a microchannel based regenerative neural interface

Gore

Choi²,

Bellamkonda

et al. 2015

J. Neural Eng.

View full text Add to dashboard Cite

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“…Some representative example applications are described here to enable gauging the impact that they have in biomedicine. In regenerating nerves, arrays of microchannels are needed to guide nerve growth [274]. In facilitating bone regrowth, periodic meshes are needed to retain and sequester bone morphogenetic protein.…”

Section: Biomedical Structuresmentioning

confidence: 99%

Multi-Beam Interference Advances and Applications: Nano-Electronics, Photonic Crystals, Metamaterials, Subwavelength Structures, Optical Trapping, and Biomedical Structures

Burrow

Gaylord

2011

Micromachines

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Abstract:Research in recent years has greatly advanced the understanding and capabilities of multi-beam interference (MBI). With this technology it is now possible to generate a wide range of one-, two-, and three-dimensional periodic optical-intensity distributions at the micro-and nano-scale over a large length/area/volume. These patterns may be used directly or recorded in photo-sensitive materials using multi-beam interference lithography (MBIL) to accomplish subwavelength patterning. Advances in MBI and MBIL and a very wide range of applications areas including nano-electronics, photonic crystals, metamaterials, subwavelength structures, optical trapping, and biomedical structures are reviewed and put into a unified perspective.

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Semi-automatic quantification of neurite fasciculation in high-density neurite images by the neurite directional distribution analysis (NDDA)

Hopkins

Wheeler

Staii

et al. 2014

Journal of Neuroscience Methods

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Background Bundling of neurite extensions occur during nerve development and regeneration. Understanding the factors that drive neurite bundling is important for designing biomaterials for nerve regeneration toward the innervation target and preventing nociceptive collateral sprouting. High-density neuron cultures including dorsal root ganglia explants are employed for in vitro screening of biomaterials designed to control directional outgrowth. Although some semiautomated image processing methods exist for quantification of neurite outgrowth, methods to quantify axonal fasciculation in terms of direction of neurite outgrowth are lacking. New Method This work presents a semi-automated program to analyze micrographs of high-density neurites; the program aims to quantify axonal fasciculation by determining the orientational distribution function of the tangent vectors of the neurites and calculating its Fourier series coefficients (‘c’ values). Results We found that neurite directional distribution analysis (NDDA) of fasciculated neurites yielded ‘c’ values of ≥ ~0.25 whereas branched outgrowth led to statistically significant lesser values of <~0.2. The ‘c’ values correlated directly to the width of neurite bundles and indirectly to the number of branching points. Comparison with Existing Methods Information about the directional distribution of outgrowth is lost in simple counting methods or achieved laboriously through manual analysis. The NDDA supplements previous quantitative analyses of axonal bundling using a vector-based approach that captures new information about the directionality of outgrowth. Conclusion The NDDA is a valuable addition to open source image processing tools available to biomedical researchers offering a robust, precise approach to quantification of imaged features important in tissue development, disease, and repair.

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In vitro Verification of a 3-D Regenerative Neural Interface Design: Examination of Neurite Growth and Electrical Properties Within a Bifurcating Microchannel Structure

Cited by 14 publications

References 16 publications

Functional recordings from awake, behaving rodents through a microchannel based regenerative neural interface

Functional recordings from awake, behaving rodents through a microchannel based regenerative neural interface

Multi-Beam Interference Advances and Applications: Nano-Electronics, Photonic Crystals, Metamaterials, Subwavelength Structures, Optical Trapping, and Biomedical Structures

Semi-automatic quantification of neurite fasciculation in high-density neurite images by the neurite directional distribution analysis (NDDA)

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