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Bioelectronic Sensors for Neuromuscular Perception in Human‐Machine Interfaces
Advanced Robotics Research, EarlyView.This review summarizes recent advances in bioelectronic sensors for neuromuscular perception in human‐machine interfaces. By integrating biopotential, electrical impedance, and electrochemical sensing strategies with flexible electrode interfaces, these bioelectronic sensing systems enable intuitive, real‐time detection of muscle and nerve activity ...
Junwei Li +5 more
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Advanced Robotics Research, EarlyView.An introduction for multidrive and environment‐adaptive micro/nanorobotics: design and fabrication strategies, intelligent actuation, and their applications. Various intelligent actuation approaches—magnetic, acoustic, optical, chemical, and biological—can be synergistically designed to enhance flexibility and adaptive behavior for precision medicine ...
Aiqing Ma +10 more
wiley +1 more source
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Nerve regeneration and nerve repair
Neurological Research, 2008(2008). Nerve regeneration and nerve repair. Neurological Research: Vol. 30, Nerve Regeneration and Nerve Repair, pp. 997-998.
Eric L. Zager, Rajiv Midha
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Neurosurgery Clinics of North America, 1991
The success of peripheral nerve regeneration is dependent on the survival of axotomized neurons, the efficacy of axonal outgrowth from those neurons, and the specificity of reinnervation of peripheral targets by those neurons. Experimental evidence indicates that following peripheral injury, primary sensory (DRG) neurons and in some cases, motoneurons ...
Bruce Tedeschi, Francis J. Liuzzi
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The success of peripheral nerve regeneration is dependent on the survival of axotomized neurons, the efficacy of axonal outgrowth from those neurons, and the specificity of reinnervation of peripheral targets by those neurons. Experimental evidence indicates that following peripheral injury, primary sensory (DRG) neurons and in some cases, motoneurons ...
Bruce Tedeschi, Francis J. Liuzzi
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Current Opinion in Neurology, 1995
The regeneration of nerve is a brilliant example of plasticity within the nervous system. Axonal sprouts form within a few hours of nerve injury and grow vigorously over long distances. Nonetheless, recovery from nerve injury, such as that seen after laceration of distal motor-sensory nerve, is often incomplete.
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The regeneration of nerve is a brilliant example of plasticity within the nervous system. Axonal sprouts form within a few hours of nerve injury and grow vigorously over long distances. Nonetheless, recovery from nerve injury, such as that seen after laceration of distal motor-sensory nerve, is often incomplete.
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Macrophages and nerve regeneration
Current Opinion in Neurobiology, 1992Macrophages are not only phagocytic cells but also secrete a plethora of growth factors that are potentially important for regeneration. This review will examine the emerging evidence of a likely contribution by macrophages to axonal regeneration.
Perry, V. Hugh, Brown, Michael C.
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Neuroscience Research, 1996
Peripheral nerve regeneration comprises the formation of axonal sprouts, their outgrowth as regenerating axons and the reinnervation of original targets. This review focuses on the morphological features of axonal sprouts at the node of Ranvier and their subsequent outgrowth guided by Schwann cells or by Schwann cell basal laminae.
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Peripheral nerve regeneration comprises the formation of axonal sprouts, their outgrowth as regenerating axons and the reinnervation of original targets. This review focuses on the morphological features of axonal sprouts at the node of Ranvier and their subsequent outgrowth guided by Schwann cells or by Schwann cell basal laminae.
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Annual Review of Neuroscience, 1990
Schwann cell basal laminae were demonstrated to serve as efficient conduits for the growth of regenerating axons in frozen nerve grafts, and in in situ freezing experiments. Regenerating axonal sprouts usually emanated from the first node of Ranvier proximal to the site of damage, and grew out along the inner surface of the basal lamina.
J W, Fawcett, R J, Keynes
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Schwann cell basal laminae were demonstrated to serve as efficient conduits for the growth of regenerating axons in frozen nerve grafts, and in in situ freezing experiments. Regenerating axonal sprouts usually emanated from the first node of Ranvier proximal to the site of damage, and grew out along the inner surface of the basal lamina.
J W, Fawcett, R J, Keynes
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Regeneration in the VIII Nerve
Acta Oto-Laryngologica, 1976After transection of the VIII nerve in the inner meatus, 95% of the cochlear neurons and practically all efferent fibres degenerate and disappear. In long-term survivals, different phenomena indicate the regeneration properties of many, probably efferent or vestibular nerve fibres. The few remaining afferent neurons react to the lesion of their central
H. Spoendlin, R. Suter
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2005
The nerve chamber model has dominated the experimental study of peripheral nerve (PN) regeneration with animal models as well as in several clinical applications, such as the treatment of paralysis of limbs following severe trauma. The two stumps resulting from nerve transection are inserted inside a tubular chamber made from one of several materials ...
Ioannis V. Yannas, Mei Zhang
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The nerve chamber model has dominated the experimental study of peripheral nerve (PN) regeneration with animal models as well as in several clinical applications, such as the treatment of paralysis of limbs following severe trauma. The two stumps resulting from nerve transection are inserted inside a tubular chamber made from one of several materials ...
Ioannis V. Yannas, Mei Zhang
openaire +3 more sources