Journal of neuroscience methods
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J. Neurosci. Methods · Mar 2007
Estimation of average muscle fiber conduction velocity from simulated surface EMG in pinnate muscles.
The aim of this simulation study was to assess the bias in estimating muscle fiber conduction velocity (CV) from surface electromyographic (EMG) signals in muscles with one and two pinnation angles. The volume conductor was a layered medium simulating anisotropic muscle tissue and isotropic homogeneous subcutaneous tissue. The muscle tissue was homogeneous for one pinnation angle and inhomogeneous for bipinnate muscles (two fiber directions). ⋯ The main factor biasing CV estimates was the propagation of action potentials in the two directions which influenced the recording due to the scatter of the projection of end-plate and tendon locations along the fiber direction, as a consequence of pinnation. The same problem arises in muscles with the line of innervation zone locations not perpendicular to fiber direction. These results indicate an important limitation in reliability of CV estimates from the interference EMG when the innervation zone and tendon locations are not distributed perpendicular to fiber direction.
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J. Neurosci. Methods · Feb 2007
A new multi-electrode array design for chronic neural recording, with independent and automatic hydraulic positioning.
We report on a new microdrive design, which enables the construction of multi-electrode arrays capable of chronically recording the multi-unit neural activity of waking animals. Our principal motivation for inventing this device was to simplify the task of positioning electrodes, which consumes a considerable amount of time and requires a high level of skill. With the new microdrives, each electrode is independently and automatically driven into place. ⋯ It allows for up to 22 electrodes, which are arranged on a 0.35 mm grid. Each electrode can be positioned at any depth up to approximately 4mm. The microdrive was evaluated under acute and chronic recording experiments, and is shown to be capable of automatically positioning each electrode and successfully recording the neural signals of waking rats.
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J. Neurosci. Methods · Jan 2007
Non-invasive intraoperative monitoring of blood pressure and arterial pCO2 during surgical anesthesia in mice.
Despite the constantly increasing use of genetically engineered mice in biomedical research, control of crucial physiological parameters such as blood pressure and arterial blood gases is difficult to achieve in temporarily anesthetized mice due to lack of techniques for reversible arterial cannulation. Here we report that arterial blood pressure and blood gases can be measured reliably in anaesthetized and artificially ventilated mice using non-invasive technology. C57Bl6 mice were anaesthetized by i.p. injection of midazolam, fentanyl, and medetomidin, intubated, and ventilated for 3h. ⋯ Non-invasive blood pressure (NIBP) correlated strongly with the invasive arterial blood pressure measured at the external carotid artery (r = 0.99, P < 0.001) and end tidal pCO2 values correlated very well with arterial blood pCO2 (r = 0.93, P < 0.001). The current results demonstrate that it is possible to reliably measure and control the most relevant physiological parameters in anesthetized mice. Thereby the current study may help to reduce animal numbers and perform mice experiments under more defined and controlled physiological conditions in the future.
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J. Neurosci. Methods · Jan 2007
Two-dimensional spatial distribution of surface mechanomyographical response to single motor unit activity.
In order to better understand the mechanisms of generation of mechanomyography (MMG) signals, the two-dimensional distribution of surface MMG produced by the activity of single motor units was analyzed by a novel two-dimensional recording method. Motor unit action potentials were identified from intramuscular electromyographic (EMG) signals and used to trigger the averaging of MMG signals detected over the tibialis anterior muscle of 11 volunteers with a grid of 5x3 accelerometers (20-mm inter-accelerometer distance). The intramuscular wires were inserted between the first and second accelerometer in the middle column of the grid, proximal to the innervation zone. ⋯ The double integrated signals (muscle displacement) indicated negative deflection in the lateral part and inflation close to the tibia bone. The maps of acceleration showed spatial dependency in single motor unit MMG activities. The technique provides a new insight into motor unit contractile properties.
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J. Neurosci. Methods · Oct 2006
A method for studying jaw muscle activity during standardized jaw movements under experimental jaw muscle pain.
This paper describes a method for studying superficial and deep jaw muscle activity during standardized jaw movements under experimental jaw muscle pain. In 22 healthy adults, pain was elicited in the right masseter muscle via tonic infusion of 4.5% hypertonic saline and which resulted in scores of 30-60 mm on a 100-mm visual analogue scale. Subjects performed tasks in five sessions in a repeated measures design, i.e., control 1, test 1 (during hypertonic or isotonic saline infusion), control 2 (without infusion), test 2 (during isotonic or hypertonic saline infusion), control 3 (without infusion). ⋯ Mandibular movement was recorded with a 6-degree-of-freedom tracking system simultaneously with electromyographic (EMG) activity from the inferior head of the lateral pterygoid muscle with fine-wire electrodes (verified by computer tomography), and from posterior temporalis, the submandibular muscle group and bilateral masseter muscles with surface electrodes. EMG root mean square values were calculated at each 0.5 mm increment of mandibular incisor movement for all tasks under each experimental session. This establishes an experimental model for testing the effects of pain on jaw muscle activity where the jaw motor system is required to perform goal-directed tasks, and therefore should extend our understanding of the effects of pain on the jaw motor system.