Mathematical Models of Proprioceptors. I. Control and Transduction in the Muscle Spindle

Mileusnic, Milana; Brown, Ian E.; Lan, Ning; Loeb, Gerald E.

doi:10.1152/jn.00868.2005

Cited by 180 publications

(199 citation statements)

References 64 publications

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“…The variation in moment arm during the range of all movements was tuned to be within a reasonable approximation to the parameters observed in a realistic human hand. Previously developed mathematical models of muscle spindles (Mileusnic et al, 2006) and Golgi tendon organs (Crago et al, 1982;Mileusnic and Loeb, 2009) were used for proprioceptive feedback. We used only the primary output (Ia) of the spindles in our simulations, which provides both position and velocity feedback depending on separately modulated static and dynamic fusimotor control.…”

Section: Biomechanical Modelmentioning

confidence: 99%

Spinal-Like Regulator Facilitates Control of a Two-Degree-of-Freedom Wrist

Raphael

Tsianos²,

Loeb³

2010

Journal of Neuroscience

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The performance of motor tasks requires the coordinated control and continuous adjustment of myriad individual muscles. The basic commands for the successful performance of a sensorimotor task originate in "higher" centers such as the motor cortex, but the actual muscle activation and resulting torques and motion are considerably shaped by the integrative function of the spinal interneurons. The relative contributions of brain and spinal cord are less clear for reaching movements than for automatic tasks such as locomotion. We have modeled a two-axis, four-muscle wrist joint with realistic musculoskeletal mechanics and proprioceptors and a network of regulatory circuitry based on the classical types of spinal interneurons (propriospinal, monosynaptic Ia-excitatory, reciprocal Ia-inhibitory, Renshaw inhibitory, and Ib-inhibitory pathways) and their supraspinal control (via biasing activity, presynaptic inhibition, and fusimotor gain). The modeled system has a very large number of control inputs, not unlike the real spinal cord that the brain must learn to control to produce desired behaviors. It was surprisingly easy to program this model to emulate actual performance in four very different but well described behaviors: (1) stabilizing responses to force perturbations; (2) rapid movement to position target; (3) isometric force to a target level; and (4) adaptation to viscous curl force fields. Our general hypothesis is that, despite its complexity, such regulatory circuitry substantially simplifies the tasks of learning and producing complex movements.

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Section: Biomechanical Modelmentioning

confidence: 99%

Spinal-Like Regulator Facilitates Control of a Two-Degree-of-Freedom Wrist

Raphael

Tsianos²,

Loeb³

2010

Journal of Neuroscience

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“…The construction of the time domain model allows new input processes to be included directly to the model in arbitrary combinations with existing input processes. A number of mathematical models of the muscle spindle have been developed (Mileusnic et al 2006). One application of the procedures developed in this article would be to apply them to assess the linear behaviour of these models using the frequency domain approach outlined in Sects.…”

Section: Discussionmentioning

confidence: 99%

Combining frequency and time domain approaches to systems with multiple spike train input and output

2009

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A frequency domain approach and a time domain approach have been combined in an investigation of the behaviour of the primary and secondary endings of an isolated muscle spindle in response to the activity of two static fusimotor axons when the parent muscle is held at a fixed length and when it is subjected to random length changes. The frequency domain analysis has an associated error process which provides a measure of how well the input processes can be used to predict the output processes and is also used to specify how the interactions between the recorded processes contribute to this error. Without assuming stationarity of the input, the time domain approach uses a sequence of probability models of increasing complexity in which the number of input processes to the model is progressively increased. This feature of the time domain approach was used to identify a preferred direction of interaction between the processes underlying the generation of the activity of the primary and secondary endings. In the presence of fusimotor activity and dynamic length changes imposed on the muscle, it was shown that the activity of the primary and secondary endings carried different information about the effects of the inputs imposed

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“…A recent study from our lab used a beta version (not yet available as a webapplication) to evaluate the short-latency component of the stretch reflex of the SO muscle (Cronin et al, 2008). This new system included: muscle spindle model (Mileusnic et al, 2006) providing the proprioceptive feedback and a Hill-type muscle model (Zajac, 1989), with viscoelastic properties of muscle fibers and tendon. In the future, several of these new elements will be made available on the web application (as part of the ReMoto simulator) and several new examples may emerge for the teaching of fundamental mechanisms regarding the neuromusculoskeletal system.…”

Section: Block(#) Questionmentioning

confidence: 99%