Your search keyword '"Beckinghausen J"' showing total 2 results

1. Deep Brain Stimulation of the Interposed Cerebellar Nuclei in a Conditional Genetic Mouse Model with Dystonia.

Author

Beckinghausen J, Donofrio SG, Lin T, Miterko LN, White JJ, Lackey EP, and Sillitoe RV

Subjects

Mice, Animals, Cerebellar Nuclei, Cerebellum, Basal Ganglia, Disease Models, Animal, Dystonia therapy, Deep Brain Stimulation methods

Abstract

Dystonia is a neurological disease that is currently ranked as the third most common motor disorder. Patients exhibit repetitive and sometimes sustained muscle contractions that cause limb and body twisting and abnormal postures that impair movement. Deep brain stimulation (DBS) of the basal ganglia and thalamus can be used to improve motor function when other treatment options fail. Recently, the cerebellum has garnered interest as a DBS target for treating dystonia and other motor disorders. Here, we describe a procedure for targeting DBS electrodes to the interposed cerebellar nuclei to correct motor dysfunction in a mouse model with dystonia. Targeting cerebellar outflow pathways with neuromodulation opens new possibilities for using the expansive connectivity of the cerebellum to treat motor and non-motor diseases., (© 2023. Springer Nature Switzerland AG.)

Published

2023

2. Electromyography as a Method for Distinguishing Dystonia in Mice.

Author

Brown AM, Lackey EP, Salazar Leon LE, Rey Hipolito AG, Beckinghausen J, Lin T, and Sillitoe RV

Subjects

Mice, Animals, Electromyography methods, Muscles, Electrodes, Movement, Dystonia

Abstract

Electromyography (EMG) methods allow quantitative analyses of motor function. The techniques include intramuscular recordings that are performed in vivo. However, recording muscle activity in freely moving mice, particularly in models of motor disease, often creates challenges that prevent the acquisition of clean signals. Recording preparations must be stable enough for the experimenter to collect an adequate number of signals for statistical analyses. Instability results in a low signal-to-noise ratio that prohibits proper isolation of EMG signals from the target muscle during the behavior of interest. Such insufficient isolation prevents the analysis of full electrical potential waveforms. In this case, resolving the shape of a waveform to differentiate individual spikes and bursts of muscle activity can be difficult. A common source of instability is an inadequate surgery. Poor surgical techniques cause blood loss, tissue damage, poor healing, encumbered movement, and unstable implantation of the electrodes. Here, we describe an optimized surgical procedure that ensures electrode stability for in vivo muscle recordings. We implement our technique to obtain recordings from agonist and antagonist muscle pairs in the hindlimbs of freely moving adult mice. We validate the stability of our method by holding EMG recordings during dystonic behavior. Our approach is ideal for studying normal and abnormal motor function in actively behaving mice and valuable for recording intramuscular activity when considerable motion is expected., (© 2023. Springer Nature Switzerland AG.)

Published

2023