C Harrington scite author profile

²

,

Marin

³

et al. 1996

Synaptic transmission was measured at visualized terminal varicosities of the motor axon providing the sole excitatory innervation of the "opener" muscle in walking legs of crayfish (Procambarus clarkii Girard). Two questions were addressed: 1) How uniform is quantal emission at different locations along terminals innervating a single muscle fiber, and 2) can differences in quantal emission account for the different excitatory postsynaptic potential (EPSP) amplitudes generated by terminals localized in defined regions of the muscle? Extracellular "macropatch" electrodes were placed over individual varicosities, viewed after brief exposure to a fluorescent dye, and synaptic currents were recorded to determine quantal content of transmission. Along terminals supplying a single muscle fiber, nonuniform release was found: Varicosities closer to the point of origin of the terminal branch released more transmitter than those located more distally. Quantal content was higher for varicosities of the muscle's proximal region (where large EPSPs occur) than for varicosities of the central region (where small EPSPs occur). The probability of transmitter release per synapse is estimated to be greater for the proximal varicosities. At low frequencies of stimulation, quantal content per muscle fiber is two to four times larger in the proximal region. Taken in conjunction with a twofold higher mean input resistance for the proximal muscle fibers, the difference in quantal content can account for a four- to eightfold difference in EPSP amplitude. The observed mean EPSP amplitude is at least eight times larger in the proximal region. We discuss factors contributing to differences in EPSP amplitudes.

Quantal release at visualized terminals of a crayfish motor axon: Intraterminal and regional differences

Cooper

¹

,

²

,

Marin

³

et al. 1996

Synaptic transmission was measured at visualized terminal varicosities of the motor axon providing the sole excitatory innervation of the "opener" muscle in walking legs of crayfish (Procambarus clarkii Girard). Two questions were addressed: 1) How uniform is quantal emission at different locations along terminals innervating a single muscle fiber, and 2) can differences in quantal emission account for the different excitatory postsynaptic potential (EPSP) amplitudes generated by terminals localized in defined regions of the muscle? Extracellular "macropatch" electrodes were placed over individual varicosities, viewed after brief exposure to a fluorescent dye, and synaptic currents were recorded to determine quantal content of transmission. Along terminals supplying a single muscle fiber, nonuniform release was found: Varicosities closer to the point of origin of the terminal branch released more transmitter than those located more distally. Quantal content was higher for varicosities of the muscle's proximal region (where large EPSPs occur) than for varicosities of the central region (where small EPSPs occur). The probability of transmitter release per synapse is estimated to be greater for the proximal varicosities. At low frequencies of stimulation, quantal content per muscle fiber is two to four times larger in the proximal region. Taken in conjunction with a twofold higher mean input resistance for the proximal muscle fibers, the difference in quantal content can account for a four- to eightfold difference in EPSP amplitude. The observed mean EPSP amplitude is at least eight times larger in the proximal region. We discuss factors contributing to differences in EPSP amplitudes.

Rural Family Caregivers’ Discoveries Following a Person-in-Context Dementia Simulation

¹

,

Hardin

²

,

Cacchione

³

et al. 2022

OJRNHC

Is Perception Reality? Using Person-in-Context Simulation to Promote Empathic Understanding of Dementia Among Nurse Practitioner Students

¹

,

Neil

²

,

Hardin

³

et al. 2021

This one-group nonexperimental pretest/posttest repeated-measures design plus interpretative phenomenological analysis explored nurse practitioner students' perceptions of dementia using virtual simulation. Perceptions of dementia and its associated challenges differed after the simulation. A critical theme that emerged was "developing empathic understanding"; the two subthemes were "mirroring dementia behaviors" and "provoking emotions." Virtual dementia simulation is an inexpensive, low-fidelity strategy to challenge assumptions and preconceived belief systems about dementia. Person-in-context experiential learning is valuable in nurse practitioner education for facilitating empathic understanding. Further research is needed to explore the correlation between empathic understanding and altruistic helping behaviors in professional practice.

“Satellite cells” and nerve terminals in the crayfish opener muscle visualized with fluorescent dyes

J of Comparative Neurology

¹

,

Atwood

²

1995

Nerve terminals and associated cells on the muscle's surface were visualized in the crayfish opener muscle with several fluorescent dyes in conjunction with confocal microscopy and conventional fluorescence microscopy. The nerve terminals of the excitatory and inhibitory axons were best seen with 4-diethylaminostyryl-N-methylpyridinium iodide (4-Di-2-Asp). This dye is selectively accumulated in mitochondria, which are numerous both in the axons and in synapse-bearing terminal varicosities. Muscle nuclei were also clearly visualized, because they excluded 4-Di-2-Asp but were stained by acridine orange (AO). A positive attraction between muscle nuclei and nerve terminals was evident by visual inspection and was confirmed by spatial statistics. Additional flat cells on the muscle's surface appeared as bright rings with elongated processes that were often close to or overlapped nearby nerve terminals. The structure of these cells was established by electron microscopy after labeling them with fluorescent polystyrene beads, which could be found over structures on the muscle surface in sections of embedded specimens. The flat surface cells were distinct from peripheral glial cells closely associated with axons and nerve terminals. Nevertheless, spatial statistics showed that the surface cells were grouped near nerve terminals. They occupied a small fraction of the muscle cell's surface. Their functional role has not been determined in crustacean muscles.