Membrane properties of nociceptive neurones in lamina II of lumbar spinal cord in the cat.

1. Intracellular recordings were made from neurones in lamina II of the dorsal horn of the lumbar spinal cord of the cat, and the electrotonic responses to brief rectangular current pulses of up to 0.5 nA passed through the recording microelectrode measured. 2. The majority of penetrations were associated with input resistances lower than 70 M omega, low resting potentials (-25 to -45 mV) and frequent firing of action potentials. Stable resting potentials of -50 to -75 mV were recorded in twenty neurones which exhibited continuous ongoing synaptic activity without action potentials. The threshold for action potential initiation was around -42 mV. The current-voltage relationships were linear over most of the range of currents used; with depolarizing currents rectification became apparent close to the firing threshold. Input resistances ranged from 80 to 150 M omega. 3. The time course of the decay of the electrotonic response was exponential with a time constant of 0.8-2.0 ms. The morphology of the cells--small soma with a small number of fine processes--and these short time constants suggest that axial current flow is limited and that the charge is dissipated locally within the soma through the membrane capacitance. 4. Effective membrane capacities were calculated from the estimated soma surface area of typical neurones in lamina II stained with HRP, and assuming a specific membrane conductance of 1.0 microF cm-2 they ranged from 3.1 to 15.7 pF. Membrane capacities were calculated for the twenty neurones in this study from measurement of input resistance and time constants (6.4-15.0 pF) and lay within this range. 5. Three neurones which had their electrical properties measured were also stained with horseradish peroxidase (HRP). Their specific membrane capacitances (1.1-1.2 microF cm-2) and specific resistances (0.9-1.1 k omega cm2) were within the range of values measured for other neurones in the CNS. 6. The short time constants found for these neurones suggests that temporal summation of postsynaptic potentials evoked by short-acting neurotransmitters will be limited. This may help to explain why action potentials arise singly from discrete, short-lived EPSPs. There is anatomical evidence for multiple connections from terminal branches of A delta and C afferent fibres within the superficial dorsal horn; this suggests that spatial summation of EPSPs is a major factor in synaptic integration of some of the primary afferent inputs to these neurones.