Determination of dose‐response curves by quantitative ionophoresis at the frog neuromuscular junction.

1. Quantitative ionophoresis at the neuromuscular junction is possible when (a) the drug is released from appropriate distances (15‐‐20 micrometer for most drugs), (b) the topology of receptors is known and (c) high resistance drug pipettes (100‐‐200 M omega) are sued. 2. With this method, drug concentration‐endplate conductance relations were determined in voltage‐clamped end‐plates of the frog for the agonists ACh, carbamylcholine (CCh) and suberyldicholine (SubCh). 3. Based on the co‐operative and independent model, theoretical dose‐response curves were computed using as parameters the Hill coefficient nH, maximum conductance gmax., and apparent dissociation constant K. It was found that the co‐operative model fitted the data much better than the independent model. 4. Based on the co‐operative model, the mean maximum conductance for ACh was gmax. = 169 nS/micrometer, equivalent to 9000 ionic channels/micrometer length of a nerve terminal which can be opened at high drug concentrations. 5. The maximum conductance for CCh at‐‐80 mV membrane potential was, on the average, 78% of that for ACh measured at the same end‐plates. This value is termed the relative efficacy of CCh. 6. The mean values for the apparent dissociation constant K were 27.8 micrometer for ACh, 336 micrometer for CCh and 18 micrometer for SubCh. 7. The inhibition of the acetylcholinesterase activity by edrophonium (3‐‐10 micrometer) affected only the local ACh concentration at the receptor sites, but not gmax. and nH. 8. Dose‐response curves measured before and after removal of single nerve terminals in collagenase‐treated muscle fibres showed no change in the nH, gmax. and K. A slight increase in gmax. to a value of 218 nS/micrometer observed comparing collagenase‐treated and untreated end‐plate. 9. Desensitization of receptors may occur in the range of several tens of milli‐seconds.