American Society of Hirudotherapy

The roles of endogenous membrane properties and synaptic interaction in generating the heartbeat rhythm of the leech, Hirudo medicinalis

Research article published in The Journal of experimental biology (1979)

Last Updated: June 18, 2026Reviewed by: ASH Editorial Board
Research article — evidence reviewArticle reference
Evidence: Preclinical (animal)Clinical TrialsCalabrese RL · The Journal of experimental biology, 1979

Abstract

1. Inhibitory synapses among the central neurones involved in the generation of the heartbeat rhythm of the leech were blocked by either low Cl- physiological saline or presynaptic hyperpolarizing current. 2. Low Cl- saline reversibly blocked inhibitory postsynaptic potentials (IPSPs) from the HN cells onto both other HN cells and HE cells but did not block electrical coupling among HN cells. 3. The rhythmic bursts of impulses in HE cells were abolished when IPSPs were blocked by either low Cl- saline or hyperpolarization of HN cells. 4. The rhythmic bursts of impulses in HN cells were not abolished (except in cell HN(5)) when IPSPs were blocked by low Cl- saline, but phase relations became unfixed (unless the cells were electrically coupled). 5. Both brief depolarizing and hyperpolarizing current pulses reset the rhythm of HN cells whose IPSPs were blocked by low Cl- saline. 6. The results indicate that the motor neurones to the heart (HE cells) produce rhythmic impulse bursts because their steady discharge is periodically inhibited by the HN interneurones. The pattern generated by the HN cells originates from an endogenous rhythm co-ordinated by the inhibitory interactions and electrical coupling between these cells.

Abstract sourced from PubMed (NCBI) for the cited record. See the original publication for the authoritative version.

Publication typeJournal ArticleResearch Support, Non-U.S. Gov'tResearch Support, U.S. Gov't, Non-P.H.S.Research Support, U.S. Gov't, P.H.S.
Indexed MeSH termsAction PotentialsAnimalsBiological ClocksChlorineElectric StimulationHeartInterneuronsLeechesMembrane PotentialsModels, NeurologicalMotor NeuronsMyocardial Contraction

Summary

Peer-reviewed clinical and outcomes research relevant to medicinal leech therapy and its biology. Indexed in PubMed and verified against the NCBI record.

Why This Matters for Hirudotherapy

This is a classic neurophysiology study using Hirudo medicinalis as a model organism: it shows that the leech heartbeat rhythm arises from an endogenous oscillation in HN interneurones, coordinated by chloride-dependent inhibitory synapses and electrical coupling, with the heart motor neurones (HE cells) bursting because their steady firing is periodically inhibited. While it does use the genuine medicinal leech, the subject is the leech's own neural pattern-generator circuitry, not its salivary secretome or any therapeutic application, so its connection to clinical hirudotherapy or the leech-derived drug-discovery story is essentially nil. ASH should set expectations low here and present it honestly as foundational invertebrate neuroscience that happens to use Hirudo medicinalis as a laboratory model, with no bearing on the safety, mechanisms, or evidence base of leech therapy in patients.

Citation

The roles of endogenous membrane properties and synaptic interaction in generating the heartbeat rhythm of the leech, Hirudo medicinalis.

Calabrese RL · The Journal of experimental biology, 1979

Added to ASH library: May 28, 2026 · Site last updated: June 18, 2026

This website provides educational information and does not constitute medical advice, diagnosis, or treatment recommendations. Medicinal leech therapy carries clinically meaningful risks and should be performed only by qualified clinicians under institutionally approved protocols. FDA 510(k) clearance for medicinal leeches is limited to specific indications; investigational and off-label discussions are labeled accordingly. For patient-specific guidance, consult a qualified healthcare provider.