In vivo low-intensity magnetic pulses durably alter neocortical neuron excitability and spontaneous activity.
Manon BoyerPaul BaudinChloé StengelAntoni Valero-CabréAnn M LohofStéphane CharpierRachel M SherrardSéverine MahonPublished in: The Journal of physiology (2022)
Magnetic brain stimulation is a promising treatment for neurological and psychiatric disorders. However, a better understanding of its effects at the individual neuron level is essential to improve its clinical application. We combined focal low-intensity repetitive transcranial magnetic stimulation (LI-rTMS) to the rat somatosensory cortex with intracellular recordings of subjacent pyramidal neurons in vivo. Continuous 10 Hz LI-rTMS reliably evoked firing at ∼4-5 Hz during the stimulation period and induced durable attenuation of synaptic activity and spontaneous firing in cortical neurons, through membrane hyperpolarization and a reduced intrinsic excitability. However, inducing firing in individual neurons by repeated intracellular current injection did not reproduce the effects of LI-rTMS on neuronal properties. These data provide a novel understanding of mechanisms underlying magnetic brain stimulation showing that, in addition to inducing biochemical plasticity, even weak magnetic fields can activate neurons and enduringly modulate their excitability. KEY POINTS: Repetitive transcranial magnetic stimulation (rTMS) is a promising technique to alleviate neurological and psychiatric disorders caused by alterations in cortical activity. Our knowledge of the cellular mechanisms underlying rTMS-based therapies remains limited. We combined in vivo focal application of low-intensity rTMS (LI-rTMS) to the rat somatosensory cortex with intracellular recordings of subjacent pyramidal neurons to characterize the effects of weak magnetic fields at single cell level. Ten minutes of LI-rTMS delivered at 10 Hz reliably evoked action potentials in cortical neurons during the stimulation period, and induced durable attenuation of their intrinsic excitability, synaptic activity and spontaneous firing. These results help us better understand the mechanisms of weak magnetic stimulation and should allow optimizing the effectiveness of stimulation protocols for clinical use.
Keyphrases
- transcranial magnetic stimulation
- high frequency
- molecularly imprinted
- spinal cord
- transcranial direct current stimulation
- ion batteries
- single cell
- cerebral ischemia
- healthcare
- randomized controlled trial
- oxidative stress
- diabetic rats
- high glucose
- spinal cord injury
- systematic review
- working memory
- machine learning
- mass spectrometry
- high throughput
- ultrasound guided
- subarachnoid hemorrhage
- drug induced
- brain injury