6.2.1 Neurostimulation
The purpose of neural stimulation is to deliver the electric charge to a nerve bundle, a
neuron, or generally, to neural tissue. For example, in patients suffering from epilepsy,
upon detecting the onset of a seizure via a neural recording front end, a neuro
stimulator is used to deliver charge to the brain tissue via a set of electrodes [2]. When
enough charges are delivered, the tissue’s membrane depolarizes to below its
threshold; this produces a unidirectional action potential that prevents the seizure. The
neurostimulator accomplishing this task must be designed such that it delivers enough
charges to cause the depolarization. Secondly, the neurostimulator must deliver the
stimulation such that there is no charge imbalance or residual average direct current
(DC) at the membrane.
Charge imbalance can cause tissue damage [2]. For instance, Aran et al. reported tissue
damage occurring in guinea pig cochleae at residual average DC levels in the range of
20–40 μA [3]. Similarly, Hurlbert et al. reported that when the average residual DC was
maintained at 1.5 μA for rat spinal cords, there was no pathological change around the
electrodes even after prolonged stimulation. This indicated that such an amount of
average residual DC was safe for the tissue. Therefore, achieving charge balance, in ad
dition to achieving the correct current amplitude and temporal characteristics, is a central
aspect of neurostimulator design [4]. Current-mode stimulation is used to achieve bi
phasic stimulation and ensures that charge balance is maintained.
Figure 6.1 illustrates a general configuration for charge balanced-neurostimulation
along with its associated stimulation regimen. A cathodic pulse with pre-defined am
plitude Icath and duration tcath is applied to the nerve to deliver the required electric
charge on the tissue membrane. This pulse is maintained until the threshold membrane
potential is reached and the action potential is elicited. With a brief delay, the anodic
pulse (Ianod, tanod) is initiated to offset the previously supplied charge to maintain charge
balance. To guarantee a complete charge balance or at least a safe average residual DC
after each cycle, the current source and current sink arms of the circuit need to be ac
curately matched. Unfortunately, achieving such matching is not feasible in practice due
FIGURE 6.1
Schematic of an electrical stimulation scheme of a nerve. (a) Switched current sources are connected to the nerve
via an electrode. (b) Typical biphasic pattern showing switch operation and the current delivered to the nerve as
a function of time.
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