2. Electrical Waveforms Used With ECT
Sine Wave ECT
• Sine wave currents are characterized by a continuous
stream of electricity that flows in alternating directions.
• The number of alterations in direction, or cycles of negative
and positive current flow, is referred to as the frequency of
the stimulus and is measured in hertz (Hz), defined as the
number of cycles per second.
3.
4. Brief Pulse ECT
• the brief pulse consists of a series of
instantaneously rising and falling rectangular
pulses of current, with adjacent pulses
separated by brief periods of no electrical
activity
5. Brief pulses are characterized by four stimulus
parameters:
•pulse width
•Frequency
•Duration
•peak current
6. • The duration of each pulse is referred to as
the pulse width, which is measured in
milliseconds (ms; thousandths of a second).
7. • Pulse frequency is defined in terms of pulse
pairs per second, although it is common
practice to use the same unit of measure,
hertz, as used for the sine wave. The actual
number of pulses per second is twice the
frequency.
8. • Duration : the length of the entire series of
pulses delivered, and is measured in seconds.
9. • peak current : the maximum intensity of each
pulse, measured from the zero baseline, in
amperes.
10. Ultra-Brief Pulse ECT
• “Brief ” pulse has a pulse width of 0.5–2.0 ms,
whereas the width of an “Ultra-brief ” pulse is
less than 0.5 ms.
11. Seizure Threshold
• the total amount of electricity necessary to
induce a seizure
• Clinical Applications,” is a parameter that is
integral to stimulus dosing in clinical practice
• The physiological efficiency of the brief pulse
stimulus in activating brain neurons is more
optimal than the sine wave because of its
rapid rise and fall
12. Current, Voltage, and Impedance
• current is the number of electrons per second
flowing through a circuit.
• In this case, the circuit is made up of the ECT
machine, the stimulus cables, the stimulus
electrodes, and the patient’s head.
13. Current, Voltage, and Impedance
• Voltage is the force that drives the flow of
electrons during the stimulus.
• It is the push of the system
14. Current, Voltage, and Impedance
• Impedance is a measure of the obstacle to the
current flow.
• It is the level of resistance to be overcome.
current=voltage/resistance
where current is measured in amperes (A) or milliamperes (mA), voltage is measured
in volts (V), and resistance (impedance) is measured in ohms (Ω).
15. Mode of Stimulus Delivery
• In addition to the type of waveform used, ECT
devices differ in whether they administer the
stimulus via a constant current or constant
voltage
16.
17. Total Amount of Electricity Delivered
With ECT:
Charge and Energy
18. • CHARGE= the amount of current in a single
pulse x the number of pulses delivered in the
series, and is measured in millicoulombs (mC).
• THE AMOUNT OF CURRENT IN A SINGLE
PULSE =peak current (in amperes) x pulse
width (in milliseconds)
• THE NUMBER OF PULSES = twice the
frequency (in hertz) x duration (in seconds).
19. Clinical Applications
Stimulus Dosing
• the purpose of the electrical stimulus in ECT is
to generate an intracerebral current flow
sufficient to induce an adequate generalized
seizure within the brain.
• The seizure threshold is the minimum amount
of stimulus electrical charge that will evoke
such a response in a given patient at a given
point in time.
20. • How a series of seizures produces the therapeutic effect of
ECT is still unclear, but four important points are generally
believed to be true:
1. An induced generalized seizure appears to be necessary for
the production of a therapeutic response.
2. Seizures produced by barely suprathreshold stimuli are
diminished in efficacy regardless of seizure duration,
particularly with unilateral ECT (Sackeim et al. 1987). This
effect is probably even more prominent with ultra-brief-
pulse stimuli.
3. Seizures produced using markedly suprathreshold levels of
stimulus intensity appear to be associated with increased
cognitive side effects.
4. The stimulus intensity necessary to produce a
therapeutically adequate seizure increases across
subsequent treatments within an index ECT course.
21. Seizure Adequacy
• For many years, an ECT treatment was
considered therapeutically adequate if the
seizure was generalized and of a certain
duration (Abrams 2002; American Psychiatric
Association 2001; Ottosson 1960).
• Typical recommended minimal durations have
been 20–25 seconds for the motor response
and 25 seconds for the ictal
electroencephalographic (EEG) response.
22. Seizure Adequacy
• Because seizures tend to be shorter in elderly
patients and also to diminish over the treatment
course (Sackeim et al. 1991), some practitioners
have used a lower criterion (e.g., <20-second
seizure duration late in the treatment course if
the patient is older than age 60 years).
• Seizure duration also may be affected by a
number of other parameters, including the dose
of anesthetic agent and the amount to which the
stimulus exceeds the seizure threshold.
23. Stimulus Intensity
• Evidence suggests that the greater the ECT
stimulus intensity is with respect to seizure
threshold (i.e., the more suprathreshold the
stimulus), the more effective the treatments
and the speedier the recovery (Sackeim et al.
1993).
24. • However, a higher stimulus intensity is directly
related to an increase in cognitive side effects.
Thus, the logical approach would be to deliver
a stimulus that is moderately suprathreshold
• Seizure threshold varies greatly from person
to person (up to 40-fold) and also from
treatment to treatment, increasing variably
over the treatment course (Sackeim et al.
1991).
25. • Researchers do not yet know how much the
stimulus needs to be above seizure threshold
to be considered moderate, although for brief
pulse bilateral ECT, the estimate is 50%–100%
above the individual’s seizure threshold
(equivalent to 1.5–2 times seizure threshold),
whereas for brief pulse unilateral ECT,
estimates run 150%–500% above seizure
threshold (i.e., 2.5–6 times seizure threshold).
26.
27. Stimulus Dosing Strategies
• Two types of methods are generally used to
determine electrical stimulus intensity: the
dose-titration method and the preselected-
dose method (American Psychiatric
Association 2001)
28. Dose Titration
• starting with a stimulus dose at the first
treatment that has a moderate (e.g., 50%)
chance of inducing a seizure.
• Although beginning at a very low dose would
theoretically allow a more precise estimate of
seizure threshold for patients with low seizure
thresholds, it would also result in excessive
numbers of restimulations in patients with
higher seizure thresholds.
29.
30.
31.
32.
33. Electrode Placement
Bilateral and Right Unilateral Electrode Placement
• right unilateral electrode placement has also resulted
in decreasing the cognitive side effects (Squire and
Slater 1978; Strِmgren et al. 1976).
• This decrease may be due in part to the relative
sparing of nondominant mesial temporal lobe
structures by both the stimulus current path and the
induced seizure. The most commonly used unilateral
placement is the d’Elia placement (d’Elia 1970)
34.
35. the following statements appear to be supported by the
majority of clinical research and experience:
1. Either technique is generally effective in the treatment
of depression. However, some data suggest that
specific subgroups, especially patients with mania, may
not respond as thoroughly to unilateral treatments
(Mukherjee et al. 1994).
2. In some studies, patients reportedly responded faster
to bilateral placement, requiring fewer treatments for
a course of ECT (Sackeim et al. 2000).
3. Some depressed patients who did not respond to right
unilateral placement in ECT experienced significant
clinical improvement after they were switched from
unilateral to bilateral placement (Abrams et al. 1983)
36. 4. Stimulus intensity just above seizure threshold
markedly reduces the efficacy of unilateral ECT. This
effect may be present to a lesser degree in bilateral
ECT (Sackeim et al. 1993), particularly with ultra-brief-
pulse stimuli.
5. Bilateral ECT results in greater acute cognitive side
effects than does nondominant unilateral ECT. This
difference is most apparent in tests assessing or
requiring verbal function (Squire and Slater 1978).
Also, although most memory functions appear to be
restored in most patients 6 months after ECT,
persisting memory complaints are more common in
patients who receive bilateral ECT.
37. • Because of the cognitive advantages of
nondominant unilateral electrode placement
over bilateral electrode placement, a
reasonable approach is to routinely use
nondominant unilateral ECT in patients who
are more susceptible to profound confusional
states.
– These patients may include those who are elderly,
who have dementia, or who have developed
significant confusion during prior courses of ECT.
• Unilateral ECT is also preferable for individuals
who are highly concerned about the effects of
ECT on memory functioning.
38. Bilateral ECT is generally preferable for
patients in whom a rapid response is clinically
required (e.g., the actively suicidal patient or
the catatonic patient who refuses to eat)
those who have preferentially responded to
bilateral ECT in the past
who indicate a preference for this modality