Residual Neuromuscular Blockade Clinical Trial
Official title:
Electromyographic Assessment of Onset and Recovery of Neuromuscular Blockade
Residual neuromuscular blockade (weakness) is a common occurrence in the postanesthesia care unit when muscle relaxant drugs have been used in the operating room. The only method of reliably detecting the presence of neuromuscular blockade is through the use of quantitative neuromuscular monitors. These devices measure and quantify the degree of muscle weakness and display the results on a screen. When using train-of-four (TOF) nerve stimulation, the ratio of the fourth muscle contraction (twitch) to the first twitch will be displayed; when this ratio is 90% (or 0.9) or greater, full recovery of muscle strength is present, and the endotracheal tube can be removed. At the present time, there is only one commercially-available quantitative monitor available in the United States -the TOF-Watch. It is not used by many clinicians because it requires experience to obtain accurate results, is expensive, and is subject to interference by factors in the operating room. The aim of this investigation is to examine a new quantitative monitor (the T4-EMG (EMG = electromyography) that may not be subject to the same limitations as the TOF-Watch AMG (AMG = acceleromyography). In order to study the accuracy of this new device, the T4-EMG will be compared to the current "clinical gold standard", the TOF-Watch.
The aim of this investigation is to examine a new prototype of a quantitative monitoring
instrument that will meet these requirements. Patients undergoing surgery under general
anesthesia will be monitored with a new EMG device (T4-EMG) from induction of anesthesia
until recovery of neuromuscular blockade. Continuous data will be recorded onto an interfaced
computer from the T4-EMG monitor during this time period. At the same time, continuous
neuromuscular data will be recorded onto the computer from an AMG device (TOF-Watch, the
"established standard" for clinical use) which is attached to the same arm. The applicability
(ease of use, equipment need, etc.), repeatability (precision or internal consistency), and
performance (agreement with established standard, bias) of the T4-EMG compared to the AMG
will be determined during onset and recovery of neuromuscular blockade.
44 patients presenting for elective surgical procedures with an expected duration greater
than 60 minutes will be enrolled in this study. ASA I to III patients requiring neuromuscular
blockade in the operating room will be eligible for enrollment. Anesthetic management will be
standardized.
Upon arrival to the operating room, neuromuscular monitoring surface electrodes will be
applied. All monitoring will be conducted while the patient is under general anesthesia for
the surgical procedure. Surface electrodes (non-invasive EKG electrodes) will be placed on
the cleansed skin over the ulnar nerve of the available arm near the wrist. The electrodes
will be connected by leads to a peripheral nerve stimulator (TOF-Watch). When the nerve
stimulator is activated, the response to stimulation will be measured simultaneously by the
AMG (TOF-Watch-acceleration of contraction of the adductor pollicis-thumb) and the EMG
(T4-EMG-electrical activity of the adductor pollicis-thumb) devices. Therefore, the TOF-Watch
will serve as nerve stimulator for both study groups. The transducer of the AMG device will
be placed on the thumb of the corresponding hand. A 75-150g preload (via the Hand adapter)
will be applied as per standard recommendations. After induction of anesthesia, but before
administration of rocuronium, calibration, supramaximal stimulation, and stable baseline will
be achieved for the TOF-Watch as suggested by the GCRP guidelines.
The T4-EMG will be placed on the same arm as the AMG device, with sensing electrodes attached
to the surface of the thenar eminence (base of the thumb). A second sensing lead, used to
detect the delivery of an electrical stimulating pulse, will be placed over the stimulating
leads of the AMG device. This sensing lead will only be used to trigger data acquisition in
the T4-EMG, and has no direct connection to the patient, nor any electrical feedback
connection that alters the function of the AMG. After a satisfactory level of stimulation and
response has been obtained for the TOF-Watch, the T4-EMG device will be turned on, and the
impedance of the thenar sensing leads will be measured. The trigger sense will be engaged,
and further baseline stimuli will be delivered via the AMG (TOF-Watch). Data simultaneously
collected from the thenar sensing leads will be inspected on the T4-EMG display, and fine
adjustment of electrode positioning and stimulus intensity may be made to optimize the evoked
myoelectric response from the patient. At the conclusion of the setup procedure, all settings
of the AMG and the T4-EMG will be held constant for the remainder of the surgery.
After these baseline data are collected (average time 5 minutes), the neuromuscular blocking
agent (NMBA) will be administered. Data relating to onset (a TOF ratio decreases from 1.0 to
0.3 or less on the AMG device display), maintenance (the TOF ratio is less than 0.3 and
constant on the AMG device display), and reversal (an increase in the TOF ratio from 0.1 to
0.9 or above) will be recorded. Monitoring will continue until full recovery of neuromuscular
function is noted (a TOF ratio of at least 0.9 or greater on the AMG device display). At this
time, the anesthesia agents will be turned off and the patient awakened and extubated.
Patients' trachea may extubated before achieving a TOF ratio of 0.9 if they awaken before
this time, as per usual clinical routine determined by the clinician.
For the first 34 patients, the TOF-Watch is used as the nerve stimulator for both the AMG
(TOF-Watch) and EMG (T4-EMG) groups. The ability of the T4-EMG device to sense/measure TOF
ratios is the primary aim of the study (in comparison to the "clinical gold standard"
TOF-Watch). However, the prototype T4-EMG (as well as the commercial device to be developed)
will also contain a nerve stimulator (as do all qualitative and quantitative monitors). On a
subset of patients monitored by the TOF-Watch (10 patients), the stand-alone T4-EMG device
(single unit containing both the nerve stimulator and sensing/monitoring components) will be
connected to the same arm and operated independently of the TOF-Watch. Its stimulating
electrodes will be placed on the surface of the arm adjacent to the TOF-Watch electrodes;
sensing leads will be placed on the thenar eminence as in the protocol described above. The
T4-EMG will be set up independently of the TOF-Watch, with its own stimulator adjustment
being made according to the same protocol as the TOF-Watch adjustment. The T4-EMG will be
operated to stimulate and record at times selected by the anesthesiologist that do not
conflict with operation of the TOF-Watch or interfere with other patient care activities.
Evoked muscle response data will be displayed by the T4-EMG, but amplitude ratios will not be
computed and it will not be used for direct patient care. The purpose is to demonstrate that
the device elicits and records evoked muscle responses from surgical patients and to assess
usability: this is in contrast to the main protocol where the T4-EMG is triggered by the
TOF-Watch and where comparison of recorded responses is the goal.
The primary endpoint in the first 33 patients will be an analysis of the agreement between
the AMG (clinical "gold standard") and EMG devices during neuromuscular recovery. Data will
be compared between the two devices at AMG-derived TOF ratios values of 0.7, 0.8, 0.9, and
1.0 (if achieved) during recovery of neuromuscular function. Bias and limits of agreement
will be calculated at each TOF value.
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