Post-mortem changes after lead extraction from the ovine coronary sinus and great cardiac vein.

We investigated in sheep, non-thoracotomy extraction of leads which had been chronically implanted in the right atrium (RA), coronary sinus/great cardiac vein (CS/GCV) and right ventricle (RV) for atrial implantable defibrillation. Clinical success of extraction as well as gross and histologic findings in the heart are reported. Six of nine sheep had successful extractions. The major complication was laceration of the wall of the great coronary vein with hemorrhage into the pericardial space and cardiac tamponade. Tissue damage included several reversible changes: intra-tissue hemorrhage, thrombosis in the veins, and some necrosis of fat, vascular wall and myocardium. Myocyte necrosis was estimated as 0.03 to 0.3 grams of tissue. Osseous and cartilaginous metaplasia was more common around the RA lead than the CS/GCV lead. In cases where the lead must be removed, removal from the venous insertion site using lead extraction equipment should only be attempted with surgical back-up for emergency thoracotomy to control hemorrhage in the event of vessel laceration. Safer explantation of these leads from the vein entry site will require the development of new extraction procedures.

Preimplant atrial defibrillation testing with a temporary catheter in sheep.

Prior to implantation of an atrial defibrillator, its effectiveness should be tested in each patient. A new catheter design for temporary use with electrodes for atrial defibrillation, electrogram sensing, and pacing was tested in this study. Atrial defibrillation thresholds defined using this temporary catheter were compared to the ones defined by catheters intended for chronic use with an implantable atrial defibrillator. Atrial defibrillation threshold was determined in six sheep using both types of catheters. Each animal was subjected to studies on 2 consecutive days. On the first day, shocks were applied between two of the temporary catheters. On the following day, permanent leads were inserted and atrial defibrillation threshold was redetermined. In both cases, defibrillation electrodes were positioned in the same heart location with one electrode in the distal coronary sinus and the second electrode in the right atrium. Atrial defibrillation threshold was obtained using 10 V increments or decrements to determine the lowest shock intensity needed to defibrillate the atria. Threshold was defined as the shock intensity at which 20 shock percent success was at or between 15% and 85%. Statistical analysis showed no significant difference (P < 0.05) between atrial defibrillation threshold energy (0.53 J vs 0.55 J), voltage (122 V vs 120 V) or current (2.2 A vs 2.6 A) measured with the temporary catheters and the permanent leads, respectively. These data indicate that temporary catheters can be used for efficacy testing prior to implant of an atrial defibrillator, and that they predict atrial defibrillation threshold adequately for chronic leads.

Ventricular defibrillating threshold: strength-duration and percent-success curves.

The term defibrillation threshold is usually understood to mean the shock intensity just enough to defibrillate a specified cardiac chamber (atria or ventricles). With the advent of so many different types of defibrillator, it is important to be able to specify the defibrillation threshold, which has frequently been described by the classical strength-duration curve. Another method of representing defibrillation plots the percent-successful defibrillation against shock-strength area. The mechanism of defibrillation is discussed, and the concepts of the strength-duration curve and percent-success against shock-strength curves are compared. Because defibrillation is associated with a time-varying spectrum of cellular excitability, a given shock strength will not always achieve defibrillation, and this produces the sigmoid shape for the curve that relates percent-successful defibrillation to shock strength. Therefore it is important to recognise two concepts: first, there is a family of strength-duration curves for defibrillation, each curve representing a given percent-successful defibrillation, and, secondly, there is a family of percent-success against shock-strength curves, one for each pulse duration. Canine ventricular defibrillation data are used to bring these two concepts together. Most importantly, the concepts adduced in the paper apply to transventricular, intracardiac and transchest defibrillation; the only difference in these applications is a scale factor that represents electrode location with respect to the heart.

Maintenance of atrial fibrillation in anesthetized and unanesthetized sheep using cholinergic drive.

Atrial fibrillation (AF) was induced electrically and the duration of AF was measured in six isoflurane-anesthetized sheep (weight range 54.5-72.7 kg), and in five unanesthetized sheep (weight range 60-75 kg). In the anesthetized sheep, AF was induced by direct electrical stimulation of the right atrium with a catheter electrode and the duration of AF was determined. Intravenous neostigmine (10 micrograms/kg IV) was administered and the duration of AF was again measured. Then cholinergic drive was increased by bilateral electrical vagal stimulation; AF was induced and the duration of AF was measured. In the anesthetized animals with no neostigmine or vagal stimulation, 34% of the episodes of AF lasted 10 seconds, 11% lasted 20 seconds, and only 1% lasted 200 seconds. However, in one anesthetized animal AF was sustained for 4,800 seconds with no drug or vagal support. The administration of neostigmine alone in 3 anesthetized animals more than doubled the average duration of AF. In the animals with vagal stimulation (after neostigmine), AF persisted throughout stimulation, but ceased shortly after vagal stimulation was terminated at 2,220, 4,500, and 3,840 seconds. The AF frequency ranged from 325-750/min. The unanesthetized sheep were lightly sedated with a small dose (200 micrograms/kg IM) of xylazine to make them less sensitive to environmental noise; then AF was induced and its duration was timed. After these measurements, neostigmine was administered (30 micrograms/kg IM) and cholinergic drive was produced reflexly by intravenous injection of 60-2,000 micrograms of phenylephrine. AF was electrically induced at the time of maximum reflex slowing in heart rate. For the control (no drug) studies, 64% of the AF episodes lasted 10 seconds, 20% lasted 20 seconds, and only 2% of the episodes lasted as long as 140 seconds. When phenylephrine was injected after neostigmine to provide increased cholinergic drive, the duration of fibrillation depended on the dose of phenylephrine. In a 60-kg sheep, the duration of AF increased from 1 second with an intravenous dose of 60 micrograms to 700 seconds with an intravenous dose of 2,000 micrograms. However, there was a considerable range in responsiveness to the reflex cholinergic drive provided by the intravenous phenylephrine; for example a single intravenous 500-micrograms dose produced AF ranging from 190-540 seconds among the sheep. The duration of AF was most controllable in the anesthetized sheep, following neostigmine administration and with bilateral vagal stimulation. In the unanesthetized sheep, AF could generally be sustained for more than the duration of the half-life (about 4 minutes) of phenylephrine following neostigmine. However, there was a large variation in the duration of AF among the animals for the same dose of phenylephrine. This study identifies two methods (direct vagal stimulation and reflex vagal stimulation) for providing the cholinergic drive needed to sustain AF in the adult sheep. The duration of AF is sufficiently long to enable the measurement of electrical atrial defibrillation threshold.

The effect of elevated intracranial pressure on the vibrational response of the ovine head.

Although potentially fatal increases in intracranial pressure (ICP) can occur in a number of pathological conditions, there is no reliable and noninvasive procedure to detect ICP elevation and quantitatively monitor changes over time. In this experimental study, the relationships between ICP elevation and the vibrational response of the head were determined. An ovine animal model was employed in which incremental increases in ICP were elicited and directly measured through intraventricular cannulae. At each ICP increment, a vibration source elicited a flexural response of the animal's head that was measured at four locations on the skull using accelerometers. Spectral analysis of the responses showed changes in proportion to ICP change up to roughly 20 cm H2O (15 mm Hg) above normal; a clinically significant range. Both magnitude and phase changes at frequencies between 4 and 7 kHz correlated well (gamma > 0.92) with ICP across the study group. These findings suggest that the vibrational response of the head can be used to monitor changes in ICP noninvasively.

Detection of pulse and respiratory signals from the wrist using dry electrodes.

A dry, tetrapolar electrode array was used to detect the differential impedance signal at the wrists of 11 adult human subjects. Experiments were conducted to determine the importance of potential-sensing electrode spacing to detect each wearer's pulse rate and respiratory rate. The current-injecting electrodes were at the sides of the wrist; the potential-sensing electrodes were on the volar wrist surface. The bandwidth-filtered root-mean-square amplitudes of the pulse and respiratory components were computed and found to increase with increasing electrode spacing. Optimum spacings were slightly different for the pulse and respiration and were slightly different in the male and female subjects. A spacing for the potential electrodes of about 60% of the wrist hemicircumference is a good compromise for detecting respiration and pulse.

Comparison of the resistance to infection of intestinal submucosa arterial autografts versus polytetrafluoroethylene arterial prostheses in a dog model.

PURPOSE: Prosthetic graft infection represents a most challenging complication to the vascular surgeon. Although expanded polytetrafluoroethylene (ePTFE) grafts have an acceptable patency rate, especially in the large-diameter arterial location, bacterial contamination of this material usually requires surgical removal of the graft. METHODS: We compared the resistance of large-diameter ePTFE grafts and grafts constructed of small intestinal submucosa (SIS) to deliberate infection with Staphylococcus aureus. Eighteen dogs were divided into two equal groups, and the infrarenal aorta was replaced with either ePTFE or SIS graft material. One hundred million S. aureus organisms were deposited directly on the graft at the time of surgery, and the dogs were observed for 30 days. RESULTS: One dog with an ePTFE graft died of hemorrhage from anastomosis site at 21 days. Of the remaining eight dogs with ePTFE grafts, four had positive culture results from the removed graft material, and all had histologic evidence for persistent infection. These dogs also had chronic fever, and the average white blood cell count at day 30 was 15,600/mm3. All nine dogs with SIS grafts had patent grafts, were afebrile after the first week, had an average white blood cell count of 11,500/mm3 at 30 days (p value = NS), had negative culture results, and had the histologic appearance of graft remodeling with collagen that was free of active inflammation. CONCLUSIONS: We conclude that large-diameter arterial SIS grafts are more resistant to persistent infection with S. aureus than ePTFE grafts in this dog model of deliberate bacterial inoculation.

Output power and metabolic input power of skeletal muscle contracting linearly to compress a pouch in a mock circulatory system.

Output power and metabolic input power values were determined for unconditioned canine latissimus dorsi (two), gastrocnemius (seven), and triceps (three) muscles contracting linearly to cause compression of a doubly valved pouch in a hydraulic model of the circulation. The motor nerves to the muscles were stimulated tetanically with 450 msec trains of 0.1 msec pulses having a frequency of 50/sec. The muscles were contracted 10, 20, 30, and 40 times per minute and pouch output in milliliters per minute was measured directly for each muscle at each contraction (train) rate. The output power in milliwatts was determined by two methods: (1) by using the pouch output and the pressure rise imparted to the stroke volume (average power) and (2) by using the pressure-volume loop. Metabolic input power in milliwatts was determined from the oxygen consumption in milliliters per minute of the working muscle. It was found that as the pouch output was increased, the pouch output power and the metabolic input power both increased. The average power output was slightly less than that computed from the pressure-volume loop. The mean output power values, when pumping at L liters per minute, were 0.62 L (average) and 0.75 L mW/gm (pressure-volume loop) for the latissimus dorsi muscles; 0.83 L (average) and 1.16 L mW/gm (pressure-volume loop) for the gastrocnemius muscles; and 0.55 L (average) and 0.66 L mW/gm (pressure-volume loop) for the triceps muscles. The percent efficiency of energy conversion ranged from 9.2% to 17.8% for the latissimus dorsi muscles, from 5.1% to 19.5% for the gastrocnemius muscles, and from 10.5% to 27.3% for the triceps muscles. However, it should not be concluded that one muscle type is better than another on the basis of percent efficiency because efficiency does not take endurance into account. An important observation in this study relates to the large output obtained with the three linearly contracting muscle types. All were capable of pumping in excess of 1.5 L/min. A second observation relates to the absence of fatigue, although determination of endurance was not an objective in these studies.

Correlation of motor-evoked potential response to ischemic spinal cord damage.

The prevalence of morbidity is a major deterrent to the success of aortic aneurysm replacement operations. We have developed a model of spinal cord ischemia, based on the amplitude reduction of the motor-evoked potential, which produces approximately a 90% prevalence of paraplegia. Regional blood flow was studied with the use of radioactive microspheres, and results showed that there was a significant decrease in flow to the lumbar cord (85% reduction) during aortic occlusion, followed by a twofold to threefold hyperemia that persisted for 24 hours. Histopathologic examination of the cord revealed that the greater portion of microgliosis, spongiosis, and neuronal damage was confined to the gray matter of the cord, and its severity increased as one progressed caudally. The somatosensory-evoked potential disappeared before the motor-evoked potential L-2 signal in all dogs, with a mean disappearance time of 10.9 +/- 5.6 minutes, compared with 21 +/- 6.6 minutes for the motor-evoked potential. Both the sensory-evoked potential and the motor-evoked potential cord signal were present 24 hours later in all dogs tested. The peripheral nerve motor-evoked potential disappeared within 1 minute of cord ischemia, was not present 24 hours later, and hence appears to be too sensitive to use as an indicator of spinal cord damage. Plotting spinal cord motor-evoked potential amplitude reduction versus both histopathologic damage and regional blood flow revealed a positive correlation between motor-evoked potential amplitude reduction, decreased cord perfusion, and increased histopathologic damage. In addition, it may be possible to make inferences about the neurologic status of a subject based on the magnitude and time-course of the motor-evoked potential's amplitude reduction and wave morphology.

The effect of skeletal muscle ventricle pouch pressure on muscle blood flow.

Skeletal muscle powered assist ventricles (SMV) are being investigated in animal studies as a treatment for heart failure. Muscle fatigue is almost always dependent upon muscle capillary blood flow. This study examined the relationship between SMV intrapouch pressure and blood flow to the circumferential muscle in a working SMV with a mock circulation. The unconditioned rectus abdominis muscle was used to create an in situ SMV in five dogs. Muscle blood flow was measured by both the radioactive microsphere and the electromagnetic flow probe method as the pouch pressure was varied between 10 and 70 mmHg and as the SMV was stimulated to contract at a rate of 20 min-1. The correlation coefficient for the two methods was 0.908. At pouch pressures of 10, 40, and 70 mmHg, the respective blood flow values were 22.60 +/- 2.50 (1 SEM), 12.20 +/- 2.10, and 4.40 +/- 0.74 ml min-1 (p less than 0.05). When they were corrected for muscle weight, the mean blood flow values at these same pouch pressures were 0.28 +/- 0.03, 0.15 +/- 0.03, and 0.05 +/- 0.01 ml min-1 g-1, respectively (p less than 0.05). SMV output was measured for each pouch pressure that was tested. Pouch output, expressed as ml min-1, was 458 +/- 20 (1 SEM) at an SMV diastolic pouch pressure of 10 mmHg, 309 +/- 22 at a pouch pressure of 40 mmHg, and 103 +/- 6 at a pouch pressure of 70 mmHg.(ABSTRACT TRUNCATED AT 250 WORDS)

Pumping capabilities of the latissimus dorsi and rectus abdominis muscles wrapped around a valved pouch in a mock circulatory system.

The pumping capabilities of nine unconditioned canine rectus abdominus muscles (93-163 gm) and six latissimus dorsi muscles (99-146 gm) were measured. The muscles were wrapped around a 100 ml ellipsoidal pouch in a mock circulatory system in which the afterload was 100 mmHg. Pouch diastolic pressure was kept low by an electrically controlled inlet valve to maximize muscle capillary blood flow. Immediately before tetanic contraction of the pouch-encircling muscle, the inlet valve opened for 450 msec to increase pouch pressure to 100 mmHg, thereby providing a high preload and ensuring a forceful muscle contraction. The motor nerves to the muscles were stimulated with 450 msec trains of 0.1 msec stimuli, using a frequency of 40/sec. The train rates (muscle contractions/min) were 10-50/min. In this circulatory model it was found that the maximum output for both muscle types occurred between 20 and 40 contractions/min. It was also found that for both muscle types, the maximum output (L/min) was dependent upon muscle weight. The data revealed that an output of 4 ml/min was obtained per gram of muscle. The power (mW/gm) developed was related to the output (L) in L/min. For the rectus muscle W = 0.47L, and for the latissimus muscle W = 0.41L mW/gm. Pumping periods lasted approximately 4 hours, with no evidence of fatigue. When viewed as a potential cardiac assist device, the muscles were able to provide a flow equivalent to approximately 25% of the cardiac output. However, it is important to note that the pumping capability is directly related to muscle weight, indicating that a higher output can be achieved with a larger muscle.

Limitations of open-chest cardiac massage after prolonged, untreated cardiac arrest in dogs.

STUDY OBJECTIVES: Open-chest cardiac massage is an effective method of resuscitation if instituted within 15 minutes of normothermic cardiac arrest that has failed to respond to ongoing closed-chest CPR efforts. The usefulness of invasive forms of CPR after various periods of untreated cardiac arrest is less certain. This study was performed to determine the effectiveness of open-chest resuscitation after prolonged periods of untreated cardiac arrest. SETTING AND DESIGN: Prospective, controlled laboratory investigation using an animal model of cardiac arrest. Open-chest cardiac massage initially was compared to standard closed-chest compression CPR. The efficacy of open-chest CPR then was evaluated after ten and 40 minutes of untreated ventricular fibrillation. TYPE OF PARTICIPANTS: Twenty mongrel dogs (24 +/- 1 kg). MEASUREMENTS AND MAIN RESULTS: After 20 minutes of untreated ventricular fibrillation, open-chest resuscitation was significantly better than closed-chest efforts for the production of coronary perfusion pressure (58 +/- 14 vs 2 +/- 1 mm Hg; P less than .05) and initial resuscitation success (five of five vs one of five; P less than .03). Open-chest cardiac massage was equally effective for initial resuscitation if begun after ten or 20 minutes of untreated ventricular fibrillation (five of five vs five of five), but if untreated ventricular fibrillation continued for 40 minutes prior to instituting open-chest massage, no resuscitation benefit was found (none of five; P less than .005). There were marked differences in 24-hour survival depending on the length of time untreated cardiac arrest continued prior to instituting open-chest resuscitation efforts. After 20 minutes of ventricular fibrillation, initial resuscitation was successful with open-chest massage, but long-term survival was poor. CONCLUSION: Open-chest cardiac massage did not produce long-term survival if untreated cardiac arrest persisted for 20 or more minutes prior to invasive resuscitation efforts.

Comparison of canine skeletal muscle power from twitches and tetanic contractions in untrained muscle: a preliminary report.

Power output and blood flow were determined in dogs for four muscles (gastrocnemius, latissimus dorsi, rectus abdominis, and triceps) to determine effects of choice of muscle, tetany or twitch rates, force loading of the muscle, and blood flow on muscle power output. Total power for a 20-Kg dog was greatest for triceps at 0.77 watts (W) and least for rectus at 0.22 W; power per gram was greatest for gastrocnemius at 5.77 mW/g. Muscle perfusion of latissimus and rectus is greatly decreased by overstretching of the muscle. Overstretching also produces severe, persistent, power loss in latissimus and rectus muscles. Gastrocnemius and triceps tolerate stretching much better. We conclude that power can be improved without causing muscle fatigue by choice of muscle, choice of electrical stimulation parameters, linear geometry for contraction of the muscle, and matching the force load to each individual muscle.

Depletion of myocardial adenosine triphosphate during prolonged untreated ventricular fibrillation: effect on defibrillation success.

We studied left ventricular endomyocardial adenosine triphosphate levels in 13 large mongrel dogs before and during ventricular fibrillation induced cardiac arrest to assess whether myocardial adenosine triphosphate content could predict successful cardiopulmonary resuscitation. Endomyocardial biopsies were performed during sinus rhythm (control), after 15 min of ventricular fibrillation or 10 min of ventricular fibrillation and 5 min of open chest cardiopulmonary resuscitation, after 20 min of ventricular fibrillation and 10 min of open chest cardiopulmonary resuscitation and after 40 min ventricular fibrillation and 15-20 min open chest cardiopulmonary resuscitation. Myocardial adenosine triphosphate was measured utilizing a bioluminescence method adapted for use with endomyocardial biopsies and normalized to protein content. Left ventricular endomyocardial adenosine triphosphate content fell significantly over time from a control level of 8.88 +/- 0.9 micrograms/mg protein to 5.73 +/- 0.5 micrograms/mg protein at 15 min of cardiac arrest, to 3.4 +/- 0.4 micrograms/mg protein after 30 min of cardiac arrest and to 1.98 +/- 0.3 micrograms/mg protein after 60 min of cardiac arrest (P less than 0.001). Adenosine triphosphate levels were significantly different between animals that received 10 min of ventricular fibrillation and successful open chest cardiopulmonary resuscitation and those that received 40 min of ventricular fibrillation and unsuccessful open chest cardiopulmonary resuscitation (4.35 +/- 0.48 vs. 2.11 +/- 0.43 micrograms/mg protein; P less than 0.025).(ABSTRACT TRUNCATED AT 250 WORDS)

Amplitude and latency characteristics of spinal cord motor-evoked potentials in dogs.

The motor-evoked potential can be reliably recorded in anesthetized dogs by use of percutaneous placement of active recording electrodes near the dorsal lamina of the vertebral column. Two types of responses were observed in this study; short (less than 5.5 ms at T9-10)- and long (greater than 5.8 ms at T9-10)-latency waves. Short-latency waves are larger in amplitude and appear with higher stimulus intensities than do long-latency waves. Short-latency waves are conducted at greater than 80 m/s and may not reflect pyramidal tract activation. The safety of using higher intensity stimuli to generate short-latency waves has not been determined.

Suprathreshold brain stimulation activates non-corticospinal motor evoked potentials in cats.

In the feline model of the motor evoked potential (MEP) test, a multiphasic spinal cord signal can be elicited in response to bipolar or transcranial brain stimulation. Previous studies have shown that signals produced by threshold stimulation travel mostly in the corticospinal tract. However, from this study we show that suprathreshold stimulation produces very large amplitude MEPs which travel in the ventral funiculus and therefore are most likely associated with extrapyramidal tract activation. The data supporting this conclusion are: (1) apparent conduction velocities of the first two large amplitude peaks are at least 80 m/s with transcranial stimulation; (2) latency of the transcranial MEP at L2 in the cord is less than or equal to 3.50 ms; (3) large amplitude, positive monophasic potentials are recorded in the ventral but not dorsal-lateral funiculus for either bipolar or transcranial MEPs; (4) both bipolar and transcranial MEPs are significantly reduced or abolished by selective lesion of the ventral funiculus. The two tracts which we believe are responsible for mediating the suprathreshold MEP in the cat are the reticulospinal and vestibulospinal tracts. This is significant because suprathreshold MEPs can be used to monitor feline ventral cord function. Furthermore, combining the use of threshold and suprathreshold MEPs may provide a differential diagnostic test for pyramidal vs. extrapyramidal motor function.

The use of an electrically activated valve to control preload and provide maximal muscle blood flow with a skeletal-muscle ventricle.

A new method for optimally loading a skeletal muscle-wrapped pouch to act as a blood pump is described. The method takes advantage of the fact that the high preload pressure required for a forceful contraction needs to be present for only a short time. By using an electrically controlled valve to delay pouch filling until just before muscle contraction, pouch diastolic pressure can be kept low, which in turn maintains a high muscle capillary blood flow. The intrapouch precontraction pressure can be controlled by selecting the appropriate valve-open time (VOT). The pumping capabilities of untrained rectus abdominis and latissimus dorsi muscles were evaluated using a hydraulic circulatory system in a ten dog study (weight range 20-32.7 kg). The afterload was constant at 100 mmHg, and the pouch precontraction pressure, selected by choice of the VOT, was the test variable. It was found that for maximum pouch output, a precontraction pressure of 60-100 mmHg was required, being attained in this hydraulic model with a VOT of 400-500 msec. Typical pouch outputs were 400-600 mL/min with a muscle contraction rate of 40/min. Muscle capillary blood flow, measured with a periarterial electromagnetic flowmeter, varied inversely with pouch diastolic pressure and was near zero during tetanic muscle contraction. In one animal, a pouch output of 200 mL/min or more was maintained for more than 20 hours of continuous pumping without fatigue. In a related experiment, the method was applied to pump blood in a 32.7 kg dog, in which the muscle-wrapped pouch was connected between the descending thoracic aorta and the abdominal aorta. A pouch output of about 400 mL/min was obtained when the muscle was contracted 30 times/min and the VOT was 400 msec. This flow represented about 20% of the animal's cardiac output. This study demonstrates that by delaying pouch filling until just before the muscle is to be contracted, a low pouch diastolic pressure can be maintained, thereby maximizing muscle capillary blood flow and, in turn, providing the best opportunity for prolonged pumping.