Here, we present a protocol to produce tachycardia-induced cardiomyopathy in swine. This model represents a potent way to study the hemodynamics of progressive chronic heart failure and the effects of applied treatment.
A stable and reliable model of chronic heart failure is required for many experiments to understand hemodynamics or to test effects of new treatment methods. Here, we present such a model by tachycardia-induced cardiomyopathy, which can be produced by rapid cardiac pacing in swine.
A single pacing lead is introduced transvenously into fully anaesthetized healthy swine, to the apex of the right ventricle, and fixated. Its other end is then tunneled dorsally to the paravertebral region. There, it is connected to an in-house modified heart pacemaker unit that is then implanted in a subcutaneous pocket.
After 4 – 8 weeks of rapid ventricular pacing at rates of 200 – 240 beats/min, physical examination revealed signs of severe heart failure – tachypnea, spontaneous sinus tachycardia, and fatigue. Echocardiography and X-ray showed dilation of all heart chambers, effusions, and severe systolic dysfunction. These findings correspond well to decompensated dilated cardiomyopathy and are also preserved after the cessation of pacing.
This model of tachycardia-induced cardiomyopathy can be used for studying the pathophysiology of progressive chronic heart failure, especially hemodynamic changes caused by new treatment modalities like mechanical circulatory supports. This methodology is easy to perform and the results are robust and reproducible.
The variety of new treatment methods for heart failure (HF), especially the growing worldwide use of mechanical circulatory supports and extracorporeal membrane oxygenation (ECMO) in clinical practice, is reflecting in preclinical experimental testing. The main focus has been on hemodynamic changes caused by the examined treatment modalities, namely on systemic blood pressure1, myocardial contractility, pressure and volume changes in heart chambers and heart work2,3, arterial blood flow in systemic and peripheral arteries, along with metabolic compensation4 – regional tissue saturation, pulmonary perfusion, and blood gas analysis. Other studies are directed on long-term effects of the circulatory support5, concomitant inflammation, or occurrence of hemolysis. All these types of study need a stable biomodel of congestive HF.
Most of the published experiments on left ventricular (LV) performance and hemodynamics of mechanical circulatory support have been performed on experimental models of acute HF2,6,7,8,9,10, or even on completely intact hearts. On the other hand, in clinical practice, mechanical circulatory supports are often being applied in a status of circulatory decompensation that develops on the grounds of previously present chronic heart disease. In such situations, the adaptation mechanisms are fully developed and can play important roles in inconsistency of outcomes observed according to the "acuteness or chronicity" of underlying cardiac disease11. Therefore, a stable model of chronic HF can offer new insights into pathophysiological mechanisms and hemodynamics. Although there are reasons why the use of chronic HF models is scarce – time consuming preparation, instability of heart rhythm, ethical questions, and mortality rate – their advantages are clear, as they offer presence of long-term neurohumoral activation, general systemic adaptation, functional changes of cardiomyocytes, and structural alterations of heart muscle and valves12,13.
In general, the availability and variety of animal models used for hemodynamic studies is wide and offers choice for many specific needs. For these experiments, mostly porcine, canine, ovine, or with smaller settings murine models, are being chosen and offer a good simulation of expected human bodily reactions14. Furthermore, forms of single organ experiments are becoming more frequent15. To reliably mimic the pathophysiology of HF, circulation is being artificially deteriorated. Damage to the heart can be caused by various methods, often by either ischemia, arrhythmia, pressure overload, or cardiotoxic effects of drugs, with any of these leading to hemodynamic deterioration of the model. To produce a true model of chronic HF, time has to be provided for developing the long-term adaptation of the whole organism. Such a reliable and stable model is represented well by tachycardia-induced cardiomyopathy (TIC), which can be produced by rapid cardiac pacing in experimental animals.
It has been shown that in predisposed hearts, long-lasting incessant tachyarrhythmias can lead to systolic dysfunction and dilation with decreased cardiac output. The condition referred to as TIC was first described in 191316, widely used in experiments since 196217, and is now a well-recognized disorder. Its origin can lie in various types of arrhythmias – both supraventricular and ventricular tachycardia can lead to progressive deterioration of systolic function, biventricular dilation, and progressive clinical signs of HF including ascites, edemas, lethargy, and ultimately cardiac decompensation leading to terminal HF and, if not treated, death.
Similar effects of circulatory suppression were observed by introduction of high rate cardiac pacing in animal models. In a porcine model, an atrial or ventricular heart rate over 200 beats/minute is potent enough to induce end-stage HF in a period of 3 – 5 weeks (progressive phase) with characteristics of TIC, though interindividual differences do exist18,19. These findings correspond well to decompensated cardiomyopathy and are, importantly, preserved also after the cessation of pacing (chronic phase)19,20,21,22,23.
Porcine, canine, or ovine TIC models were repeatedly prepared to study the pathophysiology of HF14, as changes to the LV mimic the characteristics of dilated cardiomyopathy24. The hemodynamic characteristics are well described – increased ventricular end-diastolic pressures, decreased cardiac output, increased systemic vascular resistance, and dilation of both ventricles. In contrast, wall hypertrophy is not observed consistently, and even wall thinning was described by some researchers25,26. With progression of ventricular dimensions, regurgitation on atrioventricular valves develops26.
In this publication, we present a protocol to produce a TIC by long-term fast cardiac pacing in swine. This biomodel represents potent means to study decompensated dilated cardiomyopathy, hemodynamics of progressive chronic HF with low cardiac output, and effects of applied treatment.
This experimental protocol was reviewed and approved by the Institutional Animal Expert Committee at First Faculty of Medicine, Charles University, and was performed at the University experimental laboratory, Department of Physiology, First Faculty of Medicine, Charles University in Prague, Czech Republic, in accordance with Act No. 246/1992 Coll., on the protection of animals against cruelty. All animals were treated and cared for in accordance with the Guide for the Care and Use of Laboratory Animals, 8th edition, published by National Academies Press, 2011. All procedures were performed according to standard veterinary conventions and at the completion of each study, the animal was sacrificed and a necropsy performed. Due to suitable anatomy, five healthy crossbred female swine (Sus scrofa domestica) up to 6 months of age were included in this experiment. Their mean body weight was 66 ± 20 kg at the day of data collection.
1. General Anesthesia
2. Ventricular Lead Implantation
3. Subcutaneous Lead Tunneling
4. Pacemaker Implantation
5. Postoperative Care
6. Pacing Protocol
7. Heart Failure Induction and Monitoring
Figure 1: Heart pacing unit schematic. The dual-chamber pacemaker (1), a "Y" shaped adapter (2) conducting convergently both pacemaker outputs together to a single pacing lead (3). The tip of the lead is fixated into the apical part of the RV cavity (4). This setting provides a wide range of high pacing frequencies. Please click here to view a larger version of this figure.
Figure 2: Heart pacing unit. X-ray (A) and photography (B) of the dual-chamber pacemaker (1), a "Y" shaped adapter (2), and the ventricular pacing lead (3). Please click here to view a larger version of this figure.
Desired HR | Set pacemaker rate | Pace to pace interval |
beats/min | beats/min | ms |
200 | 100 | 300 |
220 | 110 | 270 |
240 | 120 | 250 |
250 | 125 | 240 |
Table 1: Pacemaker parameters. To allow high rate cardiac pacing with the implanted in-house-modified dual-chamber pacemaker unit, the table shows the desired paced heart rate (HR) and matching pace to pace interval values. The pacemaker must be set to D00 operation mode at a rate of half of the desired HR, and the AV delay set to the corresponding pace to pace interval in milliseconds.
Figure 3: Pacing protocol. The progressive phase of the TIC induction starts after a resting period of 3 days. Then, the pacemaker is set to D00 mode with a pacing frequency of 50% of the desired paced frequency, and AV delay is set to the matching pace to pace interval (see Table 1). Thanks to the "Y" shaped adapter, both pacemaker outputs are conducted to a single pacing lead. bpm = beats/minute. Please click here to view a larger version of this figure.
Testing the model: After signs of decompensated chronic HF became prominent, anesthesia and artificial ventilation were administered again following the principles described above, but dosing was adjusted due to low cardiac output27. Due to possible cardiodepressive effects of anesthetics, careful intensive monitoring of vital functions is necessary.
The animal was attached in the supine position and all invasive approaches commenced. The femoral vein and artery and jugular vein were punctured and intravascular approaches ensured by standard percutaneous intraluminal sheaths. Right carotid and subclavian arteries were surgically exposed and circumjacent ultrasound flow probes of appropriate sizes were attached, enabling the obtainment of continuous blood flow measurements28.
Central venous pressure (CVP) was measured via the jugular vein using a standard invasive method with a fluid-filled pressure transducer, but a high-sensitivity pressure sensor equipped catheter in the thoracic aorta was used for systemic arterial pressure measurements. Regional tissue oxygenation was monitored by near-infrared spectroscopy with sensors placed on the head and right forearm representing the brain and peripheral tissue oxygen saturation levels (rSO2)29. A transthoracic echocardiographic probe was used for 2D and color Doppler imaging. Data from ECG, heart rate, pulse oximetry, blood pressures, capnometry, and rectal temperature were centralized on a bed-side monitor for immediate control. A balloon Swan-Ganz catheter was introduced through a femoral vein sheath to the pulmonary artery allowing readings of thermodilution derived continuous cardiac output (CO)30 and mixed venous hemoglobin saturation (SvO2). Through the aortic valve, a pressure-volume (PV) catheter was introduced retrogradely to the LV cavity. This PV conductance catheter enabled the registration of instant volume and pressure in the LV chamber31,32,33,34, and its stable position was guided by fluoroscopy and echocardiography to obtain optimal PV loop morphology (Figure 4 and Figure 5). Measured LV parameters included end-diastolic pressure and volume (EDP and EDV), end-systolic volume (ESV), LV peak pressure (LV PP), and maximal positive change of LV pressure, defined as the first time derivative of LV pressure normalized to EDV (dP/dtmax / EDV), which then represents a preload independent index of LV contractility35,36. Additional calculated parameters were stroke volume (SV = EDV – ESV), left ventricular ejection fraction (EF = SV / EDV), and averaged arterial flow in the carotid and subclavian arteries. Fluoroscopic guidance and X-ray imaging were conducted by a C-arm throughout the protocol. After conclusion of the experimental measurements, euthanasia by intravenous potassium overdose and autopsy were performed. The heart was exposed, cut out from the chest, emptied of blood, weighed, and investigated for structural abnormalities.
All data were acquired in native sinus rhythm after the rapid ventricular pacing had been stopped abruptly and time had been provided for stabilization to steady state conditions. Parameters were then recorded and sets of data averaged from three end-expiratory time points. If present, premature beats were omitted from the analyses. All values are expressed as mean ± standard deviation.
Measured results: Physical examination revealed severe clinical signs of chronic HF in all animals after 4 – 8 weeks of pacing protocol. Detailed results are summarized in Table 2.
Initial mean heart rate of sinus rhythm was 100 ± 38 beats/min, the mean aortic blood pressure reached 47 ± 38 mmHg and CVP 14 ± 4 mmHg. Chest X-rays showed heart shadow dilation, with a cardiothoracic ratio of 0.64 ± 0.04 (Figure 5A). This is in concordance with transthoracic echocardiography findings. Dilation of all heart chambers, severe systolic dysfunction of both ventricles, and significant mitral and tricuspid regurgitations were apparent on echocardiography. Mean ejection fraction of the left ventricle was below 30% in all animals, the LV wall was judged non-hypertrophic with a thickness of 7 – 10 mm and dyssynchrony of LV contraction was obvious (Figure 6).
Thermodilution measured cardiac output in the resting state was 2.9 ± 0.8 L/min and mixed venous blood saturation 62 ± 18% corresponded with inadequate tissue oxygen delivery in this model. Average arterial blood flow in the carotid artery was 211 ± 144 mL/min and in the subclavian artery was 103 ± 108 mL/min. Similarly, regional tissue saturation recorded transcutaneously on the head was only 57 ± 13%, and it was even lower on the right forearm, at 37 ± 13%.
The pressure volume loop obtained from the PV catheter illustrates the detailed hemodynamic measures and work produced by the mechanical activity of the left ventricle during each cardiac cycle (Figure 4). Maximum LV peak pressure was reduced to 49 ± 32 mmHg, but EDP remained low at 7 ± 4 mmHg. The measured volumes of the left ventricular chamber were reflective of its dilation and systolic dysfunction. EDV was increased to 189 ± 59 mL and ESV to 139 ± 37 mL. Averaged SV was 51 ± 45 mL and the mean LV ejection fraction was calculated to be 25 ± 16%. In addition, a preload independent index of LV contractility can be represented by a dP/dtmax / EDV ratio, which was averaged to 2.2 ± 1.7 mmHg/s/mL.
An autopsy confirmed cardiomegaly (Figure 7) with a mean heart weight of 471 ± 127 g, which formed 0.7% of body weight. Dilation of all heart chambers and LV wall thinning were stated, and fluid collections were described in pericardial and peritoneal spaces. No shunt or other cardiac anomaly was found in any of the animals.
Figure 4: Pressure-volume measurements. Samples of direct left ventricular PV loops (A-D) and schematic averaged PV loop of all TIC subjects (E). LV PP = LV peak pressure, EDP = end-diastolic pressure, EDV = end-diastolic volume, and SV = stroke volume. Please click here to view a larger version of this figure.
Figure 5: Chest X-rays. Enlarged heart shadow (red arrow) and increased cardiothoracic ratio (A). Note the pacing lead introduced to the apex of right ventricle (1), Swan-Ganz catheter placed in the pulmonary artery (2), and PV catheter with 5 electrodes in left ventricular chamber (3). For comparison, a chest X-ray of the normal heart from the day of pacemaker implantation (B). Please click here to view a larger version of this figure.
Figure 6: Transthoracic echocardiography. Representative tachycardia-induced cardiomyopathy with severe dilation of all heart chambers (A) and a similar view obtained before the pacemaker was implanted (B), for comparison. Both acquisitions were taken at end-diastole. Notice the visible tip of pacing lead in RV apex in (A). RV = right ventricle, and LV = left ventricle. Please click here to view a larger version of this figure.
Figure 7: Photographs of exposed heart. Cardiomegaly (A) after the TIC induction. Normal porcine heart sample for size comparison (B) (scales in cm). Please click here to view a larger version of this figure.
Parameter | TIC value | Units | ||
Imaging | ||||
CTR | 0.64 | ± | 0.04 | |
LV EF | < 30 | % | ||
LV EDD | 66 | ± | 3 | mm |
RV EDD | 40 | ± | 6 | mm |
AV regurgitations | severe | |||
Circulation parameters | ||||
HR | 100 | ± | 38 | beats/min |
MAP | 47 | ± | 38 | mmHg |
CO | 2.9 | ± | 0.8 | L/min |
SvO2 | 62 | ± | 18 | % |
rSO2 head | 57 | ± | 13 | % |
rSO2 right forearm | 37 | ± | 13 | % |
Carotid flow | 211 | ± | 144 | mL/min |
Subclavian flow | 103 | ± | 108 | mL/min |
CVP | 14 | ± | 4 | mmHg |
Pressure-volume acquisition | ||||
LV PP | 49 | ± | 32 | mmHg |
LV EDP | 7 | ± | 4 | mmHg |
LV EDV | 189 | ± | 59 | mL |
LV ESV | 139 | ± | 37 | mL |
SV | 51 | ± | 45 | mL |
LV EF | 25 | ± | 16 | % |
dP/dtmax / EDV ratio | 2.2 | ± | 1.7 | mmHg/s/mL |
Autopsy | ||||
mean heart weight | 471 | ± | 127 | g |
cardiomegaly, dilation of heart chambers, LV wall thinning, pericardial fluid collections |
Table 2: Numerical results of the TIC model after cessation of pacing protocol. All values expressed as mean ± standard deviation. CTR = cardiothoracic ratio, LV EF = LV ejection fraction, LV EDD / RV EDD = LV / RV end-diastolic diameter, AV regurgitations = atrioventricular valve regurgitations, HR = heart rate, MAP = mean aortic pressure, CO = cardiac output, SvO2 = mixed venous hemoglobin saturation, rSO2 = regional tissue saturation, CVP = central venous pressure, LV PP = LV peak pressure, LV EDP / LV EDV = LV end-diastolic pressure/volume, LV ESV = LV end-systolic volume, and SV = stroke volume.
Chronic HF is a major health problem that contributes greatly to morbidity and mortality. The pathogenesis and progression of HF in humans is complex, so an appropriate animal model is critical to investigate the underlying mechanisms and to test novel therapeutics that aim to interfere with native severe disease progression. To study its pathogenesis, large animal models are being used for experimental testing.
In general, surgical models of chronic HF closely mimic this disease. When compared to models of acute HF, chronic HF models offer more insight into the pathophysiology, but at the cost of time consuming experimental preparation or higher mortality rate. From the variety of known chronic HF models, we are referring to an appropriate and easily manageable model, represented here by decompensated chronic HF induced by paced tachycardia.
Tachycardia-induced cardiomyopathy as a form of dilated cardiomyopathy is inducible by fast cardiac pacing. The pacing electrode can be located in the ventricles or atria19,24. We omitted the supraventricular pacing site to prevent problems possibly caused by atrioventricular block during high pacing frequencies. The ventricular position also improved the stability of the pacing lead fixated in the ventricular apex compared to the atrial position and reduced occurrence of its dislocation. The presented methodology is specifically designed for easy performance, use of widely available equipment, and prevention of complications. Another goal of this method was to easily control chronic HF progression by titration of the pacing protocol.
Bacterial infection complications are a major problem of implants in experimental settings. Generator pocket infections and infective endocarditis are both associated with poor prognoses and would make the experiment futile. Due to porcine anatomy, the jugular region is exposed and if a pacemaker generator was placed here, healing and preventing contamination would be a difficult task in long-survival experiments. The usage of subcutaneous tunneling enables the location of the pacemaker generator pocket to the dorsal region, which is accessible and can be kept in a hygienic state. The pacemaker is also not within the animal's reach, which considerably improves healing. An alternative approach could be the use of an extracorporeal pacemaker generator attached to the skin surface, but this tactic was shown to be mechanically vulnerable, if long-term animal survival was intended.
All equipment necessary for the described protocol are widely available, and this method is reproducible with basic surgical and catheterization skills. The purpose of the "Y" shaped connection unit is to use a regular dual-chamber pacemaker, as it converges both of its outputs (atrial and ventricular) to the tip of the single pacing lead. These settings allow a wide range of high rate pacing frequencies (200 – 300 beats/min, Figure 1 and Table 1).
The most critical step is the titration of pacing frequencies. Too high from the beginning would cause acute decompensation with no time for the adaptation mechanisms to develop; conversely, titrating the pacing too low would be well tolerated and would prolong the HF induction.
According to previous publications22,25,37 and the authors' experience, the pacing protocol was defined and started with pacing rate of 200 beats/min, which is above physiological rate of healthy swine in exercise or stress. Subsequently, the frequency was escalated and titrated between 200 and 240 beats/min with respect to individual HF progression13,19. Due to interindividual differences in response to fast pacing, the time needed to produce chronic HF with profound signs of decompensation varied from 4 to 8 weeks. An issue here can become the battery life, as such high rate pacing increases energy demands. Especially when the pacing threshold is elevated, regular interrogations are important.
After the pacing protocol, symptoms of chronic HF were prominent consistently in all animals – tachypnea, fatigue, spontaneous tachycardia of >150 beats/min, and systolic murmurs. After further clinical investigation, ascites, pericardial and pleural effusions, non-sustained ventricular tachycardias, dilation of all heart chambers, and significant mitral and tricuspid regurgitations were described. Failing hemodynamics was indicated by arterial hypotension, poor myocardial contractility, low stroke volume, and cardiac output reduced to approximately 50% of a healthy animal's expected normal value38. This developed model of tachycardia induced cardiomyopathy matched well to poorly compensated dilated cardiomyopathy and was also preserved after the cessation of pacing21,39,40.
The fact that systolic function continues to be severely deteriorated after cessation of pacing makes the model an excellent choice to examine HF in native sinus rhythm. It has been previously shown that tachycardia-induced systolic dysfunction is at least partially reversible in the so-called recovery phase, but the time needed for it to improve or normalize varies significantly between individuals. The pacing protocol duration and aggressiveness of rate titration may be a significant contributor too, as permanent ischemic and fibrotic changes are produced in the myocardium22,39,40,41. The persistence of severe systolic dysfunction in the presented model was tested at least for 12 h after the pacing had been ceased4 and the qualities of the prepared model including neurohumoral dynamics, peripheral vascular abnormalities, and cardiac dysfunction were reflective of human chronic HF14.
The presented results demonstrate severely deteriorated hemodynamics, both clinical investigation and measured values indicate induction of HF syndrome. Cardiomegaly was consistently observed by clinical examination, imaging, and autopsy. Heart rate of sinus rhythm after the cessation of fast pacing was elevated from normal resting frequency, but we assume that the influence of cardiodepressive effects of anesthetics could limit this spontaneous tachycardia. Aortic pressures show deep hypotension42 and CVP was elevated.
Functional reflection is then the failing circulation and tissue hypoperfusion. These are primarily caused by impaired myocardial contraction, as indicated by the low ejection fraction of the left ventricle. Both ventricles were dilated with no extension in wall thickness, and this heart remodeling was grounds for progressive atrioventricular regurgitations and consequently low cardiac output. As no anatomical shunts were found postmortem, the cardiac output was equally low in systemic as well as in pulmonary circulation, and so the thermodilution derived cardiac output measurements in the pulmonary artery were used to calibrate the PV loop volume characteristics.
The brachial and brain regional tissue oxygen saturation as well as the regional blood flow in subclavian and carotid artery suggests centralization of the blood circulation. Their low values show severely reduced tissue perfusion in peripheral as well as in vital organs, which was confirmed by low SvO2 when compared to the expected normal value of at least 65%42. The general low tissue perfusion was in concordance with the measurements of low cardiac output.
Hemodynamics and mechanical work during each cardiac cycle of the left ventricle was well documented by the PV diagram obtained from PV catheter instant measurements. Poor myocardial strength was denoted by maximum LV peak pressure during systole and the dP/dtmax / EDV ratio, a preload independent index of LV contractility. LV chamber volumes were enlarged during the whole cycle, thus the image of dilated cardiomyopathy. The end-diastolic LV pressure was not increased as high as would be expected in cardiogenic shock. The LV filling pressure remains low, most likely due to high compliance of the LV thin myocardial wall43.
In the vast majority of previous TIC studies, porcine and canine models have been used19. However, rapid pacing can be used to induce cardiomyopathy in other species, even in small animals. Few studies have demonstrated metabolic effects of acute TIC in rats44 or myocardial contractility impairment after long-term fast pacing in rabbits45.
Although this model is adequately reliable, it has several limitations. Non-sustained ventricular tachycardias are a sign of successful HF induction, but long-lasting VT produce risks of sudden cardiac death. During anesthesia, one of the animals required resuscitation and defibrillation. The wide dispersion of results was partly due to differences in animal body weight. Also, the necessity of anesthesia has to be taken under consideration when reporting the results, especially its influence on heart rate and blood pressure. Blood levels of porcine-specific markers could be useful for assessment of the degree of cardiac remodeling, but the evidence on this front is still lacking. As most of these measurement methods were invasive and thus unrepeatable, we did not provide a baseline or sham subject measurement.
A model of progressive chronic heart failure can be produced by the presented methodology. This technique is easy to perform with widely available equipment, and the results are robust and reproducible. This tachycardia-induced cardiomyopathy offers a valuable object for further experimental studies on hemodynamics, investigation of disease mechanisms and effects of applied treatments.
positives | negatives |
chronic heart failure syndrome with systemic adaptation | time consuming model preparation |
easy control of disease progression | close monitoring necessary |
lead tunneling prevents infective complications | risk of lead dislocation |
done with basic surgical and cathetrization skills | risk of malignant arrhythmia |
potentially transferable to different animal species |
Table 3: Overview summarizing the positives and negatives of the presented methodology for tachycardia-induced cardiomyopathy in swine as a model of chronic heart failure.
The authors have nothing to disclose.
This work was supported by Charles University research grants GA UK No. 538216 and GA UK No. 1114213.
Medication | |||
midazolam | Roche | Dormicum | anesthetic |
ketamine hydrochloride | Richter Gedeon | Calypsol | anesthetic |
propofol | B.Braun | Propofol | anesthetic |
cefazolin | Medochemie | Azepo | antibiotic |
Silver Aluminium Aerosol | Henry Schein | 9003273 | tincture |
povidone iodine | Egis Praha | Betadine | disinfection |
morphine | Biotika Bohemia | Morphin 1% inj | analgetic |
Tools | |||
Metzenbaum scissors, lancet with #22 blade, DeBakey forceps, needle driver | basic surgical equipment | ||
cauterizer | |||
2-0 Vicryl | Ethicon | V323H | absorbable braided suture |
2-0 Perma-Hand Silk | Ethicon | A185H | silk tie suture |
2-0 Prolene | Ethicon | 8433H | non-absorbable suture |
Diagnostic devices | |||
ESP C-arm | GE Healthcare | ESP | X-ray fluoro C-arm |
Acuson x300 | Siemens Healthcare | ultrasound system | |
Acuson P5-1 | Siemens Healthcare | echocardiographic probe | |
Acuson VF10-5 | Siemens Healthcare | sonographic vascular probe | |
3PSB, 4PSB and 6PSB | Transonic Systems | perivascular flow probes | |
TS420 | Transonic Systems | perivascular flow module | |
TruWave | Edwards Lifesciences | T001660A | fluid-filled pressure transducer |
7.0F VSL Pigtail | Transonic Systems | pressure sensor catheter | |
INVOS 5100C Cerebral/Somatic Oximeter | Somanetics/Medtronic | near infrared spectroscopy | |
CCO Combo Catheter | Edwards Lifesciences | 744F75 | Swan-Ganz pulmonary artery catheter |
Vigillace II | Edwards Lifesciences | VIG2E | cardiac output monitor |
7.0F VSL Pigtail | Transonic Systems | pressure-volume catheter | |
ADV500 | Transonic Systems | pressure-volume system | |
LabChart and PowerLab | ADInstruments | data acquisition and analysis system | |
Prism 6 | GraphPad | statistical analysis software | |
Pacing devices | |||
ICS 3000 | Biotronic | 349528 | pacemaker programmer |
ERA 3000 | Biotronic | 128828 | external pacemaker |
Effecta DR | Biotronic | 371199 | dual-chamber pacemaker |
Tendril STS | St. Jude Medical | 2088TC/58 | ventricular pacing lead |
Lead permanent adapter | Osypka | Article 53422 | convergent "Y" connecting part |
Lead permanent adapter | Osypka | Article 53904 | convergent "Y" connecting part |
Tear-Away Introducer 7F | B.Braun | 5210593 | tear away introducer sheath |
Split Cath Tunneler | medComp | AST-L | tunneling tool |
infusion line | MPH Medical Devices | 2200045 | connecting line |