Artificial Hearts

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Partial Support

BiVAD doesnt cover the entire CI range LVAD supports fully left ventricle but doesnt support RV -capable of replacing CI = 2.5-4 LVAD supports partially left ventricle: ex - Impella does not support all of left ventricular function - about 1/3, not meant for long term function

TAH Anatomical fit Summary

TAH anatomy and interfacing with cardiovascular system: true TAH vs BiVAD connection with and without native atria

Asynchronous Pacemaker

generates pulse internally: 70-90 bpm pulses may be generated by a free running oscillator or microcontroller constant voltages (5.5V) or constant current (8-10 mA 1-1.2 ms) pulse are used lithium iodide batter - high source resistance

Asynchronous Pacemakers

generates pulses at a fixed frequency problems: excitation may occur too soon causing fibrillation or tachycardia natural and artificial pacemaker should not compete solution = frequency is higher than natural heart frequency

Pacemakers

asynchronous synchronous rate responding

typical viscosity

at 37 degrees is 1.2 N*s/m^2

continous flow

blood is propelled by spinning rotor patients do not have pulse

TAH

bridge to transplantation only FDA approved device: SynCardia

Demand pacemakers

generator is set to a certain frequency- typically 60-80 Hz after each pulse the generator resets itself and waits for certain periods of time to pass or for the QRS pulse if QRS is not detected, the the generator sends a pulse if QRS is detected, the generator is reset and the cycle begins again

Animal Studies

geometry of the device has to be altered to fit the animal model animal id monitored 24/7 blood analysis (every hour) looking for oxygenation, blood damage, kidney function etc blood pressure waveform is recorded (resting vs walking)

problems with animal studies

geometry/anatomy different blood properties calcification of membranes and valves thrombosis growth animals are healthy before implantation thus do not emulate the real clinical situation

Congestive heart failure

heart is unable to pump enough blood to deliver nutrients to the body around 6.5 million people live with CHF and 960,000 new cases annually projected to increase to 8 million by 2030

Axial Flow Pump - LVAD

heartmate II more common flow path comes straight through pump apex to aorta configuration

shear stress rate too high

hemolysis - red blood cells split

Advantages of TAH over BiVAD

higher survival rate patients undergoing long term support tended to have improved survival when supported under TAH - lower incidence of neurological events long length of mechanical support lower incidence of stroke or reoperation more successful in bridging patients to transplants

Blood Compatibility- physiological context

human body can remove around 20 g of free hemoglobin per day - 14g (12 mg/dL/hg) by renal clearance 6g (5 mg/dL/hg) by reticuloendothelial

Synchronous Pacemaker

ideally we should have intermittent cardiac pacing (for people who can establish normal rhythm between periods of block two types: demand pacemakers atrial synchronous pacemakers

Type of Errors

if the sample indicates that the mean is greater in the device treated group than in the controls (thus rejecting the null hypothesis) when in population there is no difference between means) a Type I error, also called alpha error, is made if the sample indicates no difference between means (accepting null hypothesis) when the device mean is actually greater, then Type II error is made

Advantages of TAH

immediately available at SynCardia centers patients recover rapidly up to 9.5 L/min through both ventricles 79% bridge to transplant eliminates complications cause by a failing heart patient's body automatically adjust blood flow reliability second to none hospital reimbursement

Freedom Portable Driver

investigational device, limited by US law to investigational use

heart disease

leading cause of death in the Us 1 in 7 deaths growing problem gobally

Anatomical fit

limited space in thoracic cavity limited availability to connect to exist vasculature

Tissue Compatibility

material mechanical anchoring contact pressure inside chamber: allow fibrous tissue, endothelial cell formation, binds to fibrous layer sometimes inner surface of the blood chamber is porous - HeartMate II outside: integrates with surrounding tissue, down not cause voltage bridges, inflammation, thermal burns

Full Support Requirements

max flow rate of 8-10 L/min max pressure 300 mmHg max ejection volume 70-80 mL

Body Surface Area

measures how well blood is flowing BSA= ((W*H)^1/2)/6 or BSA = ((W*H)/36)^1/2 W= kg H = m

LVAD Types

INCOR (intracorporeal)- inside human body EXCOR (extracorporeal)- outside human body

Non Invasive LVAD

Impela 2.5 non invasive axial pump LVAD

Mechanical Cadiovascular Orthotic Devices

Intra Aortic balloon Pump Left Ventricle Assist Device (LVAD) Bi-ventricular Assist Device Artificial heart

Cardiac Index

L/min/m^2 CI = CO/BSA or CI = SV*HR/BSA co= cardiac outpute L/min HR = heart rate bpm SV = stroke volume, L

LVAD Anatomical Fit Summary

Main types of devices: Axial Flow Centrifugal Pump LVAD anatomy and interfacing with cardiovascular system: atrium to aorta ventricular apex to aorta ventricular apex to abdominal aorta alternative connection to the left atrium and aorta Trend towards miniaturization of pumps for better anatomical fit

Right atrial pressure

0-7 mmHg pressure in atrium before flowing to ventricle

heart frequency

1-2 Hz

Maximal physiological stress

10 N/m^2 above 40 N/m^2 endothelial cells can be damaged

Pulmonary Arterial Pressure

15-39/8-14 mmHg

Cardiac Index

2.5-4 L/min/m^2

Mean flow of circulatory system

3-5 L/min

Left atrial pressure

4-12 mmHg

Normal shear stress

8-12 dynes/cm^2

Systemic Arterial Pressure

90-140/60-90

Cardiac Output

CO = MAP - MRAP/SVR or SV*HR MAP = mean arterial pressure MRAP = mean right atrial pressure SVR = systemic vascular resistance

Animal Models

Calves (TAH) - anatomical fitting, physiological testing Sheep(LVAD) - similar pulmonary vasculature Pigs (LVAD) - blood is closer match to humans Rats (LVAD)- ventricle loading and unloading LVAD procedure

Continous Flow LVADs

Centrifugal pump Does not have inflow tube Fits in chest cavity apex to aorta configuration

Clinical Trials

Control Groups: pharmacological therapy for CHF, do not receive the blood pump more common to have a new blood pump tested for efficacy and "non inferiority" another device in clinical trial a new blood pump is "non inferior" to an existing blood pump based on clinical data and patient outcomes For LVAD, the control device is heartmate II For TAH, the control device is Syncardia

In Vivo testing: Thrombus Formation

Danger of Stagnant Flow - thrombus formation

Newborn Oyxgenators

ECMO - Extracorporeal Membran Oxygenation

The Future of TAH

France CARMAT - sent to begin clinical trials in 2018 would rival the SynCardia

Humanitarian Device Exemption

HDE will allow up to 4,000 US patients annually who are not transplant eligible to receive the TAH on a permanent basis currently, these patients have no other options for long term survival and are often referred to hospice

Hemolysis Rate index

HRI =ΔHb*V*(100-Ht)/ T]

TAH Function Summary

Max flow rates Max pressure CI range Hydraulic Power

Normal Index of Hemolysis

NIH = = [ΔHb *V * (100- Ht)] / [(Q*T)/100] Hb = increase in free hemoglobin concentration (g/l) v = total blood volume (L) Q = flow rate (L/min) Ht = hematocrit in % T = duration of test

Null Hypothesis

No difference between untreated (control group) and treated group

Problem with Mechanical Support

No factor of safety for TAH microthrombo embolism hemolysis neurological problems infection pulmonary hypertensions acquired von Willebrand disease: deficieny of von Willebrand Factor - multimeric protein that is required for platelet adhesion result = bleeding

Power equation

P = flow * pressure

Pulmonary Vascular Resistance

PVR 2.8-3.9 mmHg/Lmin

LVAD- HeartMate II

Parts of LVAD: batteries controller pump must be placed on outside of body - easy to replace batteries, LI toxicity

Materials

Polyurethane- housing, membrane titanium - housing stainless steel - housing tygon medical/surgical - tubing Gore- tex

Right Side of heart

Pulmonary circulation

Stroke Volume

SV = EDV- ESV EDV = end diastolic volume ESV = end systolic volume

Systemic Vascular Resistance

SVR 24.6-29.8 mmHg/Lmin

Flow/ Pressure testing - Input Impedance

Zi = P/Q

Blood Pump Mechanical Power

around 1 W

Important Design Issues

anatomical fit physiological modelling blood compatibility tissue compatibility bench top testing Animal Testing Human Clinical Trials

Heartmate II LVAD

battery worn externally

Effects of Increased Hemoglobin

can cause endothelial cell dysfunction, vasomotor instability by reducing nitric oxide bioavailability, increased blood pressure, renal damage, and activation of platelets

Guaranteed treatment for end stage CHF

cardiac recovery is impossible limited supply of biological donor hearts lengthy wait time for donor heart

goals fo animal studies

device implantability an doperability show long term survival - more than 3 months demonstrate the blood pump's ability to sustain life and physiological function: animal survives in good health good arterial pressure, no pulmonary hypertension no indicators of bleeding or other complications good CO2 and O2, pH 7.38-7.41 Prove hemocompatibility: show low hemolysis show no thrombus formation inside blood pump and valves no thrombo-embolism in the brain, lungs Show adequate blood flow support (physiological CI) Show adequate perfusion (blood gases and post mortem)

Aortic Input Impedance for children vs adults

difference between age and vessel compliance with modulus of elasticity children's aortas are stretchier because they are still growing

pulsatile

either pneumatic or electromechanical flexible membrane or pusher plate with one way valves blood is sucked into chamber then expelled

TAH Physiological Responsive Desing

elastic membrane permits addition distension for changes in volume preload and after load as results of atrial pressures and changes to SVR and PVR

Types of Oxygenator Pumps

film type - large rotating disc in direct contact with 100% oxygen membrane oxygenator

Why resistance (SVR and PVR) is not enough to stimulate circulatory system

flow and pressure are not in phase with one another. each frequency the phase difference and amplitude ratios are different

LVAD function Summary

full support partial suport pulsatile vs non pulsatile

Physiological Function

full support (heart replacement, BiVAD, LVAD) partial support (LVAD) pulsatile or non pulsatile short term (days/weeks) long term (months) permanent

Pump Oxygenators

open heart surgery sometimes requires the heart is stopped O2 and CO2 exchange must occur elsewhere pump oxygenators provide mechanical pump and deliver oxygen to the blood stream as well as remove CO2 from vena cava to femoral artery right atrium to femoral artery femoral vein to femoral artery if oxygenator must be kept away from the heart

Pacemakers and Simulators

pacemaker: low current duty cycle stimulators defibrillators: high current single pulse mechanical cardiovascular orthotic devices

Pulsatile vs Non Pulsatile

partial pulsatile support needs to by synchronized with EKG usually synchronization assures that LVAD ejects blood when aortic valve is closed non pulsatile strategies can vary non pulsatile vs pulsatile debate: is pulsatile necessary? more prone to failure

Flow Studies

particle image velocity particle visualization surface washout - dye on surface stagnation area - dye in the volume valve flow - presence of jets, turbulence

Intra Aortic Balloon Pump

placed in descending aorta inflated during diastole when aortic valve opens, balloon is deflated deflation of the balloon decreases pressure seen by the heart, balloon generates region of lower pressure to which blood can easily be moved by weakened heart blood pressure waveform counter pulsation every other heart cycle the balloon is activated

electrodes

platinum alloys platinum with stainless steel, carbon, titanium elgiloy: cobalt chromium, iron, nicke, molybendum, manganese and traces of other metals

Pump Types

pulsatile continous flow pumps

TAH Anatomical Fit

pump inlets are mounted/integrated with left and right atria all heart valves and ventricles replaced outputs connect directly to the pulmonary artery and aorta via artificial valves pneumatic lines penetrate diaphragm

BiVAD Summary

pumps takes blood from left and right atrium ejects blood into aorta and pulmonary artery pulsatile VAD - blood pump stays outside of the human body

Wind Kessel Theory

rate of flow in aorta = rate of change of volume of elastic chamber + rate of flow into rigid tube windkessel theory describes flow pressure relationship in big arteries (aorta) only viable for large vessels, not the entire system

Atrium/ Inlet Variant 2

ventricles are removed as well as part of the atria and vessels ex: BiVAD - Berlin heart

Atrium/Inlet variant 1

remove ventricles and the valves leaving the pulmonary artery and aorta in tact Quick connects are sewn in and the TAH is replaces ex: SynCardia TAH

Problems with Human Studies

researcher bias patient bias control groups (ethical issues)- do not receive blood pump FDA allows TAH/LVAD experiments only with patients who are very sick - compassionate use

Types of Pumps

roller pump multiple finger pumps pulsatile pumps centrifugal pumps

Testing synthetic heart for blood compatibility

shear rate studies hemolysis- NIH, in vitro, in vivo thrombus formation - in vivo

Pre Market Studies ( Human Studies)

show safety and efficacy

Left side of heart

systemic circulation

shear stress rate too low

thrombus formation - blood clot hemolysis causes coagulation cascade which can cause clotting

Heartmate II thrombosis

thrombus formation was reported at the regions of the rear impeller hub and the entry of the impeller blades thrombus extended along the flow straightener blades

Purpose of blood circulation

transport and distribute oxygen and nutrients to tissue and remove by products

Types of BiVAD- berlin heart configurations

types: Left atrium to aorta configuration Left ventricle to aorta configuration installed outside the body for easy access to fix

Pharmacological therapy for CHF

use drugs to mitigate symptoms slows the onset

Numerical Modeling

use software to design and optimize the VAD/TAH prior to physical testing experiments speeds up the design process and reduces development costs prediction can be made regarding the overall pump performance - hydraulic performance, power usage some design question can only be answered through numerical modeling: fluid streamlines to predict flow path predictions of shear stress blood damage potential prediction of forces of the impeller or diaphragm predictions of thermal effects

Lead Wires

used to be most problematic part of device - 20% chance of failure in 10 years mechanically robust: helical coils, multiple stands well insulated: highly compliant silicone rubber or polyurethane as insulator unipolar: one electrode (negative) on the heart, second electrode away from heart bipolar: two electrodes within the heart placed against the inside surface of the heart

Controls blood flow in heart

valves

TAH surgical implantation

ventricles and valves are removed leaving pulmonary artery and aorta intact atria are preserved quick connects are sewn in and the TAH is attached

Post Market Studies (Human Studies)

with growing number of case studies safety can be better understood (rare cases of adverse effects will start showing up with larger n)


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