ARTIFICIAL
HEART WORKING MECHANISM
The Heart
A natural human heart has four chambers – two atria and two ventricles.
A natural human heart has four chambers – two atria and two ventricles.
The right atrium collects blood and the right ventricle
then pumps it to the lungs where it is oxygenated. The blood is then picked up
by the left atrium and distributed around the body and brain by the left
ventricle. Each side of the heart has a pair of valves – one pair per lung –
controlling the flow of blood.
Artificial hearts can now completely, if temporarily, replace the ventricles and valves with a device made of plastic or other man-made materials, which does the job of pumping blood around.
The type of artificial heart that was given to Green, made by Syncardia Systems, works by using a pump carried externally in a backpack – previously, patients would have to be connected to a large, immobile pump and would not have the freedom to move around.
The tubes connecting the heart to the pump “send pulses of air into two expandable, balloon-like sacs in the artificial ventricles, forcing out blood in much the same way that a beating heart would”.
Other models such as that produced by AbioMed use an internal pump and battery, which can be charged via transcutaneous energy transmission – a method of transferring power under the skin without having to penetrate it, thereby decreasing the chance of infection.
Artificial hearts can now completely, if temporarily, replace the ventricles and valves with a device made of plastic or other man-made materials, which does the job of pumping blood around.
The type of artificial heart that was given to Green, made by Syncardia Systems, works by using a pump carried externally in a backpack – previously, patients would have to be connected to a large, immobile pump and would not have the freedom to move around.
The tubes connecting the heart to the pump “send pulses of air into two expandable, balloon-like sacs in the artificial ventricles, forcing out blood in much the same way that a beating heart would”.
Other models such as that produced by AbioMed use an internal pump and battery, which can be charged via transcutaneous energy transmission – a method of transferring power under the skin without having to penetrate it, thereby decreasing the chance of infection.
The physics
Energy transmission
In the artificial hearts produced by AbioMed, an electronics package is implanted in the abdomen of the recipient of the transplant to monitor and control the pumping of the heart.
In the artificial hearts produced by AbioMed, an electronics package is implanted in the abdomen of the recipient of the transplant to monitor and control the pumping of the heart.
Power is supplied from an external source to components
under the skin, without penetrating it, using inductive electromagnetic
coupling – the same principle as used by transformers to transfer electricity
between different circuits, as in the national grid.
At their simplest, systems of transcutaneous energy
transmission will use an external power supply connected to an external coil of
wire, generating a magnetic field in it. This, in turn, produces an induced
voltage in a second coil implanted under the skin, and a rectifier is used to
change this alternating current into direct current that can be used to power
the electronics of the heart and its controller.
Though simple in theory, in practice there are
complications that arise from the need to keep the two coils aligned correctly
as the patient moves, in delivering the correct level of power so that there is
no excess dissipated as heat to potentially damage surrounding tissue in the
patient’s body, and in making the components small enough to be carried around
without too much discomfort.
Monitoring blood flow
A replacement heart needs to be able to monitor the flow of blood to regulate its pumping and ensure that the correct amount of blood is delivered around the body.
Quicker pumping is required when the transplant recipient
is more active, whereas the opposite is true while he or she is resting.
Blood-flow monitors make use of ultrasound – they bounce
high-frequency sound waves off blood cells coming out of the heart, the volume
and speed can be measured using similar basic principles to those behind radar..
Ultrasound is used because it can monitor the flow of
blood without having to be in contact with it.
Appropriate materials
Artificial hearts need to be made of light but durable materials – the Syncardia version is plastic whereas that made by AbioMed is a combination of titanium and a specially developed polyurethane, called ‘Angioflex’.
Appropriate materials
Artificial hearts need to be made of light but durable materials – the Syncardia version is plastic whereas that made by AbioMed is a combination of titanium and a specially developed polyurethane, called ‘Angioflex’.
Although the Abiomed heart is designed to have as few
moving parts as possible, those that it does have are made from Angioflex and
are tested to ensure that they are safe for contact with blood and capable of
withstanding beating 100 000 times a day for years on end.
Materials scientists can develop substances with specific
properties by manipulating the constituent elements and the way in which they
are processed. Materials are characterised using various techniques from
condensed-matter physics including electron microscopy, x-ray diffraction and neutron
diffraction.
Because they were still quite large, the first devices
produced were limited to around half the male population – those with the
largest chest cavities. A newer, smaller, model is intended to extend their
availability to smaller people.
An artificial heart being produced by the French medical
company Carmat and expected to be available by 2013 will use chemically treated
animal tissue to help avoid rejection by the host’s immune system. Aerospace
engineers from Airbus were also involved in its development.
Artificial hearts combine, and improve upon, many existing physics ideas to produce a piece of technology that saves lives – although they are currently only approved as a stopgap until a donor heart can be found.
Artificial hearts combine, and improve upon, many existing physics ideas to produce a piece of technology that saves lives – although they are currently only approved as a stopgap until a donor heart can be found.
By: Mehuli Das
0 Comments