Yuriy Yuriy Zorenko Zorenko *Electronic Department, Ivan Franko National University of Lviv, Ukraine ** Institute of Physics, Jan Dlugosz University in Czestochowa, Poland 1. Modern Materials Engineering. 2. Luminescent Materials in Medicine and Protection of Health Ultrasound and ultrasound material Ultrasound and ultrasound material in medicine in medicine
50
Embed
Ultrasound and ultrasound material in medicine · Yuriy Zorenko *Electronic Department, Ivan Franko National University of Lviv, Ukraine ** Institute of Physics, Jan Dlugosz University
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
YuriyYuriy ZorenkoZorenko*Electronic Department, Ivan Franko National University of
Lviv, Ukraine** Institute of Physics, Jan Dlugosz University in
Czestochowa, Poland
1. Modern Materials Engineering.2. Luminescent Materials in Medicine and Protection of Health
Ultrasound and ultrasound materialUltrasound and ultrasound materialin medicinein medicine
Milestone of electronic materials in medicine and protection ofMilestone of electronic materials in medicine and protection of healthhealth
Sender /receiver
Reflected wave
Object
Original wave
20 Hz-20 KHz
1MHz-18 MHz
UltrasoundUltrasound PhysicsPhysics
Diagnostic Ultrasound X-or γ- rays radiology
wave type longitudinal mechanical waves electromagnetic wavestransmissionrequirements elastic medium no medium
generation stressing the medium accelerating electriccharges
velocity depends on the mediumthrough which it propagates
3. 3. VelocityVelocity ofof ssoundound in mediain media c c (m/s)(m/s)4. 4. ImpedanceImpedance Z = pZ = pc (c (ρρ--density of mediadensity of media))
Ultrasound and animals
Bats (nietoperzy) use ultrasounds to move in the darkness. Bats use a varietyof ultrasonic techniques (echolocation) to detect their prey. They can detectfrequencies up to 100 kHz.
Ideal case is the reflection of 1 % part of ulrasound wave ( R=0,01)
is smallAbsence ofreflection
Totalreflection
Is large
Water
Bone
Air
Muscle
Water
UUltrasonographyltrasonography is widely used in medicine. It is possible to perform bothdiagnosis and therapeutictherapeutic proceduresprocedures, using ultrasound to guide interventionalprocedures (for instance biopsies or drainage of fluid collections).
UUltrasonographyltrasonography typically use a hand-held probe (called a transducer(transduktor) that is placed and moved directly on body of the patient.
The choice of frequency is a compromize between spatialspatial resolutionresolution of the imageand imagingimaging depthdepth: lower frequencies produce lessless resolutionresolution butbut imageimage deeperdeeperinto the body.
Typical diagnostic sonographic scanners operate in the of 11--18 18 MhzMhz range.5050--100100 MHzMHz has been used in a technique known as biomicroscopybiomicroscopy in specialregions, e.g. like the anterior chamber of eye.
Sonography is effective for imaging soft tissues of the body. Superficialstructures such as muscles, tendons, testes, breast and the neonatal brain areimaged at a higher frequency of 7-18 MHz, which provides better axial and lateralresolution.
Deeper structures such as liver and kidney are imaged at a lower frequency 1-6 MHz with lower axial and lateral resolution but greater penetration.
3.0 1.1 mm 2.8 mm 35.9 %4.0 0.8 mm 1.5 mm 60.9 %5.0 0.6 mm 1.2 mm 77.8 %7.5 0.4 mm 1.0 mm 100 %10.0 0.3 mm 1.0 mm 107.7 %
Modes of sonographySeveral different modes of ultrasound areused in medical imaging:
AA--modemode: A-mode is the simplest type ofultrasound. A single transducer scans a line through the body with the echoesplotted on screen as a function of depth.Used mainly for therapy.
BB--modemode: A linearlinear arrayarray ofof transducerstransducerssimultaneously scans a plane through thebody that can be viewed as a two-dimensional image on screen.
MM--modemode: A rapid sequence of B-modescans whose images follow each other insequence on screen enables to see andmeasure range of motion, as the organboundaries that produce reflections moverelative to the probe.
f1 – frequency of fall wavef2 – frequency of reflected waveC- velocity of sound in mediaν – velocity of object
DopplerDoppler modemode: This mode used of the Doppler effect in measuring andvisualizing bloodblood flowflow
ColorColor dopplerdoppler: Velocity information is presented as a color coded overlay on topof a B-mode image
PulsedPulsed wavewave (PW) (PW) dopplerdoppler: Doppler information is sampled from only a smallsample volume (defined in 2D image), and presented on a time
DuplexDuplex:: a common name for the simultaneous presentation of 2D and (usually) PW doppler information.
UltrasoundUltrasound examinationsexaminations can help to diagnose a variety of conditions and toassess organ damage following illness. Ultrasound is used to help evaluate symptoms such as:
Ultrasound is also used to:• scrotum (moszna)• guide procedures such as needle biopsies, in which needles areused to extract sample cells from an abnormal area for laboratorytesting. • image the breasts (pierśi) and to guide biopsy of breast cancer• diagnose a variety of heart conditions and to assess damage aftera heart attack or diagnose for valvular heart disease. Doppler ultrasound images can help the physician to see andevaluate:• blockages to blood flow (such as clots). • narrowing of vessels• tumors (guzy) and congenital malformation.With knowledge about the speed and volume of blood flow gainedfrom a Doppler ultrasound image, the physician can often determinewhether a patient is a good candidate for a procedure likeangioplasty.
Special application of ultrasoundSpecial application of ultrasound
Best linear scanner is complet in form of array of from crystals (~400 St.)
body
scan-line principles of linear array
sound beam
SonderSonder ((TransducersTransducers))Piezoelectric materials are used in electromechanical devices. In the case of amicrophone transducer, sound of a particular frequency results in a strain in thematerial, which in turn induces an electric field. Similarly in speakers, a voltage input into the piezoelectric material can beconverted into a mechanical strain, such as in a speaker transducer.
Construction of Sonder.Dynamics focusing in separate Matrix-Array
Linear Array Transducer
Construction of SonderLayer thickness is the key of scanning system
Ultrasonic testing is a type of nondestructive testing commonly used to find flawsin materials and to measure the thickness of objects. Frequencies of 2 to 10 MHzare common but for special purposes other frequencies are used. Inspection maybe manual or automated and is an essential part of modern manufacturingprocesses. Most metals can be inspected as well as plastics and aerospacecomposites. Lower frequency ultrasound (50–500 kHz) can also be used toinspect less dense materials such as wood, concrete (beton) and cement.
Ultrasonic Ultrasonic cleanerscleaners, sometimes mistakenly called supersonic cleaners, are usedat frequencies from 20 20 toto 40 40 kHzkHz for jewellery, lenses and other optical parts, watches, dental instruments, surgical instruments, diving regulators andindustrial parts. An ultrasonic cleaner works mostly by energy released from thecollapse of millions of microscopic cavitations near the dirty surface. The bubblesmade by cavitation collapse forming tiny jets directed at the surface.
Ultrasound Identification (USID)
Ultrasound Identification (USID) is a Real Time Locating System (RTLS) or IndoorPositioning System (IPS) technology used to automatically track and identify thelocation of objects in real time using simple, inexpensive nodes (badges/tags) attached to or embedded in objects and devices, which then transmit anultrasound signal to communicate their location to microphone sensors
Piezoelectricity – invention in 1880 by brothers Curie.Piezoelectricity is the ability of some materials (crystals and certain ceramics)
to generate an electrical potential in response to applied mechanical sress.
The piezoelectric effect is reversible. The materials exhibiting the directdirectpiezoelectricpiezoelectric effecteffect (the production of electricity when stress is applied) alsoexhibit the converseconverse piezoelectricpiezoelectric effecteffect (the production of stress when anelectric field is applied - electromechanical effectelectromechanical effect).
+A pushing force: compression A pulling force: tension
+
-
-
+
+
-
+
-
The unit cell of crystal silicon dioxide
Si
O
Polarization
-
+
+
-
+
-
+
-
The Piezoelectric Effect
Crystal
Current Meter= 0
+ - + - + -
+ - + - + -Charges canceleach other, sono current flow
Crystal material at rest: No forces applied, so the current flow is 0
The Piezoelectric Effect
Crystal
Current Meterdeflects in + direction
- - - - -
+ + + + +
Crystal material with forces applied in direction of arrows………..
Due to properties of symmetry,charges are net + on one side & net - on the opposite side: crystal gets thinner and longer
Force
-
+
+
-
+
-
+
-
The Piezoelectric Effect
Crystal
Current Meterdeflects in -direction
+ + + +
- - - - -
…. Changes the direction of current flow, and the crystal getsshorter and fatter.
Changing the direction of theapplied force………..
Force
-
+
+
-
+
-
Electromechanical nature Electromechanical nature of piezoelectric materialof piezoelectric material
• In general, if you deform a piezocrystal by applying a force, you will get charge separation: Think of a simple battery.
• Taking it one step further, what would happen to the crystal if you applied an electrical force that results in the exact same current flow from the proceeding circuit?
The electromechanical effectThe electromechanical effect
Crystal
…. With the switch open, the crystal material is now at rest again:the positive charges cancel the negative charges.
Now, replace the current meter with a power source capableof supplying the same current indicated by the meter….
+ - + - + -
+ - + - + -
switch
power sourcecharges cancel
The electromechanical effect
Crystal
…. and, the crystal should get shorter and fatter.
When the switch is closed, and you apply the exact amount of power to get the same current that resulted when you squeezedthe crystal, the crystal should deform by the same amount!!
power source(battery)
- side
+ side+ + + +
- - - - -
The electromechanical effect
Crystal
…. the crystal should get longer and skinnier.
What will happen if you switched the battery around??
power source(battery)
+ side
- side- - - - -
+ + + + +
Summary of the Summary of the Piezoelectric & Electromechanical EffectPiezoelectric & Electromechanical Effect
• A deformation of the crystal structure (eg: squeezing it) will result in an electrical current.
• Changing the direction of deformation (eg: pulling it) will reverse the direction of the current.
• If the crystal structure is placed into an electrical field, it will deform by an amount proportional to the strength of the field.
• If the same structure is placed into an electrical field with the direction of the field reversed, the deformation will be opposite.
Piezoelectric materialsPiezoelectric materials
dd-- piezoelectricpiezoelectric constantconstant of materials of materials -- inducedinduced strainstrain // unitunit electricelectric fieldfield appliedapplied;;k k -- electromechanicalelectromechanical couplingcoupling factorfactor - mechanical energy converted / electricenergy input
Piezoelectric materials with a perovskite structure exists in two crystallographicforms. Below the Curie temperature they have a tetragonal structure. In the tetragonalstate, each unit cell has an electric dipole, i.e. there is a small charge differentialbetween each end of the unit cell.
Above the Curie temperature they transform into a cubic structure.
A mechanical deformation (such as a compressive force) can decrease theseparation between the cations and anions which produces an internal field orvoltage.