Magnetic resonance imaging (MRI) Infrared imaging (thermography) Magnetic resonance imaging Infrared imaging Ø The common feature of both imaging methods is the use of non-ionising radiation and the absence of genetic damage. Ø Magnetic resonance imaging (MRI) is one of the most advanced imaging methods which gives both morphological and physiological (functional) information. The first MR image (cross-section of chest) was obtained by R. Damadian in 1977. Ø Infrared imaging is a functional imaging method giving pictorial information on body surface temperature and thus level of metabolism. It is absolutely safe for the patient as the images are produced by IR radiation given out by the patient himself. First infrared cameras appeared in late 60‘ of 20th century. MRI Spin Ø Spin is a specific property of sub-atomic particles (electrons, protons etc) like electric charge and mass Ø Spin has some strange properties! – electrons, protons and neutrons all have the same spin i.e., 1/2 – pairs of particles of a single type (e.g., 2 electrons or 2 protons or 2 neutrons) can have a total spin of zero! – particles having non-zero total spin act like small magnets (we say they have a ‘magnetic moment’) and their energy is affected if placed in a magnetic field Total Nuclear Spin (I) Ø In MRI we are interested in the spin of NUCLEI Ø In medicine, we use the magnetic properties of mainly light nuclides like hydrogen ^1H, phosphorus ^31P, carbon ^13C, fluorine ^19F or sodium ^23Na to get anatomical or physiological information. MRI Theory Ø The magnetic moment m of a nucleus is proportional to its angular momentum S (m = g.S, g is the gyromagnetic ratio) which depends on I. Ø In the absence of an external magnetic field, the magnetic moments of nuclei have all possible (random) directions with the result that: – The vector sum of the nuclear magnetic moments in a unit volume of a substance, i.e. the magnetisation vector, is equal to zero – The energy of all nuclei is the same H Nuclei in a Uniform Magnetic Field B Ø When hydrogen nuclei are placed in an homogeneous strong magnetic field with magnetic flux density B: – Their individual magnetic moments will precess with an axis parallel to the direction of B and orientate themselves either in the same direction or in the opposite direction to B – Therefore they have only two possible energies (a higher and a lower energy state). – The angular frequency of rotation of this precession (i.e., number of revolutions per second) - is called the Larmor angular frequency w and is given by : w = g B g = gyromagnetic ratio The H dipoles in the body precess at 42.6 MHz/T Magnetisation Vector Measuring H Density in Tissues For nuclei in the lower energy state to move to the higher energy state RF pulses of frequency equal to the Larmor frequency must be transmitted towards the patient using a transmitter coil (hence the ‘resonance’ in MRI). When this occurs the nuclei are also forced to precess in phase. Longitudinal magnetisation vector becomes oriented in opposite direction Transverse magnetisation vector appears and rotates in plane xy. The return to the ground state (relaxation) is accompanied by the emission of a quantum of electromagnetic energy, which is when detected by an antenna (receiver coil) - the nuclear magnetic resonance (NMR) signal. The signal is relatively strong since the nuclei are precessing in phase. The amplitude of the pulse is proportional to the H density in the tissues (often known as ‘spin density’) . Relaxation times Ø We have two relaxation times: Ø T[1] - longitudinal - time necessary for return of the “population” of nuclei to the ground state. In biological media: 150 - 2000 ms. Longitudinal magnetisation vector returns to original direction during this time. T[2] - transversal - 2x - 10x shorter than T[1]. After this time interval the precession movement of individual nuclei is not in phase again. Transverse magnetisation vector disappears after this time. MRI - Magnetic Resonance Imaging. Ø To recognize signals from the different parts of the patient magnetic field gradients („gradual change“) are used e.g., a gradient of B along the z-axis allows us to identify signals coming from different slices of patient perpendicular to the z-axis. Ø The final image is produced using similar types of image generation processes as in CT. Ø We can visualise differences in local hydrogen density or differences in relaxation times. Technical aspects Ø Up to values B = 0.3 T we can use giant permanent magnets (cheap but low contrast resolution). Ø Electromagnets are stronger but need a lot of electric energy. Ø Best contrast resolution but also the highest operational costs is obtained with magnets having superconducting coil windings, which can produce fields of up to B = 10 T today, but must be cooled by liquid helium. Typical values of B used in practice are 1 – 3 T. Ø Gradients (about several mT.m^-1) of magnetic field are formed by additional coils. MR Contrast and MR Spectroscopy Ø Some paramagnetic atoms can amplify the signal. That is why e.g., gadolinium is used as a contrast agent for MRI. Gadolinium is chemically bound to certain pharmaceuticals e.g., DTPA - diethylen-triamin-penta-acetic acid. Ø The exact value of the Larmor frequency changes slightly (shifts) according to the position of the hydrogen in the molecules. For example, different shifts of H in groups =CH- or -CH[2]- are well measurable. This allows us to identify such groups using in-vivo MR - spectroscopy is a powerful tool with application in functional MRI (analysis of ATP content etc.) Safety aspects Ø The magnet can impair function of other medical devices. Hence MRI is strongly contraindicated in patients with some electronic devices inside their bodies (pacemakers, cochlear implants etc.) Ø Iron objects are strongly attracted to the “gantry” – they can damage the device and cause injuries. MRI is strongly contraindicated in patients with any iron bodies inside (implants, bullets, splinters of grenades etc.) Ø MRI is not recommended in the first trimester of pregnancy. Ø Some minor problems can be caused by any metals inside the body or on the body surface (heating, prickling sensations). For example: jewellery, some mascaras, old tattoos, tooth fillings, dental crowns and frameworks, implants etc.) Ø Some patients are anxious or unquiet inside the device gantry, because of strong noise during the examination. Claustrophobia is also common. Important Advice magnetic memories (e.g., credit cards) can be destroyed if taken into an MRI room MRI Devices „T2 weighted“ image of transversal section of head in the level of cochlea. (Siemens). MR - Angiogram http://www.cis.rit.edu/htbooks/mri/inside.htm Sagittal section of cervical spine Sagittal section of knee 3D model of curvature of left A. cerebri media (arrow) and M1 segment of the same artery (wedge) B) other view on this model shows also curvature of A. cerebri media (arrow shows a well visible aneurysm) These are not plastic models but the result of real MRI image processing! Thermography What is infrared imaging and infrared radiation? Ø The contact-less thermographic method is based on the measurement of infrared radiation (IR) emitted by the surface of the body. Ø Digital sensor technology is used for image recording. Ø Wavelength 780 nm - 1 mm Ø IR visualised first by Holst in 1934 Ø Discovered by astronomer Herschel in 1800 Ø The wavelength used in thermography 0.7 - 14 μm IR camera of Dept. Of Biophysics, Faculty of Medicine, MU, Brno Ø High temperature and spatial resolution Ø Temperature distribution is displayed in the form of isothermal lines - isotherms Ø Possibility to display temperature profiles Ø Fast measurement Clinical Importance of Thermography The method informs us about the extent and dynamics of any pathological process which is accompanied by increased temperature. Indications - Diseases of peripheral blood vessels - Diseases of thyroid - Diseases of lymphatic system - Joint inflammations - Demarcation of burns and frostbites - Assessment ob blood supply after reconstruction surgery... Clinical Thermograms Different palettes of colours (Fluke) Human face (Fluke) Thermogram of fingers before and after cold test (Fluke) Finger inflammation after a small injury (FLUKE Ti30) Varicosity of lower limbs (Fluke) Knee inflammation Oven leaking heat – checking heat devices Overheated cable Low quality insulation of a warm water piping in area of joints (Fluke) Ultrasonographic probe (Fluke) Thermal spot left by ultrasonographic probe on the forearm + cooling effect of the coupling gel (Fluke) Ultrasound therapy application head (Fluke)