Perfusion scanning

Perfusion is defined as the passage of fluid through the lymphatic system or blood vessels to an organ or a tissue.[1] The practice of perfusion scanning, is the process by which this perfusion can be observed, recorded and quantified. The term perfusion scanning encompasses a wide range of medical imaging modalities.

Applications

Being able to observe and quantify perfusion in the human body has been an invaluable step forward in medicine. With the ability to ascertain data on the blood flow to vital organs such as the heart and the brain, doctors are able to make quicker and more accurate choices on treatment for patients. Nuclear medicine has been leading perfusion scanning for some time, although the modality has certain pitfalls. It is often dubbed 'unclear medicine' as the scans produced may appear to the untrained eye as just fluffy and irregular patterns. More recent developments in CT and MRI have meant clearer images and solid data, such as graphs depicting blood flow, and blood volume charted over a fixed period of time.

Methods

Microsphere Perfusion

Using radioactive microspheres is an older method of measuring perfusion than the more recent imaging techniques. This process involves labeling microspheres with radioactive isotopes and injecting these into the test subject. Perfusion measurements are taken by comparing the radioactivity of selected regions within the body to radioactivity of blood samples withdrawn at the time of microsphere injection.[2]

Later, techniques were developed to substitute radioactively labeled microspheres for fluorescent microspheres.[3]

CT Perfusion

The method by which perfusion to an organ measured by CT is still a relatively new concept, although the original framework and principles were concretely laid out as early as 1980 by Leon Axel at University of California San Francisco.[4] It is most commonly carried out for neuroimaging using dynamic sequential scanning of a pre-selected region of the brain during the injection of a bolus of iodinated contrast material as it travels through the vasculature. Various mathematical models can then be used to process the raw temporal data to ascertain quantitative information such as rate of cerebral blood flow (CBF) following an ischemic stroke or aneurysmal subarachnoid hemorrhage. Practical CT perfusion as performed on modern CT scanners was first described by Ken Miles, Mike Hayball and Adrian Dixon from Cambridge UK [5] and subsequently developed by many individuals including Matthias Koenig and Ernst Klotz in Germany,[6] and later by Max Wintermark in Switzerland and Ting-Yim Lee in Ontario, Canada.[7]

MR Perfusion

There are different techniques of detecting perfusion parameters with the use of MRI, the most common being dynamic susceptibility contrast imaging (DSC-MRI) and arterial spin labelling (ASL). In DSC-MRI, Gadolinium contrast agent is injected and a time series of fast T2*-weighted images is acquired. As Gadolinium passes through the tissues, it produces a reduction of T2* intensity depending on the local concentration. The acquired data are then postprocessed to obtain perfusion maps with different parameters, such as BV (blood volume), BF (blood flow), MTT (mean transit time) and TTP (time to peak).

NM Perfusion

Nuclear medicine uses radioactive isotopes for the diagnosis and treatment of patients. Whereas radiology provides data mostly on structure, nuclear medicine provides complementary information about function.[8] All nuclear medicine scans give information to the referrering clinician on the function of the system they are imaging.

Specific techniques used are generally either of the following:

Uses of NM perfusion scanning include Ventilation/perfusion scans of lungs, myocardial perfusion imaging and functional brain imaging.

Ventilation/perfusion scans

Ventilation/perfusion scans, sometimes called a VQ (V=Ventilation, Q=perfusion) scan, is a way of identifying mismatched areas of blood and air supply to the lungs. It is primarily used to detect a pulmonary embolus.

The perfusion part of the study uses a radioisotope tagged to the blood which shows where in the lungs the blood is perfusing. If the scan shows up any area missing a supply on the scans this means there is a blockage which is not allowing the blood to perfuse that part of the organ.

Myocardial perfusion imaging

Myocardial perfusion imaging (MPI) is a form of functional cardiac imaging, used for the diagnosis of ischemic heart disease. The underlying principle is that under conditions of stress, diseased myocardium receives less blood flow than normal myocardium. MPI is one of several types of cardiac stress test.

A cardiac specific radiopharmaceutical is administered. E.g. 99mTc-tetrofosmin (Myoview, GE healthcare), 99mTc-sestamibi (Cardiolite, Bristol-Myers Squibb now Lantheus Medical Imaging). Following this, the heart rate is raised to induce myocardial stress, either by exercise or pharmacologically with adenosine, dobutamine or dipyridamole (aminophylline can be used to reverse the effects of dipyridamole).

SPECT imaging performed after stress reveals the distribution of the radiopharmaceutical, and therefore the relative blood flow to the different regions of the myocardium. Diagnosis is made by comparing stress images to a further set of images obtained at rest. As the radionuclide redistributes slowly, it is not usually possible to perform both sets of images on the same day, hence a second attendance is required 1–7 days later (although, with a Tl-201 myocardial perfusion study with dipyridamole, rest images can be acquired as little as two-hours post stress). However, if stress imaging is normal, it is unnecessary to perform rest imaging, as it too will be normal – thus stress imaging is normally performed first.

MPI has been demonstrated to have an overall accuracy of about 83% (sensitivity: 85%; specificity: 72%) , and is comparable (or better) than other non-invasive tests for ischemic heart disease, including stress echocardiography.

Functional brain imaging

Usually the gamma-emitting tracer used in functional brain imaging is technetium (99mTc) exametazime (99mTc-HMPAO, hexamethylpropylene amine oxime). Technetium-99m (99mTc) is a metastable nuclear isomer which emits gamma rays which can be detected by a gamma camera. When it is attached to exametazime, this allows 99mTc to be taken up by brain tissue in a manner proportial to brain blood flow, in turn allowing brain blood flow to be assessed with the nuclear gamma camera.

Because blood flow in the brain is tightly coupled to local brain metabolism and energy use, 99mTc-exametazime (as well as the similar 99mTc-EC tracer) is used to assess brain metabolism regionally, in an attempt to diagnose and differentiate the different causal pathologies of dementia. Meta analysis of many reported studies suggests that SPECT with this tracer is about 74% sensitive at diagnosing Alzheimer's disease, vs. 81% sensitivity for clinical exam (mental testing, etc.). More recent studies have shown accuracy of SPECT in Alzheimer diagnosis as high as 88%.[9] In meta analysis, SPECT was superior to clinical exam and clinical criteria (91% vs. 70%) in being able to differentiate Alzheimer's disease from vascular dementias.[10] This latter ability relates to SPECT's imaging of local metabolism of the brain, in which the patchy loss of cortical metabolism seen in multiple strokes differs clearly from the more even or "smooth" loss of non-occipital cortical brain function typical of Alzheimer's disease.

99mTc-exametazime SPECT scanning competes with fludeoxyglucose (FDG) PET scanning of the brain, which works to assess regional brain glucose metabolism, to provide very similar information about local brain damage from many processes. SPECT is more widely available, however, for the basic reason that the radioisotope generation technology is longer-lasting and far less expensive in SPECT, and the gamma scanning equipment is less expensive as well. The reason for this is that 99mTc is extracted from relatively simple technetium-99m generators which are delivered to hospitals and scanning centers weekly, to supply fresh radioisotope, whereas FDG PET relies on FDG which must be made in an expensive medical cyclotron and "hot-lab" (automated chemistry lab for radiopharmaceutical manufacture), then must be delivered directly to scanning sites, with delivery-fraction for each trip handicapped by its natural short 110 minute half-life.

Testicular torsion detection

Radionuclide scanning of the scrotum is the most accurate imaging technique to diagnose testicular torsion, but it is not routinely available.[11] The agent of choice for this purpose is technetium-99m pertechnetate.[12] Initially it provides a radionuclide angiogram, followed by a static image after the radionuclide has perfused the tissue. In the healthy patient, initial images show symmetric flow to the testes, and delayed images show uniformly symmetric activity.[12]

See also

References

  1. American Psychological Association (APA): perfusion. (n.d.). Dictionary.com Unabridged (v 1.1). Retrieved March 20, 2008, from Dictionary.com website: http://dictionary.reference.com/browse/perfusion
  2. Studies of the Circulation with Radioactive Microspheres., Wagner et al,Invest. Radiol., 1969. 4(6): p. 374-386.
  3. "Fluorescent Microspheres" (PDF). Fluorescent Microsphere Resource Center.
  4. L. Axel. Cerebral blood flow determination by rapid-sequence computed-tomography: theoretical analysis. Radiology 137: 679-686, December 1980
  5. K.A. Miles, M. Hayball, A.K. Dixon. Colour perfusion imaging: a new application of computed tomography. Lancet. 337(8742):643-5. Mar 1991
  6. M. Koenig, E. Klotz, B. Luka, D.J. Venderink, J.F. Spittler, L. Heuser. Perfusion CT of the brain: diagnostic approach for early detection of ischemic stroke. Radiology 209(1):85-93, October 1998
  7. A.A. Konstas, G.V. Goldmakher, T.-Y. Lee, and M.H. Lev. Theoretical basis and technical implementations of CT Perfusion in acute ischemic stroke, Part 2: Technical Implementations. AJNR American Journal of Neuroradiology 30(5): 885-892, May 2009
  8. The role of nuclear medicine in clinical investigation BMJ 1998;316:1140–1146 ( 11 April ) E M Prvulovich, consultant, nuclear medicine, J B Bomanji, consultant, nuclear medicine from website: http://www.bmj.com/cgi/content/full/316/7138/1140
  9. Bonte, F. J.; Harris, T. S.; Hynan, L. S.; Bigio, E. H.; White, C. L. (2006). "Tc-99m HMPAO SPECT in the Differential Diagnosis of the Dementias with Histopathologic Confirmation". Clinical Nuclear Medicine 31 (7): 376–8. doi:10.1097/01.rlu.0000222736.81365.63. PMID 16785801.
  10. Dougall, N. J.; Bruggink, S. .; Ebmeier, K. . (2004). "Systematic Review of the Diagnostic Accuracy of 99mTc-HMPAO-SPECT in Dementia". American Journal of Geriatric Psychiatry 12 (6): 554–70. doi:10.1176/appi.ajgp.12.6.554. PMID 15545324.
  11. Sexually Transmitted Diseases Treatment Guidelines, 2010 from Centers for Disease Control and Prevention, Recommendations and Reports. December 17, 2010 / Vol. 59 / No. RR-12
  12. 1 2 Medscape > Testicular Torsion Imaging by David Paushter. Updated: May 25, 2011
This article is issued from Wikipedia - version of the Monday, April 18, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.