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Show STATE OF THE ART Diffusion- Weighted Magnetic Resonance Imaging Suresh K. Mukherji, MD, Thomas L. Chenevert, PhD, and Mauricio Castillo, MD Diffusion- weighted magnetic resonance imaging is a specialized technique that measures the degree of diffusion of water molecules within extracellular space and between intracellular and extracellular space. Diffusion- weighted imaging signal is high ( bright) when diffusion is restricted, as occurs in cytotoxic damage from ischemia, inflammation, trauma, or tumor. This technique, now available on most magnetic resonance imaging units, is especially helpful in detecting early ischemic stroke and multiple sclerosis and in differentiating arachnoid cyst from epidermoid tumor and brain abscess from neoplasm. ( JNeuvo- Ophthalmol 2002; 22: 118- 122) Diffusion- weighted imaging ( DWI) is a specialized magnetic resonance imaging ( MRI) technique that is particularly sensitive to the normally disorganized ( random, " Brownian") microscopic motion of water molecules ( 1). In the brain, signal intensity on DWI depends primarily on the ability of water molecules to move within and between the intracellular and extracellular spaces via permeable cell membranes. Thus far, DWI has been used primarily for the detection of acute cerebral infarction, which impairs water mobility. However, there are other applications in which DWI facilitates diagnostic insight. TECHNICAL CONSIDERATIONS The increased use of DWI arises from advances in newer MR units that allow them to perform echoplanar imaging. These units contain advanced gradients capable of very fast switching times that permit each image to be acquired in approximately one tenth of a second. As a result, a whole brain DWI series can be obtained in seconds rather than minutes. A DWI pulse sequence incorporates two additional gradient pulses compared with a conventional spin Departments of Radiology ( SKM, TLC) and Otolaryngology Head Neck Surgery ( SKM), University of Michigan Health System, Ann Arbor, Michigan, USA. Department of Radiology, University of North Carolina School of Medicine ( MC), Chapel Hill, North Carolina, USA. Address correspondence to Suresh K. Mukherji, MD, Department of Radiology, 1500 East Medical Center Drive, Ann Arbor, MI 48109, USA; E- mail: mukherji@ umich. edu echo imaging sequence. These additional pulses allow measurement of microscopic motion of water molecules. The first gradient pulse alters the magnetization of each water molecule based on the position of the molecule. The second gradient pulse completely removes this alteration as long as the water molecule remains at its original location and does not move. However, any molecular movement over the interval when these pulses are applied will lead to incomplete restoration of the water magnetization. That is, molecular motion in the presence of the " diffusion gradient pulses" leads to a loss of MRI signal. The sensitivity to dif-fusional signal loss is controlled by choice of an image acquisition parameter called the " b- value." For neuroimag-ing, a b- value of about lOOOsec/ mm2 is often used because it offers good diffusion- dependent contrast and image quality ( 2,3). For a given b- value, the amount of signal loss reflects molecular mobility. Greater mobility, or diffusion, yields less MRI signal. Conversely, a relatively strong MRI signal implies more stationary molecules. Figure 1 illustrates the stark signal loss in fluid tissues as the b- value is increased from zero ( Fig. \ A) to 1000 sec/ mm2 ( Fig. IB). Molecular motions that have no directional dependence are termed " isotropic". For isotropic media, the specific direction of the applied diffusion gradient is of no consequence. In some tissues, however, water mobility does vary with direction. These tissues are called " anisotropic". White matter, for example, is highly anisotropic since water mobility parallel to the white matter fiber tracts is substantially greater than perpendicular to those tracts. In anisotropic media, the direction of the applied diffusion gradient is an important consideration. Thus, by control of the diffusion gradient direction, one probes structural directionality of the imaged object ( Fig. 2). In " apparent diffusion coefficient" ( ADC) maps, regions that contain high water mobility, such as the ventricular cavities, show up as bright relative to regions of low water mobility, such as brain tissue. Modern clinical diffusion imaging systems provide several representations of diffusion properties to accentuate or suppress directional information by appropriate mathematical combination of several directional data sets. As shown in Figure 2, the average of diffusion maps from three orthogonal directions ( ADCR/ L, ADCA/ P, and ADCS/ 1) yields a diffusion map that, by design, does not exhibit complex fiber tract patterns. This " average" diffusion coefficient map is / i # , pOL10.1097/ 01. WNp, 0. QQ0019698.15867.. 57 . J. Neuro- Ophthalmol. Vol. 22, No. 2,2Q02 , Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. STATE OF THE ART JNeuro- Ophthalmol, Vol. 22, No. 2, 2002 FIG. 1. The effect of changing the acquisition parameter " b value" on diffusion- weighted magnetic resonance image signal intensity. A: Diffusion- weighted magnetic resonance image with a b- value = 0 sec/ mm2 is similar to a T2- weighted image with high signal within the ventricles { arrow) and within a glioma { arrowhead). B: DWI with a b- value = 1000 sec/ mm2 shows signal loss within the ventricle { arrow). The loss of signal within the glioma { arrowhead) indicates that the glioma contains fluid. the best single quantitative representation of diffusion in the object. The diffusion- weighted image represents the raw signal strength recorded in the presence of diffusion gradients. As such, the diffusion- weighted image exhibits high mobility areas as dark relative to water confined by tissues. Note that the relative contrast of a diffusion- weighted image is nearly reversed relative to an ADC map. The utility of the diffusion- weighted image representation is that tissues with lower restricted diffusion are depicted as bright and with greater conspicuity than on ADC maps ( Fig. 3). DWI clearly distinguishes between two types of " excess water," or edema, in the central nervous system. Vasogenic edema, caused by incompetence of blood vessels or breakdown of the blood- brain barrier, is an increase in the amount of extracellular water; it is commonly seen along white matter tracts. Cytotoxic edema implies damage to cell membranes, reflecting a failure of the sodium- potassium pump needed to exclude extracellular water from the cell ( 5,6). This type of edema is typically seen in regions of ischemia or infarcts. On T2- weighted images, both types of edema show up as high ( bright) signal. On diffusion-weighted images, vasogenic edema appears relatively low ( dark) signal intensity, whereas cytotoxic edema results in high ( bright) signal intensity. Occasionally, very high signal on T2- weighted images will result in high signal on diffusion- weighted images ( T2 " shine- through"). ADC maps are useful in determining whether the increased DWI signal is due to restricted diffusion or T2 shine- through effects. However, in routine clinical imaging, ADC maps are often not necessary, as this distinction can be made by simple visual inspection ( 4). That is, if the T2 signal is not very bright and the diffusion- weighted image is very bright, the DWI high signal likely reflects restricted diffusion. CLINICAL APPLICATIONS Cerebral Infarction DWI has made its greatest contribution to the evaluation of acute cerebral infarction. DWI may demonstrate most central nervous system infarctions within minutes of clinical onset. This feature makes it a valuable tool to determine whether thrombolytic therapy should be performed. Cytotoxic edema occurs within a few minutes of a critical decrease in cerebral blood flow. This change is picked up as high signal on DWI as early as 3 minutes after clinical symptoms occur. Most infarctions will show abnormalities within 45 minutes after onset ( 7). The sensitivity of DWI is said to be close to 100% if 2 hours have elapsed after a brain infarction. In general, sensitivity and specificity of DWI to cytotoxic edema is close to 95%, making it one of the most reliable noninvasive techniques. The presence of cytotoxic edema ( and thus high signal DWI) does not necessarily imply irreversible cell death. Zones of brightness on diffusion- weighted images closely correspond to hypoperfused brain, but if perfusion is reestablished, DWI abnormalities may reverse. DWI abnormalities are maximal 24 hours after a stroke and start to resolve within 7 to 14 days thereafter ( Fig. 3). However, disappearance of high DWI signal does FIG. 2. Effect of diffusion gradient direction on signal intensity. A: Gradient direction right to left (" ADCRL"). The fibers in the optic radiations run perpendicular to this direction and are seen as " black" { arrowhead). B: Gradient direction anteroposterior (" ADCA/ P"). Because the optic radiations run perpendicular to this direction, they now have increased signal. C: Gradient direction superoinferior (" ACSS/|"). The fibers of the genu of the corpus callosum, which run from right to left, show signal loss { arrowhead). D: A composite of images in A, B, and C (" ADCo"). It has no specific gradient directionality, so the image is very homogeneous. E: The standard diffusion- weighted magnetic resonance image (' routinely interpreted. DWL -,"). This is the image that is 119 Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited JNeuro- Ophthalmol, Vol. 22, No. 2, 2002 STATE OF THE ART FIG. 3. Diffusion- weighted magnetic resonance image in cerebral infarct. A: Diffusion- weighted magnetic resonance image shows high signal intensity in the left frontal lobe ( arrowhead) in an acute infarct. B: The corresponding apparent diffusion coefficient map shows reduced signal intensity, which indicates restricted diffusion and confirms the presence of an acute infarct. C, D: Repeat diffusion-weighted magnetic resonance imaging in the same patient 14 days later shows loss of the signal on diffusion- weighted magnetic resonance image ( C) and apparent diffusion coefficient map ( D). not imply a reversion to normal cell function. In many patients, conventional MRI will show an infarct. This phenomenon, known as " pseudonormalization," ( 2) is caused by cellular necrosis, which produces below normal signal intensity on diffusion- weighted images. Infarcts result in cell and axonal loss, reactive astrocytosis ( gliosis), and en-cephalomalacia. The encephalomalacia includes cysts that contain water whose motion is not restricted. Therefore, chronic infarcts are hypointense on diffusion- weighted images. The increased translational movement of water molecules in the encephalomalacic cysts results in increased spin dephasing and signal loss. This is similar to what is seen in arachnoid cysts ( see " Arachnoid Cyst Versus Epidermoid Tumor"). On ADC maps, chronic infarctions actually appear as areas of increased diffusion, that is, high signal intensity. Chronic infarctions appear smaller on diffusion- weighted images than on fast spin echo T2- weighted images ( 8,9,10,11,12). Arachnoid Cyst Versus Epidermoid Tumor DWI is helpful in distinguishing between arachnoid cysts and epidermoid tumors ( Fig. 4). These lesions may have similar features on Tl and T2 MRI weighted images and do not enhance. Differentiation between them is straightforward with DWI. Because arachnoid cysts tend to contain pulsating cerebrospinal fluid ( CSF), their signal intensity is low on high b- value DWI ( and high on ADC maps). By contrast, epidermoid tumors are solid masses whose water mobility is relatively low. Therefore, signal is higher on DWI and lower on ADC maps than that of the surrounding CSF. Abscess DWI has proved useful in the preoperative diagnosis of cerebral abscesses ( 13). In patients with no antecedent history, it is helpful to divide enhancing lesions into infections and tumors ( 14). Ring- enhancing lesions contain a FIG. 4. Diffusion- weighted magnetic resonance imaging differentiation of arachnoid from epidermoid cyst. A: Axial T2- weighted magnetic resonance image of arachnoid cyst shows high signal intensity mass ( arrow). B: Axial T2- weighted magnetic resonance image of epidermoid cyst shows high signal intensity mass ( arrow) similar to that of the arachnoid cyst. C: Apparent diffusion coefficient map of the arachnoid cyst has high signal ( arrow). D: Apparent diffusion coefficient map of the epidermoid cyst has low signal ( arrow). n 120 . , „.. , „ . . © 2002 Lippincott Williams & WUkins , Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. STATE OF THE ART JNeuro- Ophthalmol, Vol. 22, No. 2, 2002 FIG. 5. Diffusion- weighted magnetic resonance imaging of moderate grade glioma. A: Axial T2- weighted image shows a high signal mass in the left basal ganglia { arrow). B: Corresponding diffusion- weighted magnetic resonance image shows increased signal within the mass { arrow). From this image alone, it is unclear whether the increased signal is due to restricted diffusion or " T2 shine- through" effect. C: The apparent diffusion coefficient map shows the mass to be heterogeneous. The central area { short arrow) has reduced signal intensity, which indicates restricted diffusion, whereas the periphery { long arrow) has high signal due to T2 " shine- through" effect. center that represents necrosis and/ or cysts. In abscesses, the necrotic area harbors a complex matrix of proteins, inflammatory cells, cellular debris, and bacteria in high viscosity pus. The water molecules are bound to carboxyl, hydroxyl, and amino acid groups on the surface of macro-molecules ( 15). These characteristics contribute to restricted Brownian motion and result in increased signal intensity on DWI and low signal intensity on ADC. By contrast, the necrotic center of tumors contains a less viscous material composed mostly of cellular debris, serous fluid, blood products, and relatively fewer inflammatory cells. This less complex environment allows water molecules a greater degree of translational motion than occurs in abscesses. Thus, the center of tumors is often of relatively low signal intensity on diffusion- weighted images and shows a high signal intensity ADC. In addition, the blood products, which may not be obvious on conventional magnetic resonance images, result in significant effects on diffusion-weighted images that contribute to low signal intensity. To avoid contamination of T2 shine- through when evaluating a potential abscess, review of ADC maps is helpful. Multiple Sclerosis The breakdown of the myelin sheath in acute multiple sclerosis ( MS) plaques reduces the motion of the water molecules in the extracellular space. Because anisotropy is relatively reduced due to the loss of organization of the white matter fibers, there will be an increase in signal intensity on DWI and a lowering on ADC ( 1). DWI may measure improvement in molecular motion as a response to therapy before signal changes reverse on conventional T2W or FLAIR images. DWI may also be helpful in dating MS plaques. As with old infarctions, chronic MS plaques show low signal intensity in DWI and high signal on ADC. Primary Brain Tumor DWI and ADC values have the potential to differentiate the components of a tumor and assess overall cellular-ity ( Fig. 5). Studies ( 16- 18) have shown that ADC values are generally low in solid/ cellular tumors relative to necrotic/ cystic tumors. These observations have also lead investigators to apply ADC maps to quantify therapy-induced necrosis. The use of DWI as an indicator of therapy response has been validated with animal models and in preliminary human studies ( 19- 21). REFERENCES 1. Gray L, MacFall J. Overview of diffusion imaging. MRI Clinics of North America 1998; 6: 125- 38. 2. Provenzale JM, Sorensen AG. Diffusion- weighted MR imaging in acute stroke: theoretical considerations and clinical applications. AJR 1999; 173: 1459- 67. 3. Castillo M, Mukherji SK. Practical applications of diffusion magnetic resonance imaging in acute cerebral infarction. 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