Applied Radiology

CME CATEGORY 1

This CME program is sponsored by an educational grant from Bracco Diagnostics Inc.

The Institute for Advanced Medical Education designates this continuing medical education activity for a maximum of 2 Category 1 credits toward the AMA Physician's Recognition Award. Each physician should claim only those credits that he/she actually spent in the activity.

To go directly to the quiz please click here

This CME article consists of text and related images appearing in this journal article and online at www.appliedradiology.com. You should read the articles and accompanying images, refer to the references, and complete the self-evaluation quiz available online at www.appliedradiology.com. There is no charge for participating in this program.

Estimated time for completion: Two hours

Date of release: April 2003

Expiration date: April 2005

Program: MH-001

LEARNING OBJECTIVES

After completing this activity, the reader will:

* Be familiar with the newest technical advances in MRI as they affect the CNS

* Know when contrast agents are useful in evaluation of CNS disease by clinical MRI

* Be familiar with the latest applications for MRI in the CNS

The central nervous system (CNS) was the first field of application in which the utility of magnetic resonance imaging (MRI) was demonstrated. ^1-3 In the early 1980s it was shown that most lesions appeared bright on T2-weighted images and dark on T1-weighted images on the basis of their higher water content. The inherent contrast resolution observed was much greater than that available with computed tomography (CT). However, the lack of an available contrast agent during the early days of MRI meant that the specificity for lesion characterization was relatively low and that a contrast-enhanced CT examination was still the standard imaging examination.

With the introduction of the first gadolinium (Gd) contrast agents in the mid-1980s, the balance of power shifted toward MRI for the evaluation of lesions in the CNS. ^4-9 The subsequent introduction in the mid-1990s of new sequences, such as fluid-attenuated inversion recovery (FLAIR), further increased the potential applications of MRI to the extent that MRI can now replace CT for most, if not all, diagnostic evaluations, including acute hemorrhage. ^10-13 On the other hand, CT is frequently still the primary imaging modality used for emergency patients and for patients with contraindications for MRI due to the presence of a pacemaker or a ferromagnetic aneurysm clip.

Today, MRI--specifically contrast-enhanced MRI--is standard for a full diagnostic evaluation of many CNS pathologies. Compared with other diagnostic techniques, MRI permits better visualization of anatomy and vessels. In consequence, MRI is of high value for the detection and diagnosis of pathology. While the greater speed of CT combined with technological advances (angiography, perfusion, three-dimensional [3D] postprocessing) make this still very much a valid technique, ongoing developments in functional MR imaging (fMRI) and interventional neuroradiology are likely to lead to further applications for contrast-enhanced MRI in neuroimaging.

This article will review the most recent developments in contrast-enhanced neuroimaging of CNS pathology.

IMAGING TECHNIQUES

In the early days of MR neuroimaging, spin-echo and gradient-echo sequences permitted the acquisition of excellent MR images based on differences in soft-tissue contrast. Subsequent developments in both hardware and software have led to significant progress in MR neuroimaging, such that today a wide variety of acquisition sequences is available for MR imaging of brain and spine pathology.

SPIN-ECHO IMAGING

From the very beginning, the fundamental approach to MR imaging of the CNS has centered upon the acquisition of T1- and T2-weighted spin-echo images. ^1,2 These sequences are less sensitive to susceptibility effects than are gradient-echo techniques. Fast-spin-echo sequences, in particular, allow the rapid acquisition of high-resolution T2-weighted and proton-density-weighted images and can be combined with inversion prepulses, as in the FLAIR sequences. The T1-weighted spin-echo sequences provide crucial information for the differential diagnosis of lesions, especially when they are used following an injection of Gd contrast agents to reveal breakdown of the blood-brain barrier (BBB). Proton-density (intermediate-weighted sequences) images are frequently of value for the evaluation of thrombus and for the delimitation of perpendicular flow during the evaluation of aneurysms or arteriovenous malformations (AVMs) before and after embolization.

GRADIENT-ECHO IMAGING

The advent of gradient-echo sequences with short repetition time (TR) allowed the acquisition of the first 3D MR images. ^14-20 These sequences today are fundamental to numerous MR angiographic techniques and remain the first choice for high-resolution 3D T1-weighted imaging. The use of contrast-enhanced 3D imaging is applicable in many situations, such as for the optimal detection of brain metastases. Three-dimensional gradient-echo sequences are also employed in the context of neuro-navigation surgery for which 3D MR stereotactic imaging is mandatory. ^19,21,22

ECHOPLANAR IMAGING

Echoplanar imaging (EPI) involves the use of a fast train of gradient echoes and is often employed in T2* perfusion imaging for the detection of hemorrhage ^23,24 and in fMRI using blood-oxygen-level­dependent (BOLD) techniques. ^25,26 Echoplanar imaging is essentially a readout module, similar to spin-echo or fast-spin-echo imaging. ²⁷ The readout module is preceded by a combination of 90° and 180° radiofrequency (RF) pulses, which determine the root contrast, eg, gradient echo, spin echo, or inversion recovery. ²⁷ Both single-shot ²⁸ and multishot ²⁹ EPI sequences have been used for neuroimaging; however, single-shot EPI is by far more prevalent. Until recently, one of the principal drawbacks of EPI sequences has been a relatively high sensitivity to susceptibility artifacts. ³⁰ This is partially alleviated by multishot EPI, which results in much less geometric distortion and less blurring, particularly in the critical region of the brain stem. With single-shot EPI, however, acquisition times on the order of 0.1 sec are now achievable, which is sufficient to eliminate all motion artifacts. Starting from a spin-echo EPI sequence with additional gradient pulses, diffusion-weighted images (DWI) can be obtained. ³¹ Further developments include the use of new parallel imaging techniques such as sensitivity encoding (SENSE) ^25,32-34 to reduce the EPI single-shot echo train length by a factor of about 2 to 3 (see below).

ECHOPLANAR DIFFUSION WEIGHTED IMAGING

Echoplanar diffusion imaging is classically employed for the detection of acute ischemia based on the presence of cytotoxic edema. ^33,35,36 While this is the best known cause of high signal on diffusion images, high signal is also seen in the case of acute demyelination, in tumors with high nuclear cytoplasmic ratios, in abscesses, and in encephalitis. Another potential mimicker of ischemia is a phenomenon known as T2 shine through where the high signal on the T2-weighted reference image (b ₀ image) shines through to the diffusion image. In order to avoid misdiagnosing restricted diffusion in such cases, apparent diffusion coefficient (ADC) maps can be calculated. ³⁷

One recent development (which may have applications for the evaluation of white matter diseases, ^38-41 ischemia, ⁴² and spinal cord pathology ⁴³ ) is diffusion tensor imaging (DTI). Since water diffuses faster parallel to the white matter than perpendicular to it, normal white matter has higher diffusion anisotropy than diseased white matter or normal gray matter. This difference in anisotropy can be observed on both DWI and ADC maps. Anisotropy is largest when the white matter in the voxel is totally intact and is decreased when the voxel involves damaged white matter or gray matter, which is less anisotropic. Scalar parameters, such as fractional anisotropy or relative anisotropy, can also be calculated using the three diffusion coefficients (Dx, Dy, Dz). ³⁸ These can be used to construct anisotropy maps of the entire brain.

In DTI, images sensitive to diffusion in at least six directions and one reference (b ₀ ) image are acquired. The postprocessing of these images amounts to a reorientation of the x, y, and z axes within the voxel so that the new z-axis for each voxel (called the principal eigenvector) corresponds to the principal direction of diffusion within that voxel. Since this direction is generally parallel to the main white matter bundle in the voxel, the final images render a tractogram demonstrating the actual location of the main white matter tracts in the brain. ⁴⁴ White matter tractography may be used in conjunction with fMRI activation to demonstrate physical connectivity as well as temporal correlation between areas of activation.

ECHOPLANAR PERFUSION IMAGING

Cerebral perfusion is defined as the delivery of nutrients and oxygen via blood to brain parenchyma per unit mass (reported in mL/100 g of tissue/min). Perfusion can be assessed using arterial spin labeling (ASL) techniques. ⁴⁵ With such techniques a slice of the brain is tagged with an RF pulse and then, after a variable period of time, a slice downstream is interrogated. Spins within a certain velocity range will demonstrate changes in intensity that permit a relative quantification of perfusion. With further refinement, ASL techniques may be used for fMRI and for the evaluation of stroke patients. However, while ASL methods permit a measure of the cerebral blood flow (CBF), at 1.5 T the signal-to-noise ratio (SNR) of this method is relatively poor. ⁴⁶ Contrast-enhanced methods based on T2* bolus techniques or T1 permeability sequences are usually preferred, particularly for the evaluation of stroke patients. With contrast-enhanced perfusion MR imaging, hemodynamic parameters such as CBF, cerebral blood volume (CBV), mean transit time (MTT), flow heterogeneity, extraction fraction, and permeability surface area product can be derived from imaging data involving the passage of an MR contrast agent through the cerebrovascular system.

In echoplanar perfusion imaging a compact bolus of Gd is injected and sequential imaging is performed of the entire brain using T2*-weighted gradient-echo EPI or T2-weighted spin-echo EPI techniques. Whereas the former technique usually requires a standard 0.1 mmol/kg dose of a conventional Gd contrast agent and reveals both capillaries and veins, the latter technique frequently requires a double dose and reveals the capillaries only. ⁴⁷ As the contrast agent bolus traverses the brain, the paramagnetic Gd causes T2* shortening, which results in decreased signal within a voxel. The signal intensity versus time curve initially dips and then returns to the baseline. The area under the curve is proportional to the relative cerebral blood volume (rCBV), which can be determined by computer integration. It is also possible to determine the midpoint of the curve in time (MTT) or the time to peak, both of which are useful indicators of the time it takes the blood to get to the specific voxel. By dividing the rCBV by the MTT, the relative cerebral blood flow (rCBF) can be determined. The modifier relative is necessary since a given voxel is being compared with all the other voxels in the image. In order to acquire an absolute measure of rCBF, an accurate arterial input function is needed. By placing a cursor over the middle cerebral artery, investigators have recently been able to achieve quantitative rCBFs, ⁴⁸ which facilitates comparison with positron emission tomography (PET) and xenon CT.

The rCBV is a measure of capillary density in the brain and in brain tumors has been shown to increase with angiogenesis. Thus, the rCBV is an appropriate parameter to distinguish between grade II, grade III, and grade IV gliomas. Unfortunately, low-grade (grade I) gliomas cannot be distinguished from normal brain at present. ⁴⁹

MR spectroscopy, on the other hand, can distinguish low-grade gliomas from normal brain on the basis of elevated choline and decreased N-acetylaspartate (NAA). ⁵⁰ With increasing malignancy, the choline/NAA ratio generally increases. With treatment, eg, of lymphomas, it has been shown to revert to normal. ⁵¹ At 3.0 T, it is quite likely that additional peaks will be demonstrated that will be capable of additional characterization of malignancy and response to treatment.

FUNCTIONAL MRI

Functional MRI (fMRI) is based on the increase in blood flow to a portion of the brain when it is activated by a specific task ⁵² and is not a technique for which contrast enhancement is required. In fMRI, the amount of blood passing to a portion of activated brain increases, increasing the relative concentrations of oxyhemoglobin (oxygenated blood) to deoxyhemoglobin (deoxygenated blood). Since deoxy-hemoglobin is paramagnetic and has a short T2, it is dark on a T2- or T2*-weighted image. Thus, with increasing oxyhemoglobin, there is increased signal intensity. By comparing images within regions of activated brain versus nonactivated brain, focal areas of increased signal can be detected, which correspond to increased blood flow. The contrast resulting from the deoxygenation of oxyhemoglobin to deoxyhemoglobin can be utilized by means of BOLD sequences. ⁵²

MR ANGIOGRAPHY

Several MR angiographic (MRA) techniques are available for imaging of the intra- and extra-cranial vasculature. The inflow (time-of-flight; TOF MRA) method is widely used and can be combined with magnetization transfer pulses and, optionally, with Gd injection to give high resolution images of the cerebral vasculature. ^53-55 Phase-contrast MRA, on the other hand, permits the acquisition of directional information and flow quantification. ^55,56 Both methods have benefited from developments in fast gradient hardware, which permits short echo times (TE) and thus fewer inflow artifacts and turbulence-related signal losses. ⁵⁷

A rapidly developing approach to MR angiography of the intra- and extra-cranial vasculature is contrast-enhanced MRA (CE-MRA). ^53,58 Generally, CE-MRA is performed using gradient-echo sequences with short TR/TE (<6/<2 ms) and a large flip angle (>30°). The overall effect is one of increased vascular signal due to tissue signal saturation and a Gd-induced reduction in blood T1. ⁵⁹ Gadolinium-based contrast agents are generally injected as a bolus, preferably with a power injector. Depending on the injected dose (usually between 0.1 and 0.3 mmol/kg bodyweight), the blood T1 can be decreased by between 50 and 150 ms. These very short T1 values give rise to markedly increased signal intensities and inherently high SNRs on heavily T1-weighted sequences. While the use of a short TR ensures a short acquisition time, the use of a short TE ensures that CE-MRA images are less prone to turbulence-related signal loss and intra-voxel dephasing effects than TOF or phase-contrast sequences. Another important feature of CE-MRA is that it is almost independent of the direction of flow and, therefore, in-plane flow can be imaged over a very large field-of-view (for example, in carotid studies conducted in the coronal plane). In 3D CE-MRA, a large imaging matrix over a large field-of-view is usually employed, which permits the acquisition of images with high spatial resolution.

Alternatively, higher temporal resolution can be achieved by means of two-dimensional (2D) or 3D MR digital subtraction angiography (MRDSA). This technique consists of dynamic acquisitions with high temporal resolution (2D projection images at a rate of 2 frames/sec or a 3D volume every 3 to 6 sec) and involves real-time subtraction of a mask image, itself acquired before the Gd bolus has reached the arteries of interest. ^60-64 Thus, for the first time, 2D MRDSA has the potential to provide similar dynamic information to that which is routinely obtained with conventional digital subtraction angiography (DSA). The hemodynamic information gained on MRDSA has already proven to be clinically relevant for the evaluation of arteriovenous malformations and fistulas. ^65-67

In general, an intravenous injection of 7 mL Gd at a flow rate of 3.5 to 5 mL/sec provides satisfactory images for brain AVM studies. Because the technique involves a subtraction, the injection can be repeated, and different imaging orientations can be obtained. Moreover, by acquiring alternate images in two orthogonal planes, the need for re-injection can be eliminated. Although the SNR drops with increasing time resolution, the use of high R1 contrast agents, such as gadobenate dimeglumine, may represent a way to obviate the problem.

Unlike 2D MRDSA, 3D CE-MR arteriography is individually timed after the injection of 20 to 40 mL Gd at a rate of 2 to 4 mL/sec, with an acquisition duration of 15 to 35 sec. ^68,69 In order to trigger the 3D acquisition in the arterial phase, 2D MRDSA can be implemented as Gd tracking method, enabling the MR operator to follow the progress of the contrast agent in the vasculature up to a reference artery: at this point, the 3D sequence is started. In this arrangement the 3D k-space has to be sampled from the center to the periphery, following the so-called elliptical centric scheme. ⁷⁰ Three-dimensional CE-MR arteriography is an appropriate technique for numerous purposes. Used in conjunction with a head-neck coil, it is an effective technique to study the carotid and vertebral arteries comprehensively in the coronal plane both from their origin up to the intracranial arteries. It has also been shown to be valuable for the detection of intracranial aneurysms and for the evaluation of AVMs. ^71,72

Parallel imaging techniques are especially useful in CE-MRA. ^23,73,74 Sensitivity encoding shortens the acquisition time, which in turns allows multiple 3D arterial phases to be acquired. The reduction of raw data collection with SENSE can be reinvested in the form of an increased matrix size or an increased number of slices. Moreover, knowledge of coil sensitivity profiles can be exploited in order to correct signal intensity inhomogeneities resulting from the use of coupled surface coils. A reduced SNR is inherent to the SENSE approach. However, this does not represent a critical problem in MR arteriography, since the arterial SNR is high due to the high arterial Gd concentration.

At high field (3.0 T), images with higher spatial resolution are attainable, with voxel sizes of about 0.6 mm ³ . ⁷⁵ While this is adequate to demonstrate arterial occlusion due to an embolus or intracranial atherosclerosis, it is not usually sufficient to evaluate vasculitis or arterial spasm from subarachnoid hemorrhage. For this, 250 µm spatial resolution is required (1024 ¥ 1024), which is the same as that available in catheter angiography. In order to achieve this high resolution, it is likely that imaging at 3.0T should be combined with the use of improved Gd chelates.

CLINICAL APPLICATIONS OF CONTRAST-ENHANCED NEURO MRI

Pathologies affecting the CNS are numerous and diverse, and there are marked differences between diseases in the need for contrast enhancement to achieve accurate diagnosis. The following section will review the current value of contrast enhancement for the diagnostic evaluation of CNS pathology in the brain and spine. The relative value of recent contrast-enhanced techniques for the imaging of these pathologies is also discussed.

BRAIN

Congenital Abnormalities

The vast majority of congenital abnormalities do not require contrast enhancement to be visualized satisfactorily. Exceptions, however, include some vascular malformations and tumors associated with congenital abnormalities as seen, for example, in phakomatoses.

Vascular Malformations

The intracranial types of vascular malformation are AVMs, capillary telangiectases, cavernous angiomas, and venous malformations. In many of such cases, conventional MRI is a superb technique because it provides exquisite detail of the parenchyma while simultaneously demonstrating the vascular anomalies.

Cerebral AVMs are classically described as congenital malformations consisting of arteriovenous shunts located in the subpial space, with arteries that drain directly into veins in the absence of a normal capillary system. Patients with AVMs can present with various symptoms: cerebral and subarachnoid hemorrhage, seizures, neurologic deficits, or headache. The treatment of AVMs potentially involves three modalities: microsurgery, endovascular embolisation, and radiosurgery. The most appropriate choice of modality depends on several factors, such as angioarchitectural features, the size of the nidus, and the location in the brain. If comparatively small in size and located near the convexity, surgical removal is frequently the approach of choice. Larger AVMs, on the other hand, are best treated by endovascular therapy, often during multiple sessions. When the AVM volume is relatively small, high-dose radiosurgery induces complete obliteration. Endovascular embolization causes huge hemodynamic changes and provides partial obliteration, or, less frequently, complete obliteration. ^76-78

MRI and MRA provide valuable information concerning the anatomic location, the morphology of the AVM, and the surrounding brain parenchyma. Additionally, MR can assess the presence of risks factors, including aneurysm, venous thrombosis, central venous drainage, periventricular or deep location and the occurrence of a previous hemorrhage. An improved delineation of feeding arteries and draining veins is obtained when 3D phase-contrast acquisitions are acquired after administration of a Gd contrast agent. However, 3D CE-MRA techniques have the advantage of a shorter acquisition time and less sensitivity to turbulence-related signal losses. The dynamic information required by clinicians is traditionally obtained by means of conventional X-ray angiography DSA, but recent developments in MRDSA acquired after a short Gd bolus have shown that some hemodynamic features can be demonstrated. ⁷⁹ In this context, the advent of high R1 contrast agents, ie, those with a greater T1 shortening per unit dose, is extremely promising (Figure 1). ⁸⁰

Dural AVMs and dural fistulae are often more difficult to detect than parenchymal AVMs as they are located close to the bony structures of the skull or skull base, and typically also involve the cavernous sinus. A cortical dilated vein or a sinus stenosis may be the only indication of this vascular anomaly. Traditionally, conventional angiography, rather than plain contrast-enhanced MRI, has been used most frequently for the evaluation of these lesions. However, advances in CE-MRA have not only meant that depiction of the dural malformation is now achievable non-
invasively, but also that the interventional neuroradiologist performing the embolization can be guided more easily.

Capillary telangiectases are vascular malformations that were, in the past, most frequently identified at postmortem examinations. Today, they are often detected incidentally on contrast-enhanced studies as poorly delineated foci of increased signal intensity, most frequently in the mid pons.

Cavernous angiomas are typically not detected on DSA but have a very characteristic appearance on unenhanced T1- and T2-weighted MR images and a variable appearance on enhanced images. Venous angiomas associated with cavernous angiomas are extremely important to detect, as they may be responsible for hemorrhage. These lesions are best seen on contrast-enhanced MRI.

Venous malformations are equally important to detect, and their presence may have important clinical implications. The use of late-phase CE-MRA images can be recommended as an easy, rapid, and efficient way to display these anomalies.

Tumors

Changes in the signal behavior of tumors after contrast enhancement are often of significant diagnostic importance. The signal behavior of tumors on contrast-enhanced T1-weighted MRI frequently permits better tumor characterization and tumor delineation (Figures 2 through 7). Increased tumor vascularity, however, is not synonymous with malignancy. Several recent developments have improved the approach to the diagnosis of brain tumors. As discussed above, echo-planar perfusion imaging can be used to show the region of highest rCBV, which usually corresponds to the most malignant portion of the tumor. This information guides the choice of the biopsy site, as tumors are often heterogeneous and the most malignant areas should be identified for proper grading in order to enable the optimal therapeutic choice. Relative cerebral blood volume measurements have been shown to correlate with the vascularity of various intracranial mass lesions. MR CBV maps can be used to assess the degree of neovascularization in the brain. In addition to aiding tumor grading, the evaluation of malignancy, and the identification of other types of lesions without neovascularization such as radiation necrosis and cerebral abscess, perfusion MRI may be useful for the follow-up of treatment by providing a noninvasive assessment of changes in tumor rCBV. ⁸¹

Furthermore, MR measurements of rCBV have been shown to correlate with both conventional angiographic assessments of tumor vascular density and histologic measurements of tumor neovascularization. The results of perfusion-sensitive MR imaging using a gradient echoplanar technique have been shown to correlate with both histologic and angiographic vascularities. ⁸² In fibrillary low-grade astrocytomas, rCBV measurements appear useful for the noninvasive assessment of angiogenesis. Data suggest that high pre-therapeutic angiogenic activity in low-grade astrocytomas indicates a subgroup of tumors at higher risk for early local recurrence or malignant transformation after fractionated stereotactic radiotherapy. ⁸³ Perfusion MR data has been shown to correlate with clinical response in patients undergoing antiangiogenic therapy. ^84,85 Recent work aimed at correlating tumor grade with abnormalities in the recirculation of a contrast agent bolus may provide independent information on microcirculation and angiogenesis. Abnormalities of contrast agent recirculation may be of value as surrogate markers in trials of antiangiogenic therapy. ⁸⁶

MR spectroscopy (MRS) can also be used to show the most malignant portion of the tumor, based on the ratio of choline to N-acetyl aspartate (NAA). However, MRS suffers from lower spatial resolution than perfusion imaging. Although MRS voxel sizes have improved from 2 cm (single voxel) to 1 cm (single slice, multivoxel) and 7 mm (multislice-multivoxel or 3D), perfusion imaging has an in-plane resolution of 2 mm.

Contrast-enhanced FLAIR is more useful than unenhanced FLAIR and enhanced T1-weighted imaging for subtle cortical processes, such as leptomeningeal carcinomatosis and early meningoencephalitis. This is probably due to the fact that less Gd is required to leak into the adjacent sulcus to change the signal intensity of the cerebrospinal fluid (CSF) and prevent nulling on FLAIR that is required to cause increased signal on T1-weighted imaging. Unenhanced and contrast-enhanced T1-weighted imaging is still required to distinguish enhancement from T2 prolongation as a cause of hyperintensity on enhanced FLAIR.

Infectious Processes

Contrast-enhanced MRI is mandatory for better evaluation of most infectious types of lesions such as meningitis, ventriculitis, abscess formation, and encephalitis. Unfortunately, the contrast enhancement patterns are often nonspecific. Other MR sequences, such as MR diffusion and MR spectroscopy, allow the differentiation of tumor from abscess in cases of ring-like enhancing lesions (Figure 8). In patients with HIV, micro-abscesses may occur that can be revealed only with Gd-enhanced T1-weighted sequences. However, in such cases, diffusion sequences and MRS may again serve as valuable additional tools to the contrast-enhanced sequences. Subdural empyema is a severe condition often overlooked on CT that can be readily appreciated on Gd-enhanced T1-weighted MRI.

Demyelinating Diseases

Although multiple sclerosis (MS) was the earliest application demonstrated for MRI in the CNS more than 20 years ago, new MR techniques continue to improve the diagnosis of this and other demyelinating diseases, such as acute disseminated encephalomyelitis (ADEM). Using 2-mm sagittal FLAIR images, subcallosal striations can be seen as a stack of 1-mm thick coins aligned perpendicular to the ependymal stripe. Detection of such lesions using thin-slice, sagittal FLAIR has been shown to be highly correlated ( P <0.001) with MS. ⁸⁷

Acute inflammatory lesions show early disruption of the BBB, which is best demonstrated on contrast-enhanced T1-weighted images (Figure 9). Gadolinium enhancement correlates in time with the acute inflammatory phase; without treatment this enhancement subsides after approximately 1 month.

Acute demyelination can also be seen with diffusion imaging, which may be useful in making the diagnosis. Moreover, early studies also suggested that proton spectroscopy could lead to better categorization of MS lesions than contrast enhancement. ⁸⁸ However, with technological developments and the advent of novel contrast agents, this may no longer be the case.

Degenerative Diseases and Dementia

Currently, the use of contrast enhancement for imaging of degenerative diseases and dementia is limited. Perfusion studies can be helpful for the evaluation of Alzheimer's disease in which a temporoparietal hypoperfusion can be found, or in frontotemporal dementias, in which, again, areas of hypoperfusion are observed even in early stages of the disease. ^89,90 Although MR perfusion studies provide similar information as PET, absolute quantification of the measurements is difficult with MRI.

However, in current clinical practice, PET studies are usually preferred to perfusion MRI studies.

Trauma

MRI is not only a valuable complementary imaging procedure to CT for the evaluation of acute head trauma but is frequently considered the best imaging procedure for the evaluation of most traumatic lesions. Patients with corpus callosal injuries, in whom the incidence of diffuse axonal injury is comparatively high, ⁹¹ may have normal CT findings but demonstrate evidence of the injury on MRI. These lesions might be responsible for some aspects of the postconcussive syndrome. Although contrast injection is rarely required for the evaluation of posttraumatic changes, it can be of benefit when infectious complications occur, such as in cases of subdural empyema or intracranial abscesses linked to open fractures of the skull and skull base involving the sinuses.

In cases of traumatic dissection of the carotid or vertebral arteries, contrast-enhanced T1-weighted bolus MR angiography is the preferred procedure since the technique is fast and reliable. Moreover, the technique can be performed in conjunction with a postcontrast T1-weighted brain examination to demonstrate the extent of the BBB disruption. At present, in routine practice, diffusion imaging is the preferred approach to evaluating secondary brain ischemic lesions linked to traumatic arterial dissections.

Acute Ischemia and Stroke

Fifteen percent of all strokes in the Western world are due to hemorrhage rather than ischemic events. CT is currently performed in the acute setting to exclude hemorrhage in patients with evolving symptoms who are being considered for heparinization. However, the ability of MRI to detect hyperacute hemorrhage either in the brain parenchyma or in the subarachnoid space may enable MRI to become the primary imaging tool for the evaluation of acute stroke. Since routine treatment of stroke with thrombolytic agents generally does not allow either the time or the expense of performing both a CT and an MR examination, it is likely MRI will prove to be the most effective technique to detect hemorrhage, to further characterize the lesions, and to determine whether thrombolysis or neuroprotection is indicated.

The evaluation of stroke patients is commonly performed by means of echoplanar perfusion and diffusion imaging. Whenever the area of the perfusion abnormality is greater than the diffusion abnormality, additional brain is at risk for extension of infarction. This area of potentially salvageable brain is known as the ischemic penumbra ⁹² and is the target of current thrombolytic agents and future so-called neuroprotective agents.

While the core of the infarct is determined easily by diffusion imaging, the ischemic penumbra can occupy a volume three times greater than the core. Therefore, patients with an ischemic penumbra should be identified immediately and treated within 3 hours (for intravenous thrombolysis) or 6 hours (for intra-arterial thrombolysis) under current protocols. With echoplanar diffusion and perfusion techniques, frequently decisions to perform thrombolysis can be individualized. For example, a recent study revealed that when the rCBF in the infarcted hemisphere was <35% of the normal hemisphere, bleeding occurred with intra-arterial thrombolysis even when it was performed within 2 hours of symptom onset. On the other hand, if the ratio of rCBFs exceeded 55%, no bleeding occurred, even if intra-arterial thrombolysis was administered as late as 12 hours after symptom onset. ⁹³

Ideally, all potential candidates for thrombolytic therapy would undergo echoplanar diffusion and perfusion imaging, since as many as 50% of current stroke patients receive thrombolytics inappropriately, sometimes resulting in unnecessary cerebral hemorrhage. For example, an estimated 20% of patients who present with stroke in fact have a process other than ischemia. ⁹⁴ These include hemiplegic and hemisensory migraines, Todd's paralysis following a seizure, and certain inflammatory conditions. Thus, positive diffusion imaging will confirm the presence of true ischemia, eliminating patients who do not have ischemia and who should not be given thrombolytics. In addition, approximately 10% of all patients have had silent infarcts prior to the clinical event. ⁹⁴ While these older areas of infarction may not be evident on CT, they are clearly seen on echoplanar diffusion imaging and would constitute an increased risk of hemorrhage if thrombolytics were administered, since they exceed the 3- to 6-hour time window. Approximately 20% of all patients presenting with stroke have matched diffusion and perfusion defects, ie, they have no ischemic penumbra. ⁹⁴ Such patients are not candidates for thrombolytic therapy since the core of the infarct cannot be salvaged with current therapies.

Not all strokes are detected with echoplanar diffusion imaging. Indeed, positive identification is not usually made until the rCBF is <20% of normal. ⁹⁵ Most MR stroke evaluation today is accompanied by MR angiography of the carotid arteries and the intracranial circulation.

SPINE AND SPINAL CORD

In the spine, MRI has rapidly replaced myelography and myelo-CT for the evaluation of myelopathy and is today considered the principal modality for the evaluation of spinal cord lesions. ⁹⁶ Contrast-enhanced MRI is also of major use for the evaluation of bone lesions and degenerative disease in the spine. Currently, CT occupies a secondary, adjunctive role in the evaluation of the spine and spinal cord, generally for the evaluation of trauma and for the detection of small bone fragments impinging upon the cord.

Spinal Cord Tumors

Tumors of the spinal cord are rare. Overall, only approximately 5% of spinal tumors are intramedullary, while 40% are intradural extramedullary and 55% are extradural. ⁹⁷

Contrast-enhanced MRI is mandatory for the work-up and preoperative evaluation of spinal cord tumors (Figure 10). However, it is important to bear in mind that not all tumors enhance, and that not all enhancing intramedullary masses expanding the cord are neoplasms.

Intramedullary Tumors: Most intra-medullary tumors are one of the following types: astrocytomas, ependymomas, or hemangioblastomas. However, a differential diagnosis is important as surgical planning and prognosis will be very different for the different lesion types (Figure 11). Hence, it is important that contrast enhancement patterns are described carefully: ependymomas usually enhance more intensely and homogeneously, while astrocytomas enhance moderately and are usually inhomogeneous in appearance. Hemangioblastomas are benign, richly vascular spinal cord tumors, often located superficially, in the subpial region. Tumor nodules are usually small and are typically associated with extensive hydrosyringomyelia. After Gd injection, intense and homogeneous contrast uptake is seen. Contrast administration is especially useful in the case of small, often multiple nodules such as seen in von Hipple Lindau disease.

Many intramedullary tumors exhibit cystic components that are either part of the tumor or are associated satellite cysts that are located cephalad or caudal to the solid nodule with walls that do not enhance after Gd injection. These cysts develop as an intramedullary reaction to the presence of the tumor and the liquid has a similar behavior to CSF. They collapse spontaneously after surgery. On the other hand, tumoral cysts have enhancing walls and should be removed at surgery.

Even with MRI, it may be difficult or impossible to differentiate spinal tumors from intramedullary non-neoplastic lesions. ^98,99 In a study of 212 patients undergoing surgery for intramedullary spinal cord tumors, Lee et al ⁹⁸ reported finding non-neoplastic lesions in 4% of patients; histology showed demyelinating disease, sarcoidosis, amyloid angiopathy, and a mass of non-neoplastic inflammatory cells of unknown origin.

Intradural Extramedullary Tumors: These lesions are predominantly benign tumors and include nervesheath tumors and meningiomas. Contrast injection should be administered systematically in order to better delineate the borders of the tumor and to help in tumor characterization (Figure 12).

Epidural Tumors: Most spinal epidural tumors are malignant tumors, primarily metastases. However, lymphoma, leukemia, and multiple myeloma must also be included in the differential diagnosis. Contrast injection is useful to better delineate the intracanalar extension but should not be given from the outset as bony infiltration can be masked after contrast injection. Demonstration of the possible association of neoplastic bony infiltration is best achieved on unenhanced T1-weighted images.

INTERVENTIONAL MRI

MRI-guided biopsy is an area of growing clinical interest due in part to the superior tissue contrast of MRI relative to CT or ultrasound. The development of MR-compatible biopsy devices, as well as the diffusion of techniques involving image co-registration and the use of stereotactic frames or pellets, has made possible the era of guided microsurgery. Image-guided techniques have proven useful for directing biopies and resections, and for determining radiosurgery targets when using gamma knives or accelerator beams. Newer image co-registration techniques (MR-MR or MR-PET) permit improved follow-up studies of residual AVM niduses or small cerebral-pontine tumors after resection or irradiation.

A number of centers have now placed MR scanners in neurosurgical operating rooms. While this may appear somewhat extravagant, it is important to remember that current high-end operating microscopes cost close to $1 million which is similar to the cost of an open magnet with a coupled optical tracking system. Such systems are clearly useful for biopsy; however, they have shown even greater utility in guiding the resection of brain tumors. Several years ago, the neurosurgeons at Brigham and Women's Hospital (Boston, MA) and the neuroradiologists at Long Beach Memorial Medical Center (Long Beach, CA) presented data at U.S. national meetings showing that in 80% of cases in which the neurosurgeons thought they had achieved a gross total resection, MR-visible tumor could still be found. ¹⁰¹ While this is unlikely to have a major impact on outcome for high-grade gliomas, true gross total resection of low-grade gliomas effectively achieves a cure. Leaving even a small remnant of low-grade glioma behind increases the chance of subsequent degeneration into a glioblastoma multiforme, which is almost always fatal. Thus, whenever possible, low-grade gliomas should be resected under MR guidance.

Recently, at the Erasme Hospital (Brussels, Belgium), a low-field open intraoperative magnet was installed to guide and monitor the removal of both pituitary and brain tumors. Although the image field-of-view is limited and image resolution is relatively low, image fusion between the low-field images obtained in the operating theater and the preoperative high-resolution images has markedly improved MR guidance (Figure 13). In this setting, contrast injection is required to enhance lesion border definition: the use of gadobenate dimeglumine (Gd-BOPTA; MultiHance, Bracco Diagnostics Inc., Princeton, NJ) is presently undergoing evaluation, since better contrast enhancement can be expected due to the higher relaxivity of this contrast agent.

In addition to the presence of MR scanners in neurosurgical operating rooms, MR imaging systems are now combined with angiography suites. This could be useful for the evaluation of perfusion and diffusion in stroke patients while intra-arterial thrombolytic therapy is administered.

In the future, transcranial focused ultrasound may be capable of achieving brain tumor ablations without breaking the skin. One advantage of performing ablations under MR guidance is the sensitivity of MR to temperature changes (MR thermometry). ¹⁰² With large arrays of focused ultrasound transducers, ¹⁰³ power can be delivered to a point in the brain with minimal heating of the surrounding normal tissue. Such techniques would be particularly useful for deep-seated tumors where exposure is a problem and gaining access to the tumor frequently causes as much damage as the tumor itself. Focused ultrasound may also be used in the future to deliver gene therapy to focal areas of the brain, eg, tumors. Liposomes loaded with genetic material can be selectively lysed using focused ultrasound at a specific target. Since neither surgery, radiotherapy, nor chemotherapy has yet demonstrated significant impact on survival in patients with glioblastoma multiforme, it is hoped that gene therapy/molecular medicine will achieve this goal in the future.

TECHNICAL DEVELOPMENTS IN MRI

As MRI gradually became a dominant imaging modality in medicine, efforts by physicists further accelerated its development. As a result of multiple refinements in software and hardware, the future of CNS MRI will be both better and faster, with applications not even dreamed of a few years ago. Major hardware improvements will be found in every major MR subsystem: main magnet, gradients, RF, and computer. Moreover, improvements in imaging technique have already greatly benefited clinical practice and will continue to do so. Finally, the development of novel contrast agents with unique properties promises also to further extend the horizons for MRI of the CNS.

MAGNET STRENGTH

The field strength of the main magnet, which had plateaued at 1.5 T for almost two decades, has now jumped to 3.0 T. Systems with even higher field strengths are now being used for research applications.

Increasingly, the new 3.0 T MR systems are being used in academic settings and busy outpatient clinical environments. Specific applications that are facilitated at high field include fMRI and MR spectroscopy (MRS). Functional MRI has improved due to an increased BOLD effect at higher field caused by increased susceptibility effects. MR spectroscopy has improved as a result of increasing peak separation at higher fields. Arterial spin-labeling techniques should also perform better at 3.0 T. MR angiography at 3.0 T may also permit marked improvements in spatial resolution. ⁷⁵

GRADIENTS

There are currently three classes of gradients, which are characterized by strength and slew rate (strength/rise time). These are labeled standard (10 mT/m strength, 10 mT/m/msec slew rate), EPI (20 to 30 mT/m strength, 70 to 120 slew), and cardiovascular (40+ mT/m strength, 150 to 200 slew).

Standard gradients were available when the first high-field systems were introduced in 1984. EPI gradients became available in 1994 and cardiovascular gradients became available in 1999.

Refinements in the gradient subsystem have resulted in the ability to acquire echoplanar images in 100 msec, ie, the same time as electron beam CT. Although the speed of EPI was the initial promise of these strong, fast gradients, the real application has come with the introduction of echoplanar diffusion and perfusion imaging, particularly for evaluation of ischemic stroke. The ability of EPI gradients also facilitated the introduction of contrast-enhanced MR angiography (CE-MRA), which is now the preferred imaging technique not only for the carotid arteries, but also for every other artery in the body.

With the newest class of cardiovascular gradients, these early EPI applications are being extended, eg, to diffusion tensor imaging and even higher resolution CE-MRA. The great sensitivity of T2*-weighted gradient echo EPI techniques to susceptibility effects has allowed fMRI in the brain. These gradients also allow single-shot fast-spin-echo (HASTE) imaging in several hundred msec as well as high-resolution gradient-echo techniques (eg, True FISP, FIESTA, and CISS) with acquisition times of under one second.

RADIOFREQUENCY

Advances in the radiofrequency­coil subsystem have the potential to impact the speed of imaging, much as fast-spin echo did a decade ago. Using phased arrays, parallel imaging (eg, SENSE, SMASH) becomes possible, allowing time-savings on the order of a factor of four or higher. Sensitivity encoding takes advantage of the local sensitivity of the individual coils in the phased array to decrease image acquisition times or to improve the image quality. This has been demonstrated to have major potential impact in MRA and fMRI. ^104,105 Since this is accomplished by decreasing the number of actual acquisitions, halving the acquisition time results in the usual drop in signal-to-noise (S/N) of 40%. Thus, parallel imaging techniques will have their greatest utility in applications that are not limited by signal-to-noise issues, eg, CE-MRA and 3.0 T imaging.

COMPUTER CAPABILITY

Improvements in the computer subsystem have resulted in the ability to handle increasingly large data files in increasingly shorter times. Bandwidth continues to increase for the analog to digital converter and the entire imaging data chain. Backend (ie, workstation) applications continue to improve (eg, multiplanar reformations, volume rendering, and maximum intensityprojections).

CONTRAST AGENTS

The Gd-based contrast agents in current widespread use for MRI of the CNS can be considered first generation agents and include:

* Magnevist (gadopentetate dimeglumine [Gd-DTPA]; Schering AG, Berlin, Germany/Berlex Imaging, Wayne NJ);

* ProHance (gadoteridol [Gd-HP-DO3A]; Bracco Diagnostics Inc., Princeton NJ);

* Omniscan (gadodiamide [Gd-DTPA-BMA]; Amersham Health, Princeton, NJ);

* Optimark (gadoversetamide [Gd-DTPA-BMEA]; Mallinckrodt, St. Louis, MO);

* Dotarem (gadoterate meglumine [Gd-DOTA]; Guerbet, Aulnay-Sous-Bois, France); and

* Gadovist (gadobutrol [Gd-DO3A-butrol]; Schering AG).

These agents have a purely extracellular distribution and cross the BBB only when breakdown occurs. Despite different chemical structures and properties, these agents have similar R1 relaxivity values of approximately 5.0 mM ^-1 s ^{-1 106} and behave in a similar manner when used for contrast-enhanced MRI of the CNS.

Gadobenate dimeglumine (Gd-BOPTA, MultiHance) is a second-generation Gd agent. This agent resembles the above agents in terms of its pharmacokinetic profile and physicochemical properties but differs in that it possesses a two-fold greater R1 relaxivity (9.7 mM ^-1 s ^-1 ) deriving from a capacity for weak and transient interaction with serum albumin. ^106-108 Intra-individual crossover studies with first-generation chelates have shown that this greater relaxivity significantly improves both vascular enhancement ¹⁰⁹ and delineation of intra-axial enhancing lesions. ^110,111 Parrallel group studies comparing
Gd-BOPTA with conventional Gd agents have also demonstrated potential benefits of Gd-BOPTA in contrast enhancement. ^112-115

Future generations of MR contrast agents may include agents targeted to specific pathologies through the covalent labeling of monoclonal antibodies with Gd or other paramagnetic agents. Other innovative possibilities include agents that, upon attaching to receptors, open to expose Gd to water and cause T1 shortening. Such targeted agents would be expected to cause enhancement only when joined with the target. ¹¹⁶

CONCLUSION

MRI continues to evolve with increasing field strength, stronger and faster gradients, and more sophisticated RF subsystems and computers. This allows faster, higher resolution imaging and evaluation of processes at the molecular level, eg, diffusion and perfusion. Contrast agents continue to evolve from the first generation of extracellular agents to the latest Gd agents that are able to interact with proteins to achieve greater T1 relaxivity. Future contrast agents are likely to be targeted even more specifically to pathology. MR continues to be used to guide interventions from biopsies to brain tumor resections. In the future, MR will likely be used to guide stroke therapy, gene therapy, and minimally invasive brain tumor ablations using techniques, such as focused ultrasound, that do not even require the skin to be broken.

CME INFORMATION

This activity has been planned and implemented in accordance with the Essential Areas and Policies of the Accreditation Council for Continuing Medical Education (ACCME) through the joint sponsorship of the Institute for Advanced Medical Education and Anderson Publishing, Ltd. The Institute for Advanced Medical Education is accredited by the Accreditation Council for Continuing Medical Education (ACCME) to sponsor continuing medical education for physicians.

The Institute for Advanced Medical Education designates this continuing medical education activity for a maximum of 2 Category 1 credits toward the AMA Physician's Recognition Award. Each physician should claim only those credits that he/she actually spent in the activity.

See page 42 for instructions on how to participate in the program.

As of January 1, 2003, courses approved for AMA Category 1 CME credit that are relevant to the radiologic sciences are accepted for Category B CE credit on a one-to-one basis by the American Registry of Radiologic Technologists (ARRT).

In compliance with the Essentials and Standards of the ACCME, the authors of this CME tutorial are required to disclose any significant financial or other relationships they may have with the manufacturer(s) of any commercial product(s) or provider(s) of any commercial service(s) discussed in this program.

Dr. Baleriaux and Dr. Metens report no such relationships exist. Dr. Bradley discloses relationships with Bracco Diagnostics and Berlex Imaging through their speakers' bureaus and with GE Medical Systems and Siemens Medical Systems through research support.

To go directly to the quiz please click here