The efficacy and clinical impact of brain imaging in neurologically symptomatic AIDS patients: a prospective CT/MRI study.

The relative efficacies of cranial magnetic resonance imaging (MRI) and computed tomography (CT) brain scans for the detection of intracranial pathology in patients with the acquired immune deficiency syndrome (AIDS) were evaluated prospectively. Fifty homosexual or bisexual men with AIDS and neurologic symptoms were evaluated using both modalities. In 24 patients, MR images and CT scans provided the same diagnostic information (within normal limits in 16, cerebral atrophy only in 6, and similar lesions in 2 patients). In only one instance did CT show the presence of a lesion not seen on MRI. In the 25 remaining patients, MRI was the more sensitive modality. MRI also reflected more consistently the histopathologically documented extent and distribution of central nervous system disease. The greater sensitivity of MRI suggested significant alterations in the diagnostic evaluation and therapeutic management of 20 patients. Thus, MRI was as good or better than CT for the detection of intracranial pathology in 49 of 50 neurologically symptomatic AIDS patients and significantly affected the diagnosis and treatment of 40% of these patients. Although MRI does not appear to be more specific than other modalities in the differentiation of human immunodeficiency virus (HIV)-related neurologic diseases, its greater sensitivity suggests that MRI may be the best neuroimaging procedure for the initial radiologic evaluation of AIDS patients with neurologic illness.

Air embolism complicating percutaneous thin needle biopsy of lung.

Percutaneous thin needle biopsy, a widely used method for diagnosis of lung conditions, is generally safe and effective. A near-fatal air embolism is reported that occurred during percutaneous thin needle aspiration biopsy of the lung. Successful treatment was accomplished by hyperbaric oxygen therapy. Physicians should be aware of this possible complication and identify the location of the nearest chamber for possible transfer.

The value of relaxation times and density measurements in clinical MRI.

The hope that MRI relaxation time signatures would identify tissues, specifically, malignancies, has not been realized. This is due much less to measurement inaccuracies than to a large intrinsic variability and overlaps between malignancies and many benign pathologies. Neither has there been success in predicting relaxation times from basic tissue compositions. Nevertheless, MRI provides a qualitative measure of tissue hydration, and of flow, on the basis of relaxation times. Furthermore, pixel-by-pixel maps of relaxation times have proven useful in understanding the MRI process, in predicting the efficacy of untried techniques, and replace, in many circumstances, the need for acquisition of images with diverse sequencing parameters.

Hydrogen MR imaging of the head at 0.35 T and 0.7 T: effects of magnetic field strength.

To determine whether hydrogen magnetic resonance imaging at 0.7 T provides added clinical value over imaging at 0.35 T, images of the heads of patients with various intracranial disorders were obtained at these field strengths. Measurements of tissue contrast (C), signal-to-noise (S/N) ratio, and T1 and T2 relaxation times were determined. For a given spin-echo sequence with equal imaging time, resolution, and data sampling window, the product C X S/N was somewhat lower for the lower field strength. Under conditions of imaging with equal chemical shift artifact, C X S/N at 0.35 T was equal to or greater than that measured at 0.7 T. With an increase in field strength, T1 of pathologic areas and surrounding normal tissues increased, resulting in a corresponding loss of absolute signal level and decrease in contrast. Lesions were equally well seen at both 0.35 T and 0.7 T. The increased T1 and decreased C X S/N for higher magnetic fields--when measured with a fixed imaging time, resolution, chemical shift, and sequence--suggest that such field strengths may not improve tissue contrast, diagnostic ability, or clinical throughput when compared with lower field strength systems.

Magnetic resonance imaging performance: a comparison of sodium and hydrogen.

Although many nuclei can be used to produce magnetic resonance (MR) images, technical considerations dictate the choice of certain of these. Hydrogen is the most favorable, followed by sodium. We present an evaluation of the imaging performance of sodium MR imaging based on imager performance and biologic factors. Because it is hampered by high operating fields, low signal-to-noise levels, and radiofrequency power deposition constraints, careful clinical comparisons will be needed to identify a diagnostic niche that could take advantage of the large sodium differences known to exist within biologic systems.

Variable magnetic resonance imaging parameters: effect on detection and characterization of lesions.

With change in the imaging technique and magnetic field strength used in magnetic resonance imaging, wide variations in the delineation of pathologic features occur. Using imaging data from patients with known pathologic conditions, we evaluated the intensity images in spin-echo and inversion-recovery imaging at varying repetition times, echo times, and inversion times over broad ranges and changing magnetic field strengths. Differences in conspicuity and the apparent size of the lesions are important to consider in diagnosing and evaluating pathologic conditions, especially when different imagers and techniques are employed.

Multiple spin-echo magnetic resonance imaging.

Spin-echo magnetic resonance (MR) imaging detects a variety of pathologic states with great sensitivity. A technique for producing multiple spin-echo images in multisection operation is presented. This method of intensity-image acquisition is compared with retrospective intensity-image synthesis from routine data sets. Both yield long echo time (TE) images with similar image contrast and comparable and often increased diagnostic utility. Technical and clinical considerations are addressed, including signal-to-noise levels, flow effects, and patient throughput.