Скачать книгу

for materials characterization with MR [39,40] but also considered for biological applications [41–43] and using remarkably inexpensive components [44]. Single-sided spectrometers have also been introduced for assessing breast tissue [45,46] and muscle hydration [47,48]. Single-sided full-imaging systems are less common, but have been demonstrated [49] and applied to burn depth [50].

      Figure 3.3 Single-sided brain magnetic resonance imaging under development for monitoring applications in the emergency department or intensive care unit. The <7 kg Halbach sphere-section magnet generates ~80 mT in a subregion of the brain.

      3.4 Clinical Use Scenarios of “Easy-to-Site” POC, and Monitoring MR Devices

      3.4.1 ED and ICU

      Neuroimaging in emergency medicine often focuses on immediately ruling out or identifying a source of increased ICP from hemorrhage, stroke, hydrocephalus (enlargement of the ventricles), or cerebral mass effect (displacement of brain tissue by blood or tumor or following trauma). This is currently done in the ED using CT scanners, which are fast, relatively cheap, and easy to site compared with MRI. The addition of POC MRI would be helpful for assessment of neurological emergencies for which CT provides a poor depiction or for patient populations sensitive to the ionizing radiation used in CT.

      3.4.2 Acute Stroke Care

      3.4.3 Assessing Pediatric Hydrocephalus in the Developing World

      Figure 3.4 A low-cost, lightweight scanner under development for pediatric hydrocephalus monitoring. The system uses a rare-earth permanent magnet “Halbach” arrangement producing a 50-mT transverse field. Magnet bore is 27 cm diameter × 50 cm length.

      3.4.3 Mass-effect Monitor in ED or ICU Setting

Скачать книгу