Water content and water structure in CT and MR signal changes: possible influence in detection of early stroke.

Recent work by the authors and others has shown that MR imaging is more sensitive than CT in the detection of acute stroke. To separate the effects of water content and water structure on MR signal intensity, we undertook two sets of experiments that used simple model systems: gelatin gels with increasing water content and hardened hens' eggs. CT and MR were performed on both systems. On CT there was a direct linear relationship between CT attenuation (Hounsfield units) and the specific gravity of the gelatin gels, and an inverse relationship with water content. There was only a minimal change in the specific gravity of egg samples with hardening and, as expected on CT, no change in linear attenuation accompanying hardening. On MR there was a linear relationship between water content in gelatin gels and spin-lattice (T1) relaxation time (r = .92, p less than .01) and spin-spin (T2) relaxation time (r = .91, p less than .05). However, these changes were insufficient to explain the changes of signal intensity that occur in the brain with infarction. The simple cellular system with hens' eggs demonstrated that shortening of T1 and T2 accompanied egg hardening with minimal change in water content; the shift of water from bulk water to a bound or structured form was probably the basis of this phenomenon. We found that water structure and not merely water content is a significant mechanism underlying relaxation time changes and signal intensity changes in acute stroke.

[1]  M. Gado,et al.  Acute cerebral infarction in monkeys: an experimental study using MR imaging. , 1987, Radiology.

[2]  G. Fullerton,et al.  Characterization of water in unfertilized and fertilized sea urchin eggs , 1986, Journal of cellular physiology.

[3]  G D Fullerton,et al.  An evaluation of the hydration of lysozyme by an NMR titration method. , 1986, Biochimica et biophysica acta.

[4]  M Brant-Zawadzki,et al.  MR imaging of acute experimental ischemia in cats. , 1986, AJNR. American journal of neuroradiology.

[5]  M. Modic,et al.  Magnetic resonance with marked T2-weighted images: improved demonstration of brain lesions, tumor, and edema. , 1985, AJR. American journal of roentgenology.

[6]  F. Jolesz,et al.  Comparison of I-123 IMP cerebral uptake and MR spectroscopy following experimental carotid occlusion. , 1985, Investigative radiology.

[7]  A. Kertesz,et al.  Role of NMR in diagnosis and evaluation of stroke: 303 studies of 152 patients , 1985 .

[8]  R. Kurland,et al.  Magnetic resonance of brain tumors: considerations of imaging contrast on the basis of relaxation measurements. , 1985, Magnetic resonance imaging.

[9]  G D Fullerton,et al.  Frequency dependence of magnetic resonance spin-lattice relaxation of protons in biological materials. , 1984, Radiology.

[10]  M Brant-Zawadzki,et al.  Cerebral abnormalities: use of calculated T1 and T2 magnetic resonance images for diagnosis. , 1984, Radiology.

[11]  J. Ford,et al.  Nuclear magnetic resonance evaluation of stroke. A preliminary report. , 1983, Radiology.

[12]  M. Kaste,et al.  Serial Nuclear Magnetic Resonance (NMR) Imaging in Patients with Cerebral Infarction , 1983, Journal of computer assisted tomography.

[13]  L. Crooks,et al.  Proton nuclear magnetic resonance imaging of acute experimental cerebral ischemia. , 1983, Investigative radiology.

[14]  R. Bryan,et al.  NMR evaluation of stroke in the rat. , 1983, AJNR. American journal of neuroradiology.

[15]  I. Mano,et al.  NMR imaging of acute experimental cerebral ischemia: time course and pharmacologic manipulations. , 1983, AJNR. American journal of neuroradiology.

[16]  F. Buonanno,et al.  Proton NMR imaging in experimental ischemic infarction. , 1983, Stroke.

[17]  H. Handa,et al.  Chronological sequences and blood‐brain barrier permeability changes in local injury as assessed by nuclear magnetic resonance (NMR) images from sliced rat brain. , 1983, Stroke.

[18]  P. T. Beall,et al.  States of water in biological systems. , 1982, Cryobiology.

[19]  C. Tanaka,et al.  Proton nuclear magnetic resonance studies on brain edema. , 1982, Journal of neurosurgery.

[20]  Thomas J. Brady,et al.  Cranial anatomy and detection of ischemic stroke in the cat by nuclear magnetic resonance imaging , 1982 .

[21]  U. Ito,et al.  Brain Edema During Ischemia and After Restoration of Blood Flow Measurement of Water, Sodium, Potassium Content and Plasma Protein Permeability , 1979, Stroke.

[22]  M. Gado,et al.  CORRELATIVE ASSAY OF COMPUTERIZED CRANIAL TOMOGRAPHY (CCT), WATER CONTENT AND SPECIFIC GRAVITY IN NORMAL AND PATHOLOGICAL POSTMORTEM BRAIN , 1976, Journal of neuropathology and experimental neurology.

[23]  M E Phelps,et al.  Correlation of effective atomic number and electron density with attenuation coefficients measured with polychromatic x rays. , 1975, Radiology.

[24]  H. T. Edzes,et al.  Water in brain edema. Observations by the pulsed nuclear magnetic resonance technique. , 1975, Archives of neurology.

[25]  W. Inch,et al.  Spin-lattice relaxation times for mixtures of water and gelatin or cotton, compared with normal and malignant tissue. , 1974, Journal of the National Cancer Institute.