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  • Book
    Xuefeng Wang, Feng Li, Suyue Pan, editors.
    Summary: This book provides practical information on applications of multi-modal EEG monitoring in patients with severely neurologically diseases. The First part systematically introduces the modern EEG techniques, and multi-modal EEG monitoring system for severe neurological illness. In the second part, identification of EEG artifacts and interpretation of common abnormal EEG patterns is presented. Accompanying more than 50 typical cases and 200 EEG records, the following chapters discusses EEG's changes and clinical significance in coma, ischemic-hypoxic encephalopathy, status epilepsy, Creutzfeldt-Jakob disease, traumatic brain injury, and other diseases in details. In addition, application of multi-modal EEG in monitoring intracranial pressure and predicting suicide risk is also included. It will be a valuable reference for professionals in neurology, neurosurgery, emergency care, psychiatry, technology specialists of EEG and senior nurses with basic EEG monitoring knowledge.

    Contents:
    Part 1 Electroencephalogram (EEG) Basis and quantitative Electroencephalogram (qEEG) Technology
    1 Basic theory of EEG
    2 qEEG monitoring system in severely ill patients
    Part 2 Interpretation and clinical significance of abnormal EEG in severely ill patients
    3 Common abnormal EEG in neurocrital ill patients
    4 Abnormal EEG background activity
    5 Patterns and clinical significance of abnormal sleep EEG
    Part 3 Application of multimodal EEG in severely ill patients
    6 Application of multimodal EEG in coma patients
    7 Application of multimodal EEG in HIE
    8 Application of multimodal EEG in SE
    9 Clinical application of multimodal EEG in acute ischemic stroke
    10 Application of multimodal EEG in TBI.-11 Application of multimodal EEG in AE
    12 Application of multimodal EEG in ICP monitoring
    13 Application of multimodal EEG in sedation and analgesia
    14 Application of multimodal EEG in predicting the risk of suicide
    15 Application of multimodal EEG in the determination of brain death
    16 Application of the BIS in the ICU
    17 Application of aEEG in severely ill patients.
    Digital Access Springer 2022
  • Article
    Dietzel I, Kolb V, Boos W.
    Arch Microbiol. 1978 Aug 01;118(2):207-18.
    After induction with maltose, 30--40% of the total protein in the osmotic shock fluid consist of maltose-binding protein while the induction ratio (maltose versus glycerol grown cells) for the amount of binding protein synthesized as well as for maltose transport is in the order of 10. Induction of maltose transport does not occur during all times of the cell cycle, but only shortly before cell division. Electronmicroscopic analysis of cells grown logarithmically on glycerol or maltose revealed in the latter the formation of large pole caps. These pole caps arise from an enlargement of the periplasmic space. Small cells contain one pole cap, large cells contain two. Pulse label studies with strain BUG-6, a mutant that is temperature sensitive for cell division reveal the following: Growth at the non-permissive temperature prevents maltose-binding protein synthesis and formation of new transport capacity. After shifting to the permissive temperature the cells regain both functions. Simultaneously, the newly formed cells exhibit pole caps. We conclude that the induction of maltose-binding protein is responsible for the formation of pole caps. In addition, beside the presence of inducer, cell cycle events occuring during division are necessary for the synthesis of maltose-binding protein.
    Digital Access Access Options