1 / 48

STATES OF CONSCIOUSNESS, SLEEP

STATES OF CONSCIOUSNESS, SLEEP. Olga Vajnerová Department of Physiology 2nd Medical School Charles University Prague. Consciousness 2 different concepts. 1. Wakefulness 2. Be aware of oneself = self-awareness (thoughts, perception, memories and feelings).

brant
Download Presentation

STATES OF CONSCIOUSNESS, SLEEP

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. STATES OF CONSCIOUSNESS, SLEEP Olga Vajnerová Department of Physiology 2nd Medical School Charles University Prague

  2. Consciousness2 different concepts 1. Wakefulness 2. Be aware of oneself = self-awareness (thoughts, perception, memories and feelings) Wakefulness – vigilance High level of vigilance = arousal Ability to orient appropriately to stimuli. Dependent on the activity of two cerebral hemispheres.

  3. States of consciousness Wakefulness – vigilance SleepAAS activity is decreased Activity of sleep centers is increased Can be waken up Unconsciousness - Generalized impairment of consciousness, diffuse dysfunction in both cerebral hemispheres Cannot be waken up

  4. EEG

  5. EEG Registration of electrical brain potentials measured form tha surface of the scull It reflects function properties of the brain Richard Caton 1875 – 1. Registration of ECoG and evoked potentials Hans Berger (Swiss psychiatrist) 1929 – human EEG, basic rhythm of electrical activity alfa (8-13Hz) and beta (14-30) After 1945 – EEG as a clinical inspection

  6. Elektroencephalograf Elektroencephalogram apparatus record (registration, paper)

  7. EEG activity is mostly rhytmic and of sinusoidal shape rhythm  14-30 Hz rhythm  8-13 Hz (quiet wakefulness) rhythm  4-7 Hz rhythm  3 and less Hz rhythm , rolandic rhythm 8-10 Hz

  8. Normal EEG – lokalization of graphoelement types Frontal -  activity Fist Unbend fingers parietal – , rolandic rhythm Temporal - , activity Eyes open Eyes closed Temporo-parieto- occipital -  activity Podle Faber Elektroencefalografie

  9. Ontogenesis EEG Until 1 year –  (1-3 Hz) not too regular, high amplitude, Is not blocked by eye opening Attenuation by opening eye is imperfect 1- 3 years - rhythm  (4-7 Hz) 3-5 let – more regular prealfa  (6-8 Hz) Is blocked by eye opening 5-7 let – regular  (8-13Hz) medial voltage, frontally  Very good reactivity

  10. Montage A standard set of placements for EEG electrodes

  11. Pyramidal neuron Apical dendrite

  12. Thalamocortical system (thalamic activity is rhytmic) Ascending arousal systém (AAS or RAS) pathways from brain stem RF to thalamus

  13. Thalamocortical modulation

  14. Evoked Potentials

  15. Average evoked potentials Event-related potentials Routine procedure of clinical EEG laboratories from 1980s Valuable tool for testing afferent functions EEG changes bind to sensory, motor or cognitive events

  16. Electrical activity – electrodes placed on the patient’s scalp • Evoked electrical activity appears against a background of spontaneous electrical activity. • Evoked activity = a signal • Background activity = a noise • Signal lower amplitude than noise, it may go undetected (hidden or masked by the noise) • Solution • - by increasing amplitude of the signal – intensity of stimulation • by reducing the amount of the noise

  17. How to reduce the amount of the noise • Superimposition

  18. How to reduce the amount of the noise Simplified diagram illustrating how coherent averaging enhances a low level signal (coherent = EP time locked to the evoking stimulus)

  19. Brain’s spontaneous electrical activity is random with respect to the signal – sum of many cycles will tend to cancel out. (to zero) The polarity of the EP will always be the same at any given point in time relative to the evoking stimulus Evoked activity will sum linearly

  20. Signal averaging Mixture of electrical activity composed of spontaneously generated voltages and the voltage evoked by stimulation Segments or epochs of equal duration Start coincides with the presentation of stimulus Duration varies from 10 to hundrets milliseconds

  21. Description of waveforms: peaks (positive deflection) troughs (negative deflection) Measures: 1. Latency of peaks and troughs from the time of stimulation 2. Time elapsing between peaks and/or troughs 3. Amplitude of peaks and troughs Comparison of the patient’s recorded waveforms with normative data

  22. Visual-evoked potentials (VEP) Stimulus: checkerboard pattern on a TV monitor The black and white squers are made to reverse A pattern-reversal rate – from 1to 10 per second Electrodes - 3 standard EEG electrodes placed over the occipital area and a reference elektrode in a midfrontal area Analysis time (one epoch) is 250 ms Number of trials 250 2 tests at least to ensure that the waveforms are replicable

  23. Normal VEP VEPs to pattern-reversal, full-field stimulation of the right eye

  24. Visual-evoked potentials (VEP) Electrical activity induced in visual cortex by light stimuli Retina Rods and Cones Anatomical basis of the VEP: Bipolar neurons Ganglion cells Anterior visual pathways Optic nerve Optic chiasm Optic tract Lateral geniculate body Retrochiasmal pathways Optic radiation Occipital lobe, visual cortex

  25. Abnormal VEPs Absence of a VEP Prolonged P 100 – latency - demyelination of the anterior visual pathways Amplitude attenuation - compressive lesions Prolonged P 100 only on left or right eye stimulation – lesion of the ipsilateral optic nerve Excessive interocular difference in P 100 latency – lesion of the ipsilateral optic nerve

  26. VEPs as a tool in the diagnosis of multiple sclerosis: Excessive interocular difference in P100 latency Prolonged absolute latency Decreased amplitude Compression of optic nerve, optic chiasm (tumor of pituitary gland or optic nerve glioma) Decreased amplitude Prolonged latency of P100

  27. Epileptic seizures are characterized by following disturbances: occur in attacks, abrupt onset usually accompanied by disturbances of consciousness usually accompanied by disturbances of motor and/or sensory functions and/or vegetative symptoms abnormal EEG recordings

  28. Seizures I. Partial (focal) a simple partial seizures (without alternation of consciousness) b complex partial seizures (with impairment of consciousness c comples partial seizures evolving to secondarily generalized seizures II. Generalized seizures (simultaneous disruption of normal brain activity in both hemispheres) (convulsive or noncolvulsive) a absence (petit mal) b tonic-clonic (grand mal)

  29. Typical epileptic grafoelements in EEG Eyes open Alpha activity Petit mal (absence) Spike and wave activity unconsciousness (coma) clonic Tonic phase Grand mal Temporal seizure = partial seizure with complex symptomatology Septo-hipocampal system Theta až delta aktivita Beta aktivita 15-20 Hz

  30. Epileptic seizure - grand mal This 40 year-old patient had epilepsy worsened by an inappriopriate change in his antiepileptic treatment. Seizure begins by a sudden scream with bilateral axial flexion with an internal rotation of both upper limbs. A slight non-forced rotation of head to the right is then followed by a clonic phase. A second tonic phase occurs 55 seconds after seizue onset, followed by bilateral clonic jerks, a stertorous breathe. Post-ictal headache and limb stiffness.

  31. Sleep

  32. Ascending arousal system Frederic Bremer (30. years of 20. century) Cerveau isolé (intercollicular midbrain transection between colliculi superiores and inferiores) uncosciouness, EEG of sleep type Encephal isolé (transection at C1) Sleep and wakefulness alternate

  33. Ascending arousal system– the most important conections 1. Reticular formation (in the brain stem) 2A. Non-specific thalamic nuclei: intralaminar, periventicular, reticular 2B. Subthalamus a hypothalamus 3. Cerebral cortex (all regions, divergention)

  34. Vigility Reticular ascenden system RAS Talamocortical synchronization is disturbed Sleep activity of RAS decreased talamocortikcal synchronizaction activity of sleep centers

  35. Arousal reaction • Sensory signal – all sensory fibers project collaterals to RF and activate AAS • Limbic system – alert under the influence of emotions

  36. Sleep The age-old explanation until 1940s – sleep is simply a state of reduced activity Nathaniel Kleitman in early 1950s made remarkable discovery: Sleep is not a single process, it has two distinct phases: REM sleep (paradoxical) is characterized by Rapid Eye Movements Non-REM sleep (slow-wave sleep) Sleep is an actively induced and highly organized brain state with different phases

  37. Brain correlates of sleep Non-REM nuclei raphe (serotonin) ncl. tractus solitarii cholinergic neurons of RF (pons, mesencefalon) ncl. reticularis thalami REM nucleus reticularis pontis oralis, (nucleus of RF at the junction of the pons a midbrain), (higher activity during REM sleep, its destruction eliminates REM sleep)

  38. Charakteristic of non-REM • Skeletal muscles – relaxed • Parasympaticus predominate –heart rate, preassure, motility of GIT, breathing • Dreams – usually no • Humans are more difficult to awaken in 4. stage • Charakteristic of REM • Skeletal muscles – loss of tone except eye and breathing muscles • Sympaticus predominate – heart rate, preassure, motility of GIT, breathing, erection in men • Dreams – are frequent • EEG remind wakefulness – for this reason paradoxical

  39. 4 stages of non-REM sleep EEG 1. Slight slowing of EEG Alfa changes into theta EEG 2. Theta activity a grafoelements: K-complex and sleep spindle EEG 3. Delta activity (slow high-amplitude waves) more than 20% 4. Delta activity more than 50% EMG EOG REM – paradoxical sleep Eye movements, loss of muscle tone EEG EMG EOG Podle Faber – materiály k PhD

  40. Hypnogram Extensity REM = duration Intensity REM = fruitfulness (eye movements, jerks) Selectiv deprivation = REM sleep is blocked Next night rebound efect Aggressivenes, memory, hypersexuality, polyphagia REM is related to psychological activity Non REM to physical

  41. Polysomnography

  42. Sleep in phylogenesis and ontogenesis From 30. week of gravidity – REM Newborn – REM 50% Preschool age – REM 30% Adults – REM 20% Fish – no sleep Reptiles – begining of non REM Birds – beginning of REM Mammalian – developed non REM – REM cyklus In phylogenesis there is non REM first In ontogenesis there is REM first

  43. Sleep follows a circadian rhythm about 24 hours Circadian rhythms are endogenous – persist without enviromental cues – pacemaker, internal clock – suprachiasmatic ncl. hypothalamus Under normal circumstances are modulated by external timing cues – sunlight – retinohypothalamic tract from retina to hypothalamus (independent on vision) Resetting of the pacemaker Lesion or damage of the suprachiasmatic ncl. – animal sleep in both light and dark period but the total amount of sleep is the same suprachiasmatic ncl. regulates the timing of sleep but it si not responsible for sleep itself

  44. Thank you for your attention?

More Related