Intro to Neuroscience

Neuroscience Online38 minutes read

Neuroscience studies the brain's functions, including various disorders like Alzheimer's and Parkinson's, by examining neural circuits, neurotransmitters, and synaptic connections. Nerve cells' properties, resting potential, and integration of excitatory and inhibitory signals play a significant role in understanding neural communication and behaviors like locomotion through neural circuits.

Insights

  • Neuroscience integrates various scientific fields to study the brain's functions, emphasizing the importance of understanding individual neuron properties, connections, and neural circuits in neurological disorders like Alzheimer's, Parkinson's, and Schizophrenia.
  • Neurons communicate through excitatory and inhibitory connections, with the balance between EPSPs and IPSPs influencing action potential initiation, highlighting the significance of neural circuit motifs like feed-forward excitation and inhibition, lateral inhibition circuits, and feedback inhibition in regulating behaviors and information processing within the nervous system.

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Recent questions

  • What is neuroscience?

    Study of brain functions and disorders.

  • What are neurons?

    Cells transmitting information in the brain.

  • How do neurons communicate?

    Through electrical and chemical signals.

  • What is resting potential?

    Negative potential inside cells.

  • How do neural circuits work?

    By integrating excitatory and inhibitory signals.

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Summary

00:00

Neuroscience: Unraveling the Brain's Complexities

  • Neuroscience encompasses various disciplines like anatomy, biochemistry, physiology, and genetics to study the brain's normal and pathological functions.
  • The brain, with over 100 billion neurons, is incredibly complex, with each neuron having specific functions in different brain regions.
  • Neurons in the brain are highly interconnected, with each neuron capable of receiving and making thousands of connections to other neurons.
  • Major neurological disorders include Alzheimer's, Epilepsy, Huntington's Disease, Multiple Sclerosis, Myasthenia Gravis, Parkinson's Disease, Schizophrenia, and Stroke.
  • These disorders affect millions of individuals and involve genes, neuronal properties, neurotransmitter systems, and neural circuits.
  • Understanding the brain's functions and dysfunctions requires attention to individual neuron properties, connections, and neural circuits.
  • Neurons are polarized cells with distinct domains: cell body, dendrites for receiving connections, axon for transmitting information, and synapses for information transfer.
  • Synapses contain synaptic vesicles with neurotransmitter substances that induce changes in the postsynaptic neuron upon release.
  • Electrical signaling in nerve cells can be recorded using microelectrodes to understand the nervous system's functioning.
  • Studying the basic properties of nerve cells and neural circuits is crucial in comprehending brain function, setting the foundation for further exploration in neuroscience.

11:20

Monitoring Resting Potential and Action Potentials in Cells

  • An electrode is used to monitor electrical potential, with an oscilloscope being a suitable device for this purpose.
  • When the electrode is outside the cell, no potential is recorded due to the isopotential nature of the extracellular medium.
  • Inserting the electrode tip inside the cell results in a sharp deflection on the recording device, showing a potential of about -60 millivolts, indicating the resting potential.
  • Resting potential is a characteristic feature of all cells, including nerve cells, with a negative potential inside compared to the outside.
  • Nerve cells and muscle cells can change their resting potential to transmit and process information.
  • Nerve cells can be stimulated with a battery connected to an electrode, causing depolarization and the initiation of action potentials.
  • The size of the battery determines the magnitude of depolarization and the frequency of action potentials.
  • The principle of frequency coding in the nervous system states that the intensity of a stimulus correlates with the number of action potentials generated.
  • Neurons communicate through excitatory and inhibitory connections, with excitatory connections depolarizing the postsynaptic neuron towards threshold.
  • Inhibitory connections hyperpolarize the postsynaptic neuron, preventing it from reaching threshold and firing an action potential.

22:11

Neural Circuits: Excitatory and Inhibitory Integration

  • Membrane potential of postsynaptic cell becomes more negative at 22:05.
  • IPSP (Inhibitory PostSynaptic Potential) prevents action potentials in neuron.
  • EPSP (Excitatory PostSynaptic Potential) can lead to action potentials.
  • IPSPs reduce probability of action potential initiation.
  • Combination of excitatory and inhibitory input challenges the system.
  • Integration process involves IPSPs and EPSPs affecting firing probability.
  • Neurons can regulate each other's ability to drive postsynaptic neuron.
  • Common neural circuit motifs include feed-forward excitation and inhibition.
  • Convergence and divergence patterns in neural circuits are common.
  • Lateral inhibition circuit mediates edge enhancement phenomenon.

33:34

Neural Circuits: Light, Inhibition, and Rhythms

  • Light impinges on photoreceptors in the retina, activating them to initiate action potentials.
  • Photoreceptors connect to second-order neurons, transmitting information to the Central Nervous System.
  • Intensity of illumination affects the frequency of action potentials, with 5 lumens producing 5 Hertz and 10 lumens producing 10 Hertz.
  • Lateral inhibition occurs where retinal receptors inhibit adjacent neurons, affecting the perception of brightness at the edge.
  • Lateral inhibition leads to edge enhancement but can also cause visual illusions like Mach bands.
  • Feedback inhibition involves a nanonetwork that generates oscillatory behavior in neurons through calcium influx and buffering.
  • Feedback inhibition circuits can create short-term oscillations and underlie 24-hour rhythms like circadian rhythms.
  • The suprachiasmatic nucleus in the brain regulates circadian rhythms through a feedback inhibition circuit involving the gene per.
  • A simple circuit with inhibitory neurons can potentially explain quadrupedal locomotion patterns like walking, trotting, bounding, and galloping.
  • Understanding neural circuits that produce various animal gaits remains a complex area of study.

44:25

Neural circuits coordinate gallop movements effectively.

  • By setting up the timing of limb movements, specifically the hind limbs, in a specific phase relationship, a gallop could theoretically be produced, with the hind limbs following the front limbs half a cycle later.
  • To achieve this coordination, a circuit involving four bursting neurons can be utilized, allowing for the generation of different gallops through modifications in synaptic connections' strength.
  • The complexity of neural circuits, including micro and macro circuits, plays a crucial role in behaviors and information processing within the nervous system, with specific importance in memory mechanisms and visual information processing.
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