Introduction to the Pharmacology of CNS acting drugs.

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Presentation transcript:

Introduction to the Pharmacology of CNS acting drugs

CNS acting drugs are of major therapeutic and clinical importance. They can produce diverse physiological and psychological effects such as: Induction of Anesthesia Relief of Pain Prevention of Epileptic seizures Reduction of Anxiety Treatment of Parkinsonism Treatment of Alzheimer's disease Treatment of Depression Centrally acting drugs also include drugs that are administered without medical intervention like tea, coffee, nicotine, and opiates.

The CNS is a highly complex tissue that controls all of the body activities and serves as a processing center that links the body to the outside world. It is an assembly of interrelated “parts” and “systems” that regulate their own and each other’s activity. Structure of the CNS

1- Brain 2- Spinal cord The brain is formed of 3 main parts: I. The forebrain the cerebrum the thalamus the hypothalamus II. The midbrain III. The hindbrain the cerebellum the pons the medulla oblongata Structure of the CNS

Different Parts of the CNS & their functions The cerebrum (cerebral hemispheres): It constitutes the largest division of the brain. The outer layer of the cerebrum is known as the “cerebral cortex”.

The cerebral cortex is divided into different functional areas: 1. Motor areas (voluntary movements) 2. Sensory areas (sensation) 3. Association areas (higher mental activities as consciousness, memory, and behavior).

Deep in the cerebral hemispheres are located the “basal ganglia” which include the “corpus striatum” & “substantia nigra”. The basal ganglia play an important role in the control of “motor” activities.

The thalamus: It functions as a sensory integrating center for well-being and malaise. It receives the sensory impulses from all parts of the body and relays them to specific areas of the cerebral cortex.

The hypothalamus: It serves as a control center for the entire autonomic nervous system. It regulates blood pressure, body temperature, water balance, metabolism, and secretions of the anterior pituitary gland.

The mid-brain: It serves as a “bridge” area which connects the cerebrum to the cerebellum and pons. It is concerned with “motor coordination”.

The cerebellum: It plays an important role in maintaining the appropriate body posture & equilibrium. The pons: It bridges the cerebellum to the medulla oblongata. The “locus ceruleus” is one of the important areas of the pons.

The medulla oblongata: It serves as an organ of conduction for the passage of impulses between the brain and spinal cord. It contains important centers: cardioinhibitory vasomotor respiratory vomiting (chemoreceptor trigger zone, CTZ).

The spinal cord: It is a cylindrical mass of nerve cells that extends from the end of the medulla oblongata to the lower lumbar vertebrae. Impulses flow from and to the brain through descending and ascending tracts of the spinal cord.

Different Systems of the CNS & their functions These systems are pathways formed of specific parts of the brain and the neurons connecting them. They include: 1. The pyramidal system 2. The extrapyramidal system 3. The limbic system 4. The reticular formation 5. The tuberohypophyseal system

The pyramidal system: It originates from the motor area of the cerebral cortex and passes through the spinal cord, therefore it is also known as the “corticospinal tract”. It is responsible for the regulation of the fine voluntary movements.

The extrapyramidal system: It also controls the motor function but involves areas other than the corticospinal tract. It is involved in the regulation of gross voluntary movements, thus it complements the function of the pyramidal system. The “basal ganglia” constitute an essential part of this system. Degenerative changes in the pathway running from the “substantia nigra” to the “corpus striatum” (or nigrostriatal pathway) may cause tremors and muscle rigidity characteristic of “Parkinson’s disease”.

The limbic system: The major parts of this system are: the hypothalamus, the basal ganglia, the hippocampus (responsible for short term memory), and some cortical areas. The limbic system is involved in the control of “behavior” & “emotions”.

The reticular formation: It is composed of interlacing fibers and nerve cells that run in all directions beginning from the upper part of the spinal cord and extending upwards. It is important in the control of “consciousness” and “wakefulness”. The tuberohypophyseal system: It is a group of short neurons running from the hypothalamus to the hypophysis (pituitary gland) regulating its secretions.

Cells of the Nervous System 1- Neurons (Nerve Cells): function units of the nervous system by conducting nerve impulses, highly specialized and amitotic. Each has a cell body (soma), one or more dendrites, and a single axon. Cell Body: it has a nucleus with at least one nucleolus and many of the typical cytoplasmic organelles, but lacks centrioles for cell division. Dendrites: Dendrites and axons are cytoplasmic extensions (or processes), that project from the cell body. They are sometimes referred to as fibers. Dendrites (afferent processes) increase their surface area to receive signals from other neurons, and transmit impulses to the neuron cell body. Axon: There is only one axon (efferent process) that projects from each cell body. It carries impulses away from the cell body.

Cells of the Nervous System 2- Glial cells: do not conduct nerve impulses, but support, nourish, and protect the neurons. They are mitotic, and far more numerous than neurons. Astrocyte: A glial cell that provides support for neurons of the CNS, provides nutrients regulates the chemical composition of the extracellular fluid.

Cells of the Nervous System Oligodendrocyte: A type of glial cell in the CNS that forms myelin sheaths.

Cells of the Nervous System Microglia: The smallest glial cells; act as phagocytes (cleaning up debris) and protect the brain from invading microorganisms.

Cells of the Nervous System Schwann cell: A cell in the PNS that is wrapped around a myelinated axon, providing one segment of its myelin sheath.

Types of Neurons (Function) There are 3 general types of neurons (nerve cells): 1- Sensory (Afferent ) neuron: A neuron that detects changes in the external or internal environment and sends information about these changes to the CNS. (e.g: rods and cones, touch receptors). They usually have long dendrites and relatively short axons. 2- Motor (Efferent) neuron: A neuron located within the CNS that controls the contraction of a muscle or the secretion of a gland. They usually have short dendrites and long axons. 2- Interneuron or association neurons: A neuron located entirely within the CNS in which they form the connecting link between the afferent and efferent neurons. They have short dendrites and may have either a short or long axon.

Types of Neurons (Morphology) 1- Unipolar neuron: A neuron with one axon attached to its soma. the axon divides, with one branch receiving sensory information and sending the information into the CNS.

2- Bipolar neuron: A neuron with one axon and one dendrite attached to its soma.

3- Multipolar neuron: A neuron with one axon and many dendrites

Neuron Basic Structure (How brain cells communicate) Synapse: A junction between the terminal button of an axon and the membrane of another neuron Terminal button(or bouton): The bud at the end of a branch of an axon; forms synapses with another neuron; sends information to that neuron. Neurotransmitter: A chemical that is released by a terminal button; has an excitatory or inhibitory effect on another neuron.

Different types of Synapses 1- Axo-denrdritic 2- Axo-axonal 3- Axo-somatic

What happens at a synapse How Neurotransmitters work

Chemical transmission in the CNS The CNS controls the main functions of the body through the action endogenous chemical substances known as “neurotransmitters”. These neurotransmitters are stored in and secreted by neurons to “transmit” information to the postsynaptic sites producing either excitatory or inhibitory responses. Most centrally acting drugs exert their actions at the synaptic junctions by either affecting neurotransmitter synthesis, release, uptake, or by exerting direct agonist or antagonist action on postsynaptic sites.

Neurotransmitters can be classified into: 1. Biogenic amines: ACh, NA, DA, 5-HT, Histamine 2. Amino acids: Excitatory (glutamate & asparate) Inhibitory (GABA & glycine) 3. Others: Adenosine, melatonin

Acetylcholine - Acetylcholine is widely distributed in major parts of the CNS. Cholinergic neurons occur particularly in the motor areas of the cerebral cortex, the corpus striatum, the hippocampus, and the spinal cord. - Both types of Cholinergic receptors (nicotinic & muscarinic) occur in the CNS. -Muscarinic receptors (predominantly M 1 ) are much more abundant than nicotinic receptors and mediate many of the behavioral effects of acetylcholine in cholinergic pathways. -Muscarinic receptors are located presynaptically and upon stimulation by agonist inhibits Ach release, while muscarinic antagonists increase Ach release.

1- Arousal 2- Learning 3- Motor control 4- Short term memory - Loss of cholinergic neurons in the hippocampus (memory site) is associated with “Alzheimer’s disease (The most common neurodegenerative disease causing progressive irreversible dementia associated with old age. Acetylcholine in the brain plays a role in

Cholinergic drugs and Alzheimer's disease Reversible cholinesterase inhibitors: Tacrine, Donepezil and Galantamine. Pseudo-reversible cholinesterase inhibitors: Physostigmine, Eptastigmine and Rivastigmine. Irreversible cholinesterase inhibitors: Metrifonate

- Hyperactivity of cholinergic neurons in the corpus striatum leads to “Parkinson’s disease”. - Parkinsonism, is a progressive neurodegenerative brain disorder that was first described by Dr. James Parkinson in The disease occurs above the age of 65 and affects the "extrapyramidal system" at the level of the "corpus striatum" & "substantia nigra"

In the basal ganglia, the 2 neurotransmitters "dopamine" & "acetylcholine" co-exist in a normal balance, where dopaminergic neurons exert an inhibitory effect on excitatory cholinergic neurons. In Parkinson’s disease, the "nigrostriatal dopaminergic neurons" are degenerated (damaged) while cholinergic neurons are intact, resulting in a marked decrease in dopamine content (dopamine deficiency syndrome) and a relative predominance of cholinergic activity. DA ACh Therefore, the strategy for treatment of Parkinsonism is to restore the normal balance between dopaminergic & cholinergic tones in the basal ganglia.

Treatment of Parkinsonism TyrosineDOPADA MAO-B Dopaminergic Nerve terminal D2D2 D2D2 D2D2 D2D2 Postsynaptic receptors

Drugs used to treat Parkinsonism do not stop the progression of the disease but they can only ameliorate the symptoms. Parkinsonism could be managed by: A. Enhancing dopaminergic activity using: 1.drugs that replace dopamine (levodopa) 2.drugs that release dopamine from its stores (amantadine) 3.drugs that prolong the action of dopamine by preventing its metabolism (seligiline) 4.drugs that mimic the action of dopamine (dopaminergic agonists) B.Reducing cholinergic activity by the use of anticholinergic drugs (benzatropine) C.Neurotransplantation (which is still in experimental phase). D.Physical therapy & regular exercise.

Noradrenaline Noradrenergic neurons arise mainly from the “locus ceruleus” (in the pons) and the reticular formation and project diffusely to many areas of the brain. As in the periphery, the same types of adrenergic receptors are described in the CNS. Noradrenaline plays an important role in the regulation of both “arousal” and “mood”.

1- Mood: Deficiency of noradrenaline in certain parts of the brain is thought to be the underlying cause of “depression”. 2- Arousal: Increased release of noradrenaline in the brain is responsible for wakefulness and alertness. 3- Blood pressure regulation: In addition, noradrenergic synapses form a part of the baroreceptor reflex pathway that regulates blood pressure. Noradrenaline plays a role in

Dopamine Dopamine acts as both a “precursor” for noradrenaline by the action of the enzyme “dopamine β-hydroxylase” in noradrenergic neurons, as well as a “neurotransmitter” in dopaminergic neurons which lack this enzyme. Dopamine receptors are of 2 types: D 1 -type (including D 1 & D 5 subtypes) D 2 -type (including D 2, D 3, & D 4 subtypes) Both types are G-protein-coupled receptors that involve “adenylate cyclase/cAMP” as a signal transduction mechanism (D 1 -receptors activate, while D 2 -receptors inhibit adenylate cyclase).

Dopamine is the major neurotransmitter of the 3 following systems: 1.The nigrostriatal system 2.The mesolimbic system 3.The tuberohypophyseal system

1- Motor activity: In the nigrostriatal system, dopamine is involved in the control of motor function. Deficiency of dopamine in this system causes “Parkinson’s disease”. 2- Behavioural effects: In the mesolimbic system, dopamine is involved in the control of behavior and emotion. Increased dopaminergic activity in this system is believed to cause “schizophrenia”. Dopamine plays a role in

3- Anterior pituitary function: In the tuberohypophyseal system, dopamine inhibits the secretion of prolactin. Bromocriptine (dopaminergic agonist) is used clinically for this purpose. Dopamine stimulates the secretion of growth hormone from the pituitary gland in normal subjects, but inhibits its release in acromegaly, a condition in which bromocriptine is useful therapeutically if given before excessive growth has taken

4- Vomiting: Dopamine has a role in the production of “nausea & vomiting” by stimulating dopamine receptors in the chemoreceptor trigger zone (CTZ) in the medulla oblongata. Therefore, dopaminergic antagonists as Metoclopramide and phenothiazines have antiemetic properties. Dopaminergic agonists as Bromocriptine and levodopa cause nausea and vomiting as side-effects.

5-Hydroxytryptamine (5-HT) 5-HT is an important CNS transmitter although the brain accounts for only 1% of its total body content. 5-HT-containing neurons arise from nuclei in the pons and medulla known as the “raphe nuclei” and project diffusely to many areas of the brain similar to noradrenergic neurons. Formation and release of 5-HT is very similar to NA. Many drugs as TCA that inhibit NA uptake, also inhibit 5-HT uptake.

5-HT receptors 5-HT receptors in the CNS include 1- 5-HT1 receptors: located presynaptically and act to inhibit transmitter release. They includes 5 subtypes(5-HT1A,5-HT1B, 5-HT1C,5-HT1D, 5-HT1E) 2- 5-HT2 receptors: located post-synaptically and may exhibit excitatory or inhibitory functions. They includes 3 subtypes (5-HT2A, 5-HT2B, 5-HT2C) 3- 5-HT3 receptors. 5-HT pathways in the CNS are involved in behavioral changes, mood, hallucinations, sleep, wakefulness, and control of sensory transmission.

5-HT plays a role in 1- Mood: increasing 5-HT levels by giving tryptophan is useful in depressive states. 2- Sensory transmission: 5-HT inhibits transmission of pain impulses in the spinal cord and brain and enhances morphine analgesia. 3- Temperature control: the hypothalamus is rich in 5-HT containing neurons. Experimentally, injection of 5-HT in that region causes a rise in body temperature, while exposure to cold climates increases 5HT release. 4- Anterior pituitary function: The secretion of the hypothalamic releasing factors for certain anterior pituitary hormones as gonadotrophins is influenced by 5-HT containing neurons in the hypothalamus. 5- Vomiting: 5-HT3 blocker (ondansetrone) is used as anti-emetic.

Histamine is present in the brain in much smaller amounts than in other tissues (skin & lung). Histaminergic neurons arise from a small region in the hypothalamus and extend to the forebrain and midbrain. Histamine receptors in the brain include H 1, H 2, and H 3 -receptors, which are all G-protein coupled receptors. Histamine

The role of histamine in the CNS is minor and poorly understood. It is thought to function in the regulation of arousal, body temperature and vascular dynamics. Blocking central H 1 - receptors is associated with both sedative and antiemetic effects.

Excitatory amino acids (EAAs) are widely distributed in the CNS and have important metabolic and neurotransmitter roles. They include the dicarboxylic amino acids “glutamate” & “aspartate”. EAAs receptors (also known as glutamate receptors) are classified into: I. Ionotropic glutamate receptors. II. Metabotropic glutamate receptors. Excitatory amino acids (EAAs)

I. Ionotropic glutamate receptors: They are channel-linked receptors which include: NMDA (N-methyl D-aspartate) receptors AMPA (amino methyl propionic acid) receptors Kainate receptors II. Metabotropic glutamate receptors: They are G-protein coupled receptors which are linked to second messenger systems.

Glutamate & aspartate exert an extremely powerful excitatory effect on neurons in every region of the CNS. Therefore, glutamate antagonists could have a potential therapeutic role in the treatment of “epilepsy” & “schizophrenia” as well as reduction of “brain cell death” caused by excessive NMDA receptor activation.

Gamma amino butyric acid (GABA) GABA is an inhibitory neurotransmitter amino acid that is synthesized by decarboxylation of the excitatory amino acid, glutamate. It occurs only in brain tissues, and is abundant in the nigrostriatal system. GABA acts on 2 types of receptors: GABA A -receptors GABA B -receptors

GABA A -receptors: They are channel-linked receptors, which are stimulated by GABA leading to increased chloride permeability, hyperpolarization, and reduction of excitability. GABA B -receptors: They are G-protein-coupled receptors, which inhibit calcium channels and open potassium channels reducing excitability. GABA B receptors are stimulated by the GABA B selective agonist “baclofen” (used to treat spasticity and related motor disorders).

The GABA A receptor has 3 different sites that can be considered as the target of action of several important CNS drugs. 1. GABA-binding site (receptor site): It is stimulated by endogenous GABA or GABA agonists (e.g. muscimol) producing hyperpolarization, and blocked by GABA antagonists (e.g. bicuculline) producing convulsions. 2. Modulatory site (accessory site): It is also known as “benzodiazepine receptor”. Benzodiazepines, which have powerful anxiolytic and sedative effects, bind to this modulatory site to facilitate the binding and inhibitory action of GABA at the receptor site. 3. The chloride channel: It can be blocked by drugs producing convulsions (e.g. picrotoxin)

Glycine Glycine is an inhibitory amino acid which is present in high concentrations in the spinal cord. The spinal stimulant “strychnine” produces convulsions by competitive antagonism of the inhibitory response to glycine. In addition, “tetanus toxin” acts selectively to prevent glycine release from inhibitory neurons of the spinal cord causing excessive reflex hyperexcitability and violent muscle spasms.

Adenosine is a purine acting on A 1, A 2, and A 3 receptors (G-protein coupled). Adenosine is mainly inhibitory producing drowsiness, analgesia, and anticonvulsant activity. Therefore, synthetic adenosine agonists could be useful in treating sleep disturbance, pain, and epilepsy. On the other hand, xanthines, such as caffeine, produce arousal and alertness by acting as antagonists at the A 2 -receptors. Adenosine

Melatonin is a mediator that is synthesized from 5-HT in the pineal gland. Melatonin receptors are G-protein coupled, and are mainly found in the retina and brain. Melatonin secretion is controlled by an input from the retina to a structure in the hypothalamus termed as “the biological clock”. Melatonin secretion is high at night and low by day, therefore it is important in the regulation of “circadian rhythm”. Melatonin is medicinally used to control “jet-lag” and in improving the performance of night-shift workers. Melatonin

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