knowt logoknowt logo
HomeExploreExamsBlog
knowt logoKnowt
Rating
4.0(1)
Exam Icon
Take a practice test
Flashcard Icon
undefined Flashcards
0.0(0)

Studied by 0 people

Tags
Explore Top Notes
Chapter 6: Fertility
noteNote
studied byStudied by 4 people
5.0 Stars(1)
Anatomy and Physiology 'Blood'
noteNote
studied byStudied by 98 people
4.0 Stars(2)
Biology 2201 Unit 2
noteNote
studied byStudied by 11 people
5.0 Stars(1)
Chapter 6 - Harmonic Organization 2: Chords in Diatonic Contex
noteNote
studied byStudied by 14 people
5.0 Stars(1)
Chapter 2: States
noteNote
studied byStudied by 6 people
5.0 Stars(1)
Unit 2 - Supply and Demand Guide
noteNote
studied byStudied by 1698 people
5.0 Stars(3)
knowt logo

Chapter 12: Degenerative Disorders

In this Chapter…

  • Alzheimer’s Disease

  • Amyotrophic Lateral Sclerosis (ALS)

  • Huntington’s Disease

  • Parkinson’s Disease

Alzheimer’s Disease

  • Earliest symptoms of Alzheimer’s disease include:

    • Forgetfulness

    • Disorientation as to time or place

    • Difficulty with:

      • Concentration

      • Calculations

      • Language

      • Judgment

  • As the disease progresses, severe behavioral disturbances can occur

    • The individual may even become psychotic

  • The individual also becomes incapable of self-care and bedridden in the final stages

    • Usually death occurs from pneumonia or another complication of immobility

  • A diagnosis of possible Alzheimer’s disease can be made with less than 80% accuracy in earliest stages

    • As the disease progresses, the accuracy of the diagnosis exceeds 90%

  • The diagnosis depends on

    • Medical history

    • Physical & neurological examinations

    • Psychological testing

    • Lab tests

    • Brain imaging studies

      • New brain imaging strategies show promise in enabling doctors to visualize Alzheimer’s

    • The final confirmation of the diagnosis requires examination of brain tissue

      • The brain tissue is usually obtained through an autopsy

  • The causes and mechanisms for brain abnormalities in Alzheimer’s disease are still not fully understood

  • Reductions occur in the markers for many neurotransmitters that allow cells to communicate with others

    • These neurotransmitters inlcude acetylcholine, somatostatin, monoamine neurotransmitters, and glutamate

  • The damage to neural systems for attention, memory, learning, and higher cognitive abilities are believed to cause clinical symptoms

    • Brain tissue of deceased Alzheimer’s patients shows abnormal accumulations of beta-amyloid

      • Beta-amyloid: a small fibrillar peptide that accumulates in the spaces around synapses in Alzheimer’s patients

        • These accumulations are called neuritic plaques

    • Neurofibrillary tangles: a modified, aggregated form of the protein tau in the cell bodies of neurons

    • Neuritic plaques and neurofibrillary tangles form in brain regions important for memory and intellectual function

    • A mildly radioactive chemical marker can show amyloid plaques and tau tangles in living people

  • Early-onset Alzheimer’s: a rare, dominantly inherited disorder that causes the onset of Alzheimer’s in an individual’s 40s or 50s instead of past 65

    • The gene encoding the Amyloid Precursor Protein (APP) is on Chromosome 21

    • Early-onset Alzheimer’s is related to mutations in the genes for presenilin 1 and 2

      • Presenilin 1 and 2 are proteins involved in the process of generating beta-amyloid from APP

    • Genes for Early-onset Alzheimer’s causes the beta-amyloid plaques to accumulate earlier

  • Apolipoprotein E (ApoE): influences one’s susceptibility to Alzheimer’s disease later in life

    • Exists in 3 forms

    • The epsilon 4 form of ApoE is most clearly associated with increased risk for Alzheimer’s disease

Latest Research and Treatments

  • Current treatments do not modify the course of the disease

    • They only offer temporary mitigation of some symptoms including agitation, anxiety, unpredictable behavior, sleep disturbances, and depression

    • 4 of the current treatments prevent the breakdown of acetylcholine

      • The last available one regulates glutamate

  • Mice carrying mutant genes develop abnormalities and some of the microscopic changes in tissue structure that occur in humans

    • Mice models don’t work for all diseases

  • Beta and gamma secretases: enzymes that cut the amyloid peptide and release it from neurons into the space around synapses

  • Alpha secretases: break up beta-amyloid peptides and prevent amyloid accumulation

  • Anti-amyloid therapies aim to remove existing beta-amyloid or decrease the production of new beta-amyloid

  • Cognitive activity, physical activity, and heart-healthy diets all lower the risk for Alzheimer’s disease

    • Obesity, high blood pressure, high cholesterol, metabolic syndrome, and diabetes raise the risk

Amyotrophic Lateral Sclerosis (ALS)

  • ALS is also called Lou Gehrig’s disease

  • ALS affects neurons that control voluntary muscle movements

    • Motor neurons in the brain and spinal cord begin to disintegrate

    • The muscles weaken and deteriorate from lack of stimulation

  • The first signs of progressive paralysis are seen in the hands and feet or in muscles of speech and swallowing

  • Early symptoms include:

    • Weakness in legs

    • Difficulty walking

    • Clumsiness of hands when washing and dressing

    • Slurred speech

  • Almost all the muscles under voluntary control are affected

    • However, the mind and senses are still intact

  • Death is usually caused by respiratory failure or pneumonia

  • Over 90% of ALS is sporadic

    • Potential causes include:

      • An excess amount of glutamate

      • Oxygen in a dangerous form (oxidative distress)

      • Environmental factors

      • Autoimmune response

  • The other 5-10% of ALS is familial and linked to a genetic defect

    • A mutation in the gene that codes for the enzyme superoxide dismutase might be a cause of ALS

Huntington’s Disease (HD)

  • The disease slowly progresses over a 10 to 20 year period

    • HD doesn’t allow the individual to walk, think, talk, and reason

  • Symptoms start between 30 and 50 years of age

  • HD Affects basal ganglia and cerebral cortex

  • Initial symptoms include:

    • Involuntary jerking of limbs, torso, facial muscles

    • Mood swings

    • Depression

    • Irritability

    • Slurred speech

    • Clumsiness

  • Symptoms as the disease progresses

    • Difficulty swallowing

    • Unsteady gait

    • Loss of balance

    • Impaired reasoning

    • Memory problems

  • Death can occur by pneumonia, heart failure, or other complications

  • Diagnosis of HD is made by a detailed clinical exam and examining the family history

    • Predictive testing is only for adults

    • Children under the age of 18 may be tested to confirm the diagnosis of juvenile-onset Huntington’s

  • The mutation for HD is an expanded triplet repeat

    • Essentially, a sequence is repeated is repeated more often than needed

      • This abnormal gene codes for an abnormal version of a protein called huntingtin

        • The normal function of this protein is still unknown

      • This protein is widely distributed in the brain and appears to be associated with proteins involved in transcription

        • HD may be caused by the gain of a new and toxic function among these proteins

Parkinson’s Disease

  • Individuals with Parkinson’s disease only start showing symptoms over the age of 50

    • Age is the only known risk factor for the development of the disorder

  • Parkinson’s disease is characterized by:

    • Slowness of movement

    • Muscular rigidity

    • Walking

    • Balance impairment

    • Many patients develop resting tremors as well

  • It may also cause changes in non-motor functions of the brain

  • Parkinson’s disease is caused by the loss of dopamine-producing cells of the substantia nigra pars compacta in the midbrain

    • 40% of these cells must be lost before symptoms occur

      • This suggests that the brain has a way of temporarily warding off symptoms

  • Continued loss of cells leads to reaching the threshold where the brain can no longer recover

  • It is believed that both genetic and environmental factors contribute to the injury and loss of cells in Parkinson’s disease

  • Cases of early-onset Parkinson’s disease may be inherited

Treatment Breakthroughs and the need for more research

  • Levodopa: a drug discovered in the 1960s that is converted to dopamine in the brain

  • Other drugs either boost the effect of dopamine by inhibiting breakdown or extend the length of dopamine-like effects

    • This is because of their ability to bind and act on similar brain regions for longer periods of time

    • One example of this is the use of carbidopa with levodopa

      • Carbidopa helps prevent the breakdown of levodopa in the bloodstream

  • Dopamine replacement therapy doesn’t cure the disease or slow its progression

    • It is not optimal for treating non-motor aspects of disease

    • It also becomes less effective over time

  • MPTP (1-methyl-4-phenyl-1,2,3,6 tetrahydropyridine) was accidentally discovered by drug synthesizers in the late 1970’s

    • Drug addicts who injected MPTP-contaminated drugs developed Parkinson’s

    • MPTP is converted to a substance in the brain that destroys dopamine-producing neurons

    • Specific regions in the basal ganglia become abnormally active

  • Pallidotomy: surgical deactivation or destruction of overactive structures that greatly reduces symptoms

    • The structures that are operated on are the pallidum and subthalamic nucleus

  • Other treatments include

    • Chronic deep-brain stimulation

    • Replacement therapy using stem cells is being tried

    • Gene transfer of trophic factors is being studied in animal models and tested in clinical trials

AA
Home
Home
Science
Science
Biology
BiologyOther

Chapter 12: Degenerative Disorders

In this Chapter…

  • Alzheimer’s Disease

  • Amyotrophic Lateral Sclerosis (ALS)

  • Huntington’s Disease

  • Parkinson’s Disease

Alzheimer’s Disease

  • Earliest symptoms of Alzheimer’s disease include:

    • Forgetfulness

    • Disorientation as to time or place

    • Difficulty with:

      • Concentration

      • Calculations

      • Language

      • Judgment

  • As the disease progresses, severe behavioral disturbances can occur

    • The individual may even become psychotic

  • The individual also becomes incapable of self-care and bedridden in the final stages

    • Usually death occurs from pneumonia or another complication of immobility

  • A diagnosis of possible Alzheimer’s disease can be made with less than 80% accuracy in earliest stages

    • As the disease progresses, the accuracy of the diagnosis exceeds 90%

  • The diagnosis depends on

    • Medical history

    • Physical & neurological examinations

    • Psychological testing

    • Lab tests

    • Brain imaging studies

      • New brain imaging strategies show promise in enabling doctors to visualize Alzheimer’s

    • The final confirmation of the diagnosis requires examination of brain tissue

      • The brain tissue is usually obtained through an autopsy

  • The causes and mechanisms for brain abnormalities in Alzheimer’s disease are still not fully understood

  • Reductions occur in the markers for many neurotransmitters that allow cells to communicate with others

    • These neurotransmitters inlcude acetylcholine, somatostatin, monoamine neurotransmitters, and glutamate

  • The damage to neural systems for attention, memory, learning, and higher cognitive abilities are believed to cause clinical symptoms

    • Brain tissue of deceased Alzheimer’s patients shows abnormal accumulations of beta-amyloid

      • Beta-amyloid: a small fibrillar peptide that accumulates in the spaces around synapses in Alzheimer’s patients

        • These accumulations are called neuritic plaques

    • Neurofibrillary tangles: a modified, aggregated form of the protein tau in the cell bodies of neurons

    • Neuritic plaques and neurofibrillary tangles form in brain regions important for memory and intellectual function

    • A mildly radioactive chemical marker can show amyloid plaques and tau tangles in living people

  • Early-onset Alzheimer’s: a rare, dominantly inherited disorder that causes the onset of Alzheimer’s in an individual’s 40s or 50s instead of past 65

    • The gene encoding the Amyloid Precursor Protein (APP) is on Chromosome 21

    • Early-onset Alzheimer’s is related to mutations in the genes for presenilin 1 and 2

      • Presenilin 1 and 2 are proteins involved in the process of generating beta-amyloid from APP

    • Genes for Early-onset Alzheimer’s causes the beta-amyloid plaques to accumulate earlier

  • Apolipoprotein E (ApoE): influences one’s susceptibility to Alzheimer’s disease later in life

    • Exists in 3 forms

    • The epsilon 4 form of ApoE is most clearly associated with increased risk for Alzheimer’s disease

Latest Research and Treatments

  • Current treatments do not modify the course of the disease

    • They only offer temporary mitigation of some symptoms including agitation, anxiety, unpredictable behavior, sleep disturbances, and depression

    • 4 of the current treatments prevent the breakdown of acetylcholine

      • The last available one regulates glutamate

  • Mice carrying mutant genes develop abnormalities and some of the microscopic changes in tissue structure that occur in humans

    • Mice models don’t work for all diseases

  • Beta and gamma secretases: enzymes that cut the amyloid peptide and release it from neurons into the space around synapses

  • Alpha secretases: break up beta-amyloid peptides and prevent amyloid accumulation

  • Anti-amyloid therapies aim to remove existing beta-amyloid or decrease the production of new beta-amyloid

  • Cognitive activity, physical activity, and heart-healthy diets all lower the risk for Alzheimer’s disease

    • Obesity, high blood pressure, high cholesterol, metabolic syndrome, and diabetes raise the risk

Amyotrophic Lateral Sclerosis (ALS)

  • ALS is also called Lou Gehrig’s disease

  • ALS affects neurons that control voluntary muscle movements

    • Motor neurons in the brain and spinal cord begin to disintegrate

    • The muscles weaken and deteriorate from lack of stimulation

  • The first signs of progressive paralysis are seen in the hands and feet or in muscles of speech and swallowing

  • Early symptoms include:

    • Weakness in legs

    • Difficulty walking

    • Clumsiness of hands when washing and dressing

    • Slurred speech

  • Almost all the muscles under voluntary control are affected

    • However, the mind and senses are still intact

  • Death is usually caused by respiratory failure or pneumonia

  • Over 90% of ALS is sporadic

    • Potential causes include:

      • An excess amount of glutamate

      • Oxygen in a dangerous form (oxidative distress)

      • Environmental factors

      • Autoimmune response

  • The other 5-10% of ALS is familial and linked to a genetic defect

    • A mutation in the gene that codes for the enzyme superoxide dismutase might be a cause of ALS

Huntington’s Disease (HD)

  • The disease slowly progresses over a 10 to 20 year period

    • HD doesn’t allow the individual to walk, think, talk, and reason

  • Symptoms start between 30 and 50 years of age

  • HD Affects basal ganglia and cerebral cortex

  • Initial symptoms include:

    • Involuntary jerking of limbs, torso, facial muscles

    • Mood swings

    • Depression

    • Irritability

    • Slurred speech

    • Clumsiness

  • Symptoms as the disease progresses

    • Difficulty swallowing

    • Unsteady gait

    • Loss of balance

    • Impaired reasoning

    • Memory problems

  • Death can occur by pneumonia, heart failure, or other complications

  • Diagnosis of HD is made by a detailed clinical exam and examining the family history

    • Predictive testing is only for adults

    • Children under the age of 18 may be tested to confirm the diagnosis of juvenile-onset Huntington’s

  • The mutation for HD is an expanded triplet repeat

    • Essentially, a sequence is repeated is repeated more often than needed

      • This abnormal gene codes for an abnormal version of a protein called huntingtin

        • The normal function of this protein is still unknown

      • This protein is widely distributed in the brain and appears to be associated with proteins involved in transcription

        • HD may be caused by the gain of a new and toxic function among these proteins

Parkinson’s Disease

  • Individuals with Parkinson’s disease only start showing symptoms over the age of 50

    • Age is the only known risk factor for the development of the disorder

  • Parkinson’s disease is characterized by:

    • Slowness of movement

    • Muscular rigidity

    • Walking

    • Balance impairment

    • Many patients develop resting tremors as well

  • It may also cause changes in non-motor functions of the brain

  • Parkinson’s disease is caused by the loss of dopamine-producing cells of the substantia nigra pars compacta in the midbrain

    • 40% of these cells must be lost before symptoms occur

      • This suggests that the brain has a way of temporarily warding off symptoms

  • Continued loss of cells leads to reaching the threshold where the brain can no longer recover

  • It is believed that both genetic and environmental factors contribute to the injury and loss of cells in Parkinson’s disease

  • Cases of early-onset Parkinson’s disease may be inherited

Treatment Breakthroughs and the need for more research

  • Levodopa: a drug discovered in the 1960s that is converted to dopamine in the brain

  • Other drugs either boost the effect of dopamine by inhibiting breakdown or extend the length of dopamine-like effects

    • This is because of their ability to bind and act on similar brain regions for longer periods of time

    • One example of this is the use of carbidopa with levodopa

      • Carbidopa helps prevent the breakdown of levodopa in the bloodstream

  • Dopamine replacement therapy doesn’t cure the disease or slow its progression

    • It is not optimal for treating non-motor aspects of disease

    • It also becomes less effective over time

  • MPTP (1-methyl-4-phenyl-1,2,3,6 tetrahydropyridine) was accidentally discovered by drug synthesizers in the late 1970’s

    • Drug addicts who injected MPTP-contaminated drugs developed Parkinson’s

    • MPTP is converted to a substance in the brain that destroys dopamine-producing neurons

    • Specific regions in the basal ganglia become abnormally active

  • Pallidotomy: surgical deactivation or destruction of overactive structures that greatly reduces symptoms

    • The structures that are operated on are the pallidum and subthalamic nucleus

  • Other treatments include

    • Chronic deep-brain stimulation

    • Replacement therapy using stem cells is being tried

    • Gene transfer of trophic factors is being studied in animal models and tested in clinical trials