1. Ch. 49: Nervous Systems

2. The central nervous system (CNS): the brain and the spinal cord
Many animals have a complex nervous system that consists of
The central nervous system (CNS): the brain and the spinal cord
The peripheral nervous system (PNS) consists of neurons/ nerves and ganglia (clusters of neurons) carrying information into and out of the CNS. The neurons of the PNS, when bundled together, form nerves
Brain
Region specialization is a hallmark of both systems
Spinal cord (dorsal nerve cord)
Sensory ganglia
(h) Salamander (vertebrate)

3. Central nervous system (CNS) Brain Cranial nerves Spinal cord
Figure 49.6
Central nervous system (CNS)
Brain
Cranial nerves
Spinal cord
Peripheral nervous system (PNS)
Ganglia outside CNS
Spinal nerves
Figure 49.6 The vertebrate nervous system

4. Glia
Glial cells, or glia have numerous functions to nourish, support, and regulate neurons
Embryonic radial glia form tracks along which newly formed neurons migrate
Astrocytes induce cells lining capillaries in the CNS to form tight junctions, resulting in a blood-brain barrier and restricting the entry of most substances into the brain
Radial glial cells and astrocytes can both act as stem cells
Researchers are trying to find a way to use neural stem cells to replace brain tissue that has ceased to function normally

5. Information is transmitted from a presynaptic cell (a neuron) to a postsynaptic cell (a neuron, muscle, or gland cell)
Most neurons are nourished or insulated by cells called glia or glial cells
80 µm
Glia
Cell bodies of neurons

6. Capillary Neuron CNS PNS VENTRICLE Cilia Ependymal cells Astrocytes
Figure 49.3
Capillary
Neuron
CNS
PNS
VENTRICLE
Cilia
Figure 49.3 Glia in the vertebrate nervous system
Ependymal cells
Astrocytes
Oligodendrocytes
Microglia
Schwann cells

7. Organization of the Vertebrate Nervous System
The CNS develops from the hollow nerve cord
The cavity of the nerve cord gives rise to the narrow central canal of the spinal cord and the ventricles of the brain
The canal and ventricles fill with cerebrospinal fluid, which supplies the CNS with nutrients and hormones and carries away wastes

8. The brain and spinal cord contain
Figure 49.5
The brain and spinal cord contain
Gray matter, which consists of neuron cell bodies, dendrites, and unmyelinated axons
White matter, which consists of bundles of myelinated axons
Gray matter
White matter
Figure 49.5 Ventricles, gray matter, and white matter
Ventricles

9. The spinal cord also produces reflexes independently of the brain
The spinal cord conveys information to and from the brain and generates basic patterns of locomotion
The spinal cord also produces reflexes independently of the brain
A reflex is the body’s automatic response to a stimulus
For example, a doctor uses a mallet to trigger a knee-jerk reflex

10. Cell body of sensory neuron in dorsal root ganglion
Figure 49.7
Cell body of sensory neuron in dorsal root ganglion
Gray matter
White matter
Quadriceps muscle
Spinal cord (cross section)
Hamstring muscle
Figure 49.7 The knee-jerk reflex
Key
Sensory neuron
Motor neuron
Interneuron

11. The Peripheral Nervous System
The PNS transmits information to and from the CNS and regulates movement and the internal environment
In the PNS, afferent neurons transmit information to the CNS and efferent neurons transmit information away from the CNS
The PNS is further broken down into the motor division which we have voluntary control over, and the involuntary autonomic division, further broken down into the antagonistic sympathetic and parasympathetic divisions as well as the enteric division.

12. The PNS has two efferent components: the motor system and the autonomic nervous system
The motor system carries signals to skeletal muscles and is voluntary
The autonomic nervous system regulates smooth and cardiac muscles and is generally involuntary
The autonomic nervous system has sympathetic and parasympathetic divisions
The sympathetic division regulates arousal and energy generation (“fight-or-flight” response)
The parasympathetic division has antagonistic effects on target organs and promotes calming and a return to “rest and digest” functions

13. CENTRAL NERVOUS SYSTEM (information processing)
Figure 49.8
CENTRAL NERVOUS SYSTEM (information processing)
PERIPHERAL NERVOUS SYSTEM
Afferent neurons
Efferent neurons
Autonomic nervous system
Motor system
Sensory receptors
Control of skeletal muscle
Figure 49.8 Functional hierarchy of the vertebrate peripheral nervous system
Internal and external stimuli
Sympathetic division
Parasympathetic division
Enteric division
Control of smooth muscles, cardiac muscles, glands

14. Parasympathetic division Sympathetic division
Figure 49.9
Parasympathetic division
Sympathetic division
Constricts pupil of eye
Dilates pupil of eye
Stimulates salivary gland secretion
Inhibits salivary gland secretion
Sympathetic ganglia
Constricts bronchi in lungs
Relaxes bronchi in lungs
Cervical
Slows heart
Accelerates heart
Stimulates activity of stomach and intestines
Inhibits activity of stomach and intestines
Thoracic
Stimulates activity of pancreas
Inhibits activity of pancreas
Stimulates glucose release from liver; inhibits gallbladder
Stimulates gallbladder
Figure 49.9 The parasympathetic and sympathetic divisions of the autonomic nervous system
Lumbar
Stimulates adrenal medulla
Promotes emptying of bladder
Inhibits emptying of bladder
Sacral
Promotes erection of genitalia
Promotes ejaculation and vaginal contractions
Synapse

15. Concept 49.2: The vertebrate brain is regionally specialized
Specific brain structures are particularly specialized for diverse functions
The vertebrate brain has three major regions: the forebrain, midbrain, and hindbrain
The forebrain has activities including processing of olfactory input, regulation of sleep, learning, and any complex processing
The midbrain coordinates routing of sensory input
The hindbrain controls involuntary activities and coordinates motor activities

16. Figure 49.10
Comparison of vertebrates shows that relative sizes of particular brain regions vary
These size differences reflect the relative importance of the particular brain function
Lamprey
Shark
ANCESTRAL VERTEBRATE
Ray-finned fish
Amphibian
Figure Vertebrate brain structure and evolution
Crocodilian
Key
Bird
Forebrain
Midbrain
Hindbrain
Mammal

17. During embryonic development the anterior neural tube gives rise to the forebrain, midbrain, and hindbrain
The midbrain and part of the hindbrain form the brainstem, which joins with the spinal cord at the base of the brain
The rest of the hindbrain gives rise to the cerebellum
The forebrain divides into the diencephelon, which forms endocrine tissues in the brain, and the telencephalon, which becomes the cerebrum

18. Figure 49.11b
Embryonic brain regions
Brain structures in child and adult
Telencephalon
Cerebrum (includes cerebral cortex, basal nuclei)
Forebrain
Diencephalon
Diencephalon (thalamus, hypothalamus, epithalamus)
Midbrain
Mesencephalon
Midbrain (part of brainstem)
Metencephalon
Pons (part of brainstem), cerebellum
Hindbrain
Myelencephalon
Medulla oblongata (part of brainstem)
Mesencephalon
Cerebrum
Diencephalon
Metencephalon
Midbrain
Myelencephalon
Hindbrain
Diencephalon
Figure 49.11b Exploring the organization of the human brain (part 2: brain development)
Midbrain
Pons
Brainstem
Medulla oblongata
Telencephalon
Forebrain
Cerebellum
Spinal cord
Spinal cord
Embryo at 1 month
Embryo at 5 weeks
Child

19. Cerebrum Forebrain Thalamus Hypothalamus Pituitary gland Midbrain Pons
Figure 49.UN07
Cerebrum
Forebrain
Thalamus
Hypothalamus
Pituitary gland
Midbrain
Figure 49.UN07 Summary of key concepts: vertebrate brain regions
Pons
Spinal cord
Hindbrain
Medulla oblongata
Cerebellum

20. Diencephalon Thalamus
Figure 49.11d
Diencephalon
Thalamus
Pineal gland
Hypothalamus
Midbrain
Pituitary gland
Pons
Figure 49.11d Exploring the organization of the human brain (part 4: diencephalon and brainstem)
Medulla oblongata
Spinal cord

21. Arousal and Sleep The brainstem and cerebrum control arousal and sleep
The core of the brainstem has a diffuse network of neurons called the reticular formation
These neurons control the timing of sleep periods characterized by rapid eye movements (REMs) and by vivid dreams
Sleep is also regulated by the biological clock and regions of the forebrain that regulate intensity and duration
Sleep is essential and may play a role in the consolidation of learning and memory

22. Input from nerves of ears
Figure 49.12
Eye
Input from nerves of ears
Figure The reticular formation
Reticular formation
Input from touch, pain, and temperature receptors

23. Some animals have evolutionary adaptations allowing for substantial activity during sleep
Dolphins, for example, sleep with one brain hemisphere at a time and are therefore able to swim while “asleep”
Key
Low-frequency waves characteristic of sleep
High-frequency waves characteristic of wakefulness
Location
Time: 0 hours
Time: 1 hour
Left hemisphere
Figure Dolphins can be asleep and awake at the same time.
Right hemisphere

24. Biological Clock Regulation
Cycles of sleep and wakefulness are examples of circadian rhythms, daily cycles of biological activity
Such rhythms rely on a biological clock, a molecular mechanism that directs periodic gene expression and cellular activity
Biological clocks are typically synchronized to light and dark cycles
In mammals, circadian rhythms are coordinated by a group of neurons in the hypothalamus called the suprachiasmatic nucleus (SCN)
The SCN acts as a pacemaker, synchronizing the biological clock

25. Emotions
Generation and experience of emotions involve many brain structures, including the amygdala, hippocampus, and parts of the thalamus
These structures are grouped as the limbic system
Generating and experiencing emotion often require interactions between different parts of the brain
The structure most important to the storage of emotion in the memory is the amygdala, a mass of nuclei near the base of the cerebrum

26. Thalamus Hypothalamus Olfactory bulb Amygdala Hippocampus Figure 49.14
Figure The limbic system in the human brain
Olfactory bulb
Amygdala
Hippocampus

27. Concept 49.3: The cerebral cortex controls voluntary movement and cognitive functions
The cerebrum, the largest structure in the human brain, is essential for language, cognition, memory, consciousness, and awareness of our surroundings
Four regions, or lobes (frontal, temporal, occipital, and parietal), are landmarks for particular functions

28. Motor cortex (control of skeletal muscles)
Figure 49.16
Motor cortex (control of skeletal muscles)
Sensory association cortex (integration of sensory information)
Somatosensory cortex (sense of touch)
Frontal lobe
Parietal lobe
Prefrontal cortex (decision making, planning)
Visual association cortex (combining images and object recognition)
Broca’s area (forming speech)
Figure The human cerebral cortex
Temporal lobe
Occipital lobe
Auditory cortex (hearing)
Cerebellum
Visual cortex (processing visual stimuli and pattern recognition)
Wernicke’s area (comprehending language)

29. Information Processing
The cerebral cortex receives input from sensory organs and somatosensory receptors
Somatosensory receptors provide information about touch, pain, pressure, temperature, and the position of muscles and limbs
The thalamus directs different types of input to distinct locations
Information received at the primary sensory areas is passed to nearby association areas that process particular features of the input

30. Primary somatosensory cortex
Figure 49.17
Frontal lobe
Parietal lobe
Shoulder
Upper arm
Forearm
Elbow
Trunk
Knee
Trunk
Hip
Head
Neck
Forearm
Elbow
Hip
Leg
Wrist
Fingers
Hand
Hand
Fingers
Thumb
Thumb
Neck
Eye
Brow
Nose
Face
Eye
Lips
Genitalia
Face
Toes
Teeth
Figure Body part representation in the primary motor and primary somatosensory cortices
Gums
Lips
Jaw
Jaw
Tongue
Pharynx
Tongue
Primary motor cortex
Primary somatosensory cortex
Abdominal organs

31. Language and Speech
Studies of brain activity have mapped areas responsible for language and speech
Patients with damage in Broca’s area in the frontal lobe can understand language but cannot speak
Damage to Wernicke’s area causes patients to be unable to understand language, though they can still speak

32. Max Hearing words Seeing words Min Speaking words Generating words
Figure 49.18
Max
Hearing words
Seeing words
Figure Mapping language areas in the cerebral cortex
Min
Speaking words
Generating words

33. Frontal Lobe Function
Frontal lobe damage may impair decision making and emotional responses but leave intellect and memory intact
The frontal lobes have a substantial effect on “executive functions”

34. Lateralization of Cortical Function
The two hemispheres make distinct contributions to brain function
The left hemisphere is more adept at language, math, logic, and processing of serial sequences
The right hemisphere is stronger at facial and pattern recognition, spatial relations, and nonverbal thinking
The differences in hemisphere function are called lateralization
The two hemispheres work together by communicating through the fibers of the corpus callosum

35. Memory and Learning
Neuronal plasticity describes the ability of the nervous system to be modified after birth
The formation of memories is an example of neuronal plasticity
Short-term memory is accessed via the hippocampus
The hippocampus also plays a role in forming long-term memory, which is later stored in the cerebral cortex
Some consolidation of memory is thought to occur during sleep

36. Study hard….. study often…. N1 N1 N2 N2
Figure 49.20 N1 N1
Study
hard…..
study
often…. N2 N2
(a) Connections between neurons are strengthened or weakened in response to activity.
Figure Neural plasticity
(b) If two synapses are often active at the same time, the strength of the postsynaptic response may increase at both synapses.

37. Concept 49.5: Many nervous system disorders can be explained in molecular terms
Disorders of the nervous system include schizophrenia, depression, drug addiction, Alzheimer’s disease, and Parkinson’s disease
These are a major public health problem
Genetic and environmental factors contribute to diseases of the nervous system

38. Schizophrenia Depression
About 1% of the world’s population suffers from schizophrenia. Schizophrenia is characterized by hallucinations, delusions, and other symptoms. Evidence suggests that schizophrenia affects neuronal pathways that use dopamine as a neurotransmitter
Depression
Two broad forms of depressive illness are known
In major depressive disorder, patients have a persistent lack of interest or pleasure in most activities
Bipolar disorder is characterized by manic (high-mood) and depressive (low-mood) phases
Treatments for these types of depression include drugs such as Prozac, which increase the activity of biogenic amines in the brain

39. The Brain’s Reward System and Drug Addiction
The brain’s reward system rewards motivation with pleasure
Some drugs are addictive because they increase activity of the brain’s reward system
These drugs include cocaine, amphetamine, heroin, alcohol, and tobacco
Drug addiction is characterized by compulsive consumption and an inability to control intake
Addictive drugs enhance the activity of the dopamine pathway
Drug addiction leads to long-lasting changes in the reward circuitry that cause craving for the drug

40. Nicotine stimulates dopamine- releasing VTA neuron.
Figure 49.23
Inhibitory neuron
Nicotine stimulates dopamine- releasing VTA neuron.
Opium and heroin decrease activity of inhibitory neuron.
Dopamine- releasing VTA neuron
Cocaine and amphetamines block removal of dopamine from synaptic cleft.
Figure Effects of addictive drugs on the reward system of the mammalian brain
Cerebral neuron of reward pathway
Reward system response

41. Alzheimer’s Disease Parkinson’s Disease
Alzheimer’s disease is a mental deterioration characterized by confusion and memory loss
Alzheimer’s disease is caused by the formation of neurofibrillary tangles and amyloid plaques in the brain
There is no cure for this disease though some drugs are effective at relieving symptoms
Parkinson’s Disease
Parkinson’s disease is a motor disorder caused by death of dopamine-secreting neurons in the midbrain
It is characterized by muscle tremors, flexed posture, and a shuffling gait
There is no cure, although drugs and various other approaches are used to manage symptoms

42. Neurofibrillary tangle 20 µm
Figure 49.24
Amyloid plaque
Neurofibrillary tangle
20 µm
Figure Microscopic signs of Alzheimer’s disease

43. Figure 49.11a
Figure 49.11a Exploring the organization of the human brain (part 1: MRI)