1. CELLS

3. Adipose Tissue

5. BONE CELLS
Osteocytes

6. CARTILAGE

7. MUSCLE CELLS

8. NERVE CELLS (NEURONS)

10. CELLS FROM THE EYE

12. SKIN CELLS
(EPITHELIAL)

13. CELLS FROM MOUTH

14. TOOTH

16. NASAL CELLS

17. CELLS OF LUNG

18. LIVER CELLS
(hepatocytes)

20. Nervous systems
Nervous systems contain neural cells and glial cells

21. Types of neurons
Sensory neurons
Interneurons
Motor neurons

22. Sensory receptor Sensory neuron Brain Motor Spinal neuron cord
Fig. 28-1b 1
Sensory
receptor 2
Sensory neuron
Brain
Motor
neuron
Spinal
cord 3 4
Quadriceps
muscles
Interneuron
CNS
Nerve
Flexor
muscles
PNS

23. Signal direction Dendrites Cell Body Cell body Layers of
Fig. 28-2
Signal direction
Dendrites
Cell Body
Cell
body
Layers of
myelin sheaths
Signal
pathway
Schwann
cell
Nucleus
Axon
Nucleus
Schwann
cell
Myelin sheath
Synaptic terminals

24. Neurons work by sending an electrical impulse (action potential) from one end of the neuron (cell body) to the other (synaptic terminal)

25. -inside is negative; outside is positive
Resting Potential
There is a difference in the distribution of charges inside the cell compared to outside
-inside is negative; outside is positive
There is a difference in the concentration of certain ions inside compared to outside
outside high concentration of Na+
inside high K+
Animation link

26. Action Potential
A stimulus to a neuron causes Na+ gates to open (Na+ rushes into the cell) reversing the charge
cell is DEPOLARIZED
Charge distribution is reestablished when K+ is allowed to leave the cell
Cell is Repolarized
Na+/K+ pump reestablishes the ion concentrations (expends the most energy in your body)

27. Sending the message on

28. Synaptic terminals Inhibitory Dendrites Excitatory Myelin sheath
Fig. 28-7a
Synaptic terminals
Dendrites
Inhibitory
Excitatory
Myelin
sheath
Receiving
cell body
Axon

29. Fig. 28-7b
Synaptic
terminals

30. Acetylcholine
motor neurons /
muscles
Serotonin & dopamine in brain affect sleep/mood
Botulinum toxin
-inhibits release of acetylcholine

31. Sending neuron Action potential arrives Vesicles Axon of sending1
Action
potential
arrives
Vesicles
Axon of
sending
neuron
Synaptic
terminal
Synapse 2 3
Vesicle fuses
with plasma
membrane
Neurotransmitter
is released into
synaptic cleft
Figure 28.6 Neuron communication.
Synaptic
cleft
Receiving
neuron 4
Neurotransmitter
binds to receptor
Receiving
neuron
Neurotransmitter
molecules
Ion channels

32. Neurotransmitter broken down and released Receptor
Ions
Figure 28.6 Neuron communication. . 5
Ion channel opens 6
Ion channel closes

33. Fetus (three months old)
Cerebral
hemisphere
Diencephalon
Midbrain
Midbrain
Hindbrain
Pons
Cerebellum
Medulla
oblongata
Figure Embryonic development of the human brain.
Spinal cord
Forebrain
Embryo (one month old)
Fetus (three months old)

34. Cerebral cortex Cerebrum Thalamus Forebrain Hypothalamus
Pituitary gland
Figure 28.15A The main parts of the human brain.
Midbrain
Pons
Spinal
cord
Medulla
oblongata
Hindbrain
Cerebellum

35. Left cerebral hemisphere Right cerebral hemisphere Corpus callosum
Figure 28.15B A rear view of the brain.
Corpus
callosum
Basal
ganglia

36. Frontal lobe Parietal lobe Somatosensory cortex Motor cortex
association
area
Frontal
association
area
Speech
Taste
Reading
Speech
Hearing
Visual
association
area
Smell
Figure Functional areas of the left cerebral hemisphere.
Auditory
association
area
Vision
Temporal lobe
Occipital lobe

37. Embryonic Brain Regions Brain Structures Present in Adult
Cerebrum (cerebral hemispheres; includes
cerebral cortex, white matter, basal ganglia)
Forebrain
Diencephalon (thalamus, hypothalamus,
posterior pituitary, pineal gland)
Midbrain
Midbrain (part of brainstem)
Figure Embryonic development of the human brain.
Pons (part of brainstem), cerebellum
Hindbrain
Medulla oblongata (part of brainstem)

38. Sensory receptors Specialized cells or neurons that detect stimuli
Sensory receptors
Specialized cells or neurons that detect stimuli
Student Misconceptions and Concerns
1. The concept of sensory transduction, as applied to any particular sense organ, is typically new to most students. Students’ familiarity with numerous forms of digital technology may help them make a connection. CD players, DVD recordings, and MP3 players rely upon electricity and signal conversions to store and generate sounds and images.
Teaching Tips
1. Students can better understand sensory adaptation by thinking about events in their lives. Perhaps they have visited a grandparent’s home and noticed a distinct smell, possibly that of freshly baked items. Maybe they have entered a science building and picked up a few distinct odors! However, after a few minutes, we tend not to notice the smells as much. These experiences illustrate sensory adaptation.

40. Peripheral nervous system Somatic nervous system Autonomic nervous
Fig
Peripheral
nervous system
Somatic
nervous
system
Autonomic
nervous
system
Sympathetic
division
Parasympathetic
division
Enteric
division

41. Fig. 28-13 Parasympathetic division Sympathetic division Brain Eye
Constricts
pupil
Dilates
pupil
Salivary
glands
Stimulates
saliva
production
Inhibits
saliva
production
Lung
Constricts
bronchi
Dilates
bronchi
Accelerates
heart
Slows
heart
Heart
Adrenal
gland
Spinal
cord
Stimulates
epinephrine
and norepi-
nephrine release
Liver
Stomach
Stimulates
stomach,
pancreas,
and intestines
Pancreas
Stimulates
glucose release
Inhibits
stomach,
pancreas,
and intestines
Intestines
Bladder
Stimulates
urination
Inhibits
urination
Promotes
erection of
genitals
Promotes ejacu-
lation and vaginal
contractions
Genitalia

42. All senses trigger the same type of action potential
All senses trigger the same type of action potential
The brain distinguishes the type of stimulus
Perception is the brain’s integration of sensations
Teaching Tips
1. Optical illusions can reveal the mental gymnastics our mind performs to make sense of our visual world. Consider searching “optical illusions” on the Internet to identify some examples to share with your class.
Copyright © 2009 Pearson Education, Inc.

43. The hypothalamus “master controller” influences many hormones
The hypothalamus
Links the endocrine and nervous systems
Receives input from nerves about body conditions
Responds by sending out appropriate nervous or endocrine signals
Uses the pituitary gland to exert master control over the endocrine system
Student Misconceptions and Concerns
1. The abuse of growth hormones and steroids is of great concern in the world of professional and amateur sports. Although this is mentioned briefly in the text, consider emphasizing further the potential negative consequences of the abuse of these powerful hormones. The National Institutes of Health provide additional details on its website at
Teaching Tips
1. Morphine and other opiates bind to the same cell receptors that naturally bind endorphins, producing powerful pain-killing effects.
Copyright © 2009 Pearson Education, Inc.

44. The pituitary gland Brain Hypothalamus Posterior pituitary
Figure 26.4A Location of the hypothalamus and pituitary.
Anterior pituitary
(Bone)

45. Uterine muscles Mammary glands
Hypothalamus
Hormone
Neuron
cell
Posterior
pituitary
Anterior
pituitary
Blood
vessel
Figure 26.4B Hormones of the posterior pituitary.
Oxytocin
ADH
Uterine muscles
Mammary glands
Kidney tubules

46. the anterior pituitary
Neuron
cell
Blood
vessel
Releasing hormones
from hypothalamus
Endocrine cells of
the anterior pituitary
Figure 26.4C Hormones of the anterior pituitary.
Pituitary hormones
TSH
ACTH
FSH
and LH
Prolactin
(PRL)
Growth
hormone
(GH)
Endorphins
Thyroid
Adrenal
cortex
Testes or
ovaries
Mammary
glands
(in mammals)
Entire
body
Pain
receptors
in the brain

47. HORMONES AND HOMEOSTASIS
HORMONES AND HOMEOSTASIS
Copyright © 2009 Pearson Education, Inc.

48. Feedback Inhibition
Hypothalamus
Inhibition
TRH
The product of a pathway shuts down an earlier step in the pathway
Anterior
pituitary
Inhibition
TSH
Thyroid
Thyroxine

49. Pancreatic hormones regulate blood glucose levels
The pancreas secretes two hormones that control blood glucose
Insulin—signals cells to use and store glucose
Glucagon—causes cells to release stored glucose into the blood
Student Misconceptions and Concerns
1. Many students struggle to remember the basic structures, functions, and locations of the major vertebrate organs. Understanding and remembering the specific control mechanisms are typically beyond their background knowledge entering a general biology college course. Students will appreciate any reminders or reference materials that help them to organize this information.
2. As the section title indicates, a central theme of endocrine function is the maintenance of homeostasis. Repeatedly framing the details of hormonal and glandular function in the context of homeostasis can increase levels of student comprehension.
Teaching Tips
1. The use of calcitonin and parathyroid hormone to hold blood calcium levels steady is similar to the use of a heater and chiller on a fish tank or a laboratory incubator to hold temperatures steady. The same analogy can be applied to the contrasting functions of insulin and glucagon.
2. Scientists are exploring the use of pancreatic cell transplants into patients with type 1 diabetes as a new source of insulin. Pancreatic cells may be derived from donors and/or modified from other cells using stem cell technology. One website devoted to this subject is
Copyright © 2009 Pearson Education, Inc.

50. Homeostasis: Normal blood glucose level
Body
cells
take up more
glucose
Insulin 3 2
Beta cells of pancreas stimulated
to release insulin into
the blood 4
Blood glucose level
declines to a set point;
stimulus for insulin
release diminishes
Liver takes
up glucose
and stores it as
glycogen 1
High blood
glucose level
Stimulus:
Rising blood glucose
level (e.g., after eating
a carbohydrate-rich
meal)
Glucose
level
Homeostasis: Normal blood glucose level
(about 90 mg/100 mL)
Stimulus:
Declining blood
glucose level
(e.g., after
skipping a meal)
Glucose
level
Figure 26.7 Glucose homeostasis. 5
Low blood
glucose level
Blood glucose level
rises to set point;
stimulus for glucagon
release diminishes 6
Alpha
cells of
pancreas stimulated
to release glucagon
into the blood 8
Liver
breaks down
glycogen and
releases glucose
to the blood 7
Glucagon

51. Homeostasis: Normal blood glucose level
Body
cells
take up more
glucose
Insulin 3 2
Beta cells of pancreas stimulated
to release insulin into
the blood 4
Blood glucose level
declines to a set point;
stimulus for insulin
release diminishes
Liver takes
up glucose
and stores it as
glycogen 1
High blood
glucose level
Stimulus:
Rising blood glucose
level (e.g., after eating
a carbohydrate-rich
meal)
Figure 26.7 Glucose homeostasis.
Glucose
level
Homeostasis: Normal blood glucose level
(about 90 mg/100 mL)
Glucose
level

52. Homeostasis: Normal blood glucose level
(about 90 mg/100 mL)
Stimulus:
Declining blood
glucose level
(e.g., after
skipping a meal)
Glucose
level 5
Low blood
glucose
level
Blood glucose level
rises to set point;
stimulus for glucagon
release diminishes 6
Alpha
cells of
pancreas stimulated
to release glucagon
into the blood
Figure 26.7 Glucose homeostasis. 8
Liver
breaks down
glycogen and
releases glucose
to the blood 7
Glucagon