1. Negative and Positive feedback systems in the human body
How does your body work to maintain equilibrium in all of its cells? Homeostasis
Negative and Positive feedback systems in the human body
(Adapted from Lesson By Karyn Coulon)
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2. What is homeostasis? Process that occurs in all living things
All organ systems work together to achieve homeostasis
Ability of an organism to maintain its internal environment, despite changes to its internal or external environment
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3. How does homeostasis work?
Feedback pathways
A cellular relay race!
Specific organs and structures must communicate with each other in response to changes in the body
Keeps levels of certain processes within a normal range
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4. Control Center (Integration Center) – compares conditions to set point
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.

5. Positive Feedback: Negative Feedback:
Response from effector reinforces or exaggerates the stimulus
Very rare
Negative Feedback:
Response from effector decreases or inhibits stimulus

6. How is a home heating system an example of a feedback loop?
One example of a feedback system is a thermostat connected to a furnace. The thermostat compares the temperature of the air in the room to a pre-determined setting. If the temperature in the room is below that ideal setting, the thermostat signals the furnace to send warmer air into the room. When the air in the room becomes warmer than the desired temperature, the thermostat stops signaling the furnace. The furnace switches off. If the air in the room grows cool again, the furnace switches on. The cycle repeats indefinitely, as information about the system’s status is constantly fed back into the system. Because of their cyclical nature, feedback systems are often referred to as feedback loops.

7. Identify the following components in a home heating system:
Receptor:
Stimulus:
Integrating center:
Effector:
Response:
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.

8. Identify the following components in a home heating system:
Receptor: Sensors in thermostat
Stimulus: Heat
Integrating center: Thermostat
Effector: Furnace
Response: Furnace turned on to produce heat OR turned off
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.

9. What things in your body need to be kept within a range?
Body Temperature
Blood pressure
Blood pH
O2 and CO2 concentration
Osmoregulation-Water balance
Blood glucose
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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10. Homeostasis Flowcharts
Flowchart must include:
Stimulus
Receptor
Set Point
Integrating Center
Effector
Response
Type of Feedback (Positive or Negative)

11. Life Sciences-HHMI Outreach
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.

12. Cellular Relay Race Stimulus Receptor Integrating center Effector
Response
Reverses the stimulus
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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13. Why is feedback important in living things?
Allows baseline to be regained
Conserves resources
Cellular Materials
Energy (ATP)
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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14. all images generated by Microsoft Clip Art Gallery
mouth
Stomach
Sm. Intestine
Circulatory Runners
Target cells- Brain
Target cells-Muscle
Target cells- Liver
Pancreas
Game set-up
ß-cells
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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15. “Glucose!! Release the insulin!”
mouth
Stomach
Sm. Intestine
Circulatory Runners
Target cells- Brain
Target cells-Muscle
Target cells- Liver
“Glucose!! Release the insulin!”
Pancreas
Lots of glucose circulating, so Pancreas calls out for insulin
ß-cells
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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16. “Glucose!! Release the insulin!”
mouth
Stomach
Sm. Intestine
Circulatory Runners
Target cells- Brain
Target cells-Muscle
Target cells- Liver
“Glucose!! Release the insulin!”
Pancreas
Insulin has been passed to the target cells. Targets can now receive glucose.
ß-cells
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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17. “Hold insulin production”
mouth
Stomach
Sm. Intestine
Circulatory Runners
Target cells- Brain
Target cells-Muscle
Target cells- Liver
“Hold insulin production”
Pancreas stops insulin from being passed once there is no more glucose circulating
Pancreas
ß-cells
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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18. Dueling Hormones What goes up, must come down!
Insulin
Produced by -cells of the Pancreas
Released into circulatory system when blood glucose is high
Facilitates the transport of glucose into target cells
Glucagon
Produced by -cells of the pancreas
Released into the circulatory system when blood glucose is low
Signals the liver to break down glycogen into simple glucose
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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19. Dueling Mechanisms What goes up, must come down!
Thermoregulation
Sweating (cooling) vs. shivering (warming)
Blood Pressure
Vasconstriction vs. vasodilation
Osmoregulation
Hypotonic vs. hypertonic
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20. Food for thought…
On average, how many organ systems are involved in each of the processes we’ve explored?
Are there any organ systems that you see in all of these processes?
What might happen to these pathways if just one system was not functioning properly?
Life Sciences-HHMI Outreach. Copyright 2009 President and Fellows of Harvard College.
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