group 3: math & biology teachable unit: passing gas gas exchange is a unifying concept in...
TRANSCRIPT
Group 3: MATH & BIOLOGY
Teachable Unit: PASSING GAS
Gas Exchange is a Unifying Concept in BiologicalSystems
•This teachable unit, Passing Gas, will be presented to a student body consisting of majors and non-majors at the introductory level.•Passing Gas will have examples that can be utilized in sequences dealing with cellular, organismal and ecological biology. •The Passing Gas unit assumes that the students will have basic competency in algebra, geometry and high-school level biology.
Unit Learning Goals
• Biology students will become more comfortable using math in biological applications.
• Students will develop quantitative skills.• Students will use math to analyze
biological phenomena at multiple scales.• Students will understand that gas
exchange is a unifying concept in biology.
Learning Outcomes of Tidbit 1
• Students will use quantitative skills in novel situations involving gas exchange.
• Students will determine the mathematical relationship between parameters that influence levels of gas exchange in an animal system.
• Exoskeleton too weak
• When shed exoskeleton when molting, collapse under weight
• Can’t get enough oxygen
• Limits on ant hill size
• Lung capacity
Clicker Question review from last semester
As the radius of a cell increases, the surface area to volume ratio of the cella) Increasesb) Decreasesc) Stays the samed) Insufficient data to answer this question
A Review: Surface Area/Volume and Maximum Cell Size
Volume of a sphere = 4/3πr3
Surface area of a sphere = 4πr2
Relationship of Surface Area to Volume as a Function of Cell Radius
0
0.5
1
1.5
2
2.5
3
3.5
0 1 2 3 4 5
Cell Radius
Su
rfac
e A
rea
/ V
olu
me
nutrients
wastes
Mini Lecture on Respiratory System of Insects
•Exoskeleton with waxy cuticle prohibitssimple diffusion through epidermis•No blood vessels, so no lungs•Tube system that carries O2 from surfaceto cells and takes up CO2
flatworm
Tracheal tube system
Tracheal volume data Length of Beetles Tracheal volume
(as % of body volume)
17mm 1.9%18mm 2.1%27mm 3.3%47mm 5.7%60mm 7.4%62mm 7.6%80mm 9.9%129mm 15.8%
Graph the data and determine the relationshipbetween tracheal volume and beetle body length.
•What is the mathematical formula describing the relationshipbetween these two variables?A) x2 + y2 = 0B) y = mx + bC) y = log xD) y = 1/x
•What does this information tell us about insectsize and tracheal system size?
Let’s do some math!
SMALL INSECT
Oxygen depleted if tube diameter stays the same
Large Insect
Tracheole volume larger to accommodate needs
SUMMARY OF THE PROBLEM
LARGE INSECT
•Based on your data, what is the theoretical maximum length of a beetle?
The largest living beetle today actually is 170 mm.•What do you think limits the body volume that an insect can devote to the tracheal system?
Entrance Ticket for Next Class
During the Carboniferous (350 mya) there were insects much larger than any found on Earth today. •Develop a hypothesis from this observation.•How would you test your hypothesis?
The relationship between body length and the % of the body volume taken up by tracheal tubes in beetles is defined by a line with a slope of 0.123. Even today there are insects much longer than the beetles we examined in this exercise.
•If you assume that a maximum volume of tracheal tubes is 20% of total insect volume, and the slope of the relationship betweenlength and tracheal volume is 0.056, what is the length of this insect?•What does this insect look like?Explain your answer.
Individual take-home question