Monday, August 12, 2013

First Unit Plan with Objectives and AP Connections...

Major Models to Deploy and Develop Throughout the Year:
-Natural Selection leading to Speciation (1st)
-Central Dogma Traits, Genes, Inheritance (2nd)
-Homeostasis (3rd)
-Interactions between molecules/enzymes leads to all characteristics (4th)
-Math in experimentation as a foundation and scientific questions and conclusions.
-Cellular Reproduction and Development
-Energy and Matter in Ecosystems Carbon Cycling (Photosynthesis Respiration) (Mid First Semester)
-Response to Environment-Nervous system vs. Hormones
-Immune System

Unit Progression (CR2)
Unit #1: Laying the Groundwork of Biology
Time: August-September 4 Weeks
Goal: SWBAT to explain biological process in terms of natural selection and review the processes of the central dogma.
Driving Question: What are the fundamental concepts that describe living organisms?

Key Mental Models to Start to Develop:
-Natural Selection leading to Speciation (1st)
-Central Dogma Traits, Genes, Inheritance (2nd)
-Homeostasis (3rd)
-Interactions between molecules/Enzymes (4th)
-Math in experimentation as a foundation.

Objectives and Activities:
Model Deployment: Formative Whiteboard Prompt: At the cellular level, what what is responsible for your traits? How does this work?
Lesson 1.) SWBAT: Summarize the evidence of gene interactions with the environment.  (1.A.4, 3.B.1, 3.B.2, 4.C.2, 4.C.3)
Activities with this objective...
a.) Summer reading and answering questions over “Genius in All of Us.” by David Shenk. CR5.
b.) Students analyze situations that reveal the interactions between our genes and the environment (CR4c).  Students describe how the gene to protein process relies upon input from external  factors (CR3c, CR3d).  Group presentations over specific chapters of the book and large group discussion over the themes of the book and application to their lives.
c.) Students use evidence to describe why Jamaica produces so many top sprinters (they must determine if they belief innate characteristics or environmental triggers play a more critical role using evidence).  Intro questions...Why do populations living closer to the equator have longer legs in proportion to their bodies than those who live further from the equator? .   Play at 9:50 The Sports Gene from Jeremy Schapp’s podcast.  http://espn.go.com/espnradio/play?id=9554684
Lesson 2.) Model Development: SWBAT: refine their model for how DNA relates to traits. (1.A.1, 1.A.2,  1.A.3)
a.) Students draw and describe the connection between DNA and their traits.  Whiteboard prompt “If DNA is responsible for your traits, what does this look like at the cellular level?” (Green Pea and Strawberry DNA extraction)
b.) Students use paper models to explain how DNA codes for proteins. Watching of HHMI videos of transcription and translation.
c.) Refine their model after extraction and notes. “If DNA is responsible for you traits, what does this look like at the cellular level?” Revisit and make a poster.
Model Deployment: Where do new species come from?
Lesson 3.) Model Development: SWBAT: make visual models of a variety of mechanisms of evolution/speciation 1.A.1, 4.A.1, 4.A.2, 4.B.1, 4.B.2,
a.) Desert Snakes-Mechanics of Evolution Sampsons and Schleigh.
b.) Frog, Cichlid data whiteboarding.
c.) Geographical Isolation/Slips of Paper Speciation.
Model Deployment: How do we use math to represent biological information?
Lesson 4.) Model Development: SWBAT: use mathematical evidence to describe maple seed dispersion patterns relating to natural selection. (4.A.4)
a.) Phospholipid Bubble paper modeling and finding different averages for sizes. Standard Deviation and Standard Error (quick experimental design practice)
b.) LAB write up over natural selection with maple seed travel distances under different environmental situations. Computing standard deviation and standard error in data analysis.  Devising controlled experiments and communicating results (1.B.1) . CR6, CR7
Model Deployment: What are the rules that govern molecular interactions?  
Lesson 5.) Model Development: SWBAT: describe the basic structure and function of the four categories of macromolecules and water.   Macromolecule notes+ATP, group analysis of situations when characteristics of monomers are altered. CR4d
a.) model the building and breaking of biological polymers. Building and breaking biomolecules-modeling dehydration synthesis, hydrolysis.
b.) relate the structure to the function of water. Water inquiry activities and connection to molecular structure (adhesion, cohesion, capillary action)
Lesson 6.) SWBAT: use cell organelle data to make hypothesis about cell function.
a.) Cell organelle review sheet and analyzing cells with different organelle ratios
Lesson 7.) SWBAT: describe the components of and test the variables in an enzyme catalyzed reaction.
a.) Enzyme LAB (First Analogy with “Toothpickase”) and actual Enzyme Catalysis Lab using potatoes (along with other vegetables and fruits) and Peroxide to generate oxygen gas using guided inquiry.  The rate of reaction is measured by Vernier Labquest gas pressure sensors. (plant Homeostasis seed with peroxidase lab write up) CR6, CR7
Lesson 8.) SWBAT: generate a cladogram using anatomical characteristics.
a.) Simple cladogram generation using anatomical characteristics of vertebrates.
b.) For the cladogram, questions to answer....identify shared characteristics, (2) make inferences about the evolutionary history of the group, and (3) identify character data that could extend or improve the phylogenetic tree. (EU 1.B.2, LO 1.17-1.19)
Lesson 9.) SWBAT: determine characteristics that are shared and theorize the origin of the universal characteristics of life.
a.) Students use this information about the different cells to generate a cladogram (LO.2.14) as well where students explain unique and shared characteristics.  
b.) Determining universal characteristics activity: Analysis of components/macromolecules of cells of all sorts of organisms.  Students determine set of “Universal Physical Components and Processes of Life” CR3a
c.) For above cladograms...identify shared characteristics, (2) make inferences about the evolutionary history of the group, and (3) identify character data that could extend or improve the phylogenetic tree. (EU 1.B.2, LO 1.17-1.19)

d.) Shared or unshared game? Given a characteristic, students determine if it is shared or unshared with all of life.  (EU 1.B.1, LO 1.15)

Tuesday, May 14, 2013

End of April to AP Test

Leading up to AP Test...
Practice Free Response Questions and reflection on each question.
Practice Designing experiments
Reviewing during advisor
Final experimentation

AP Biology Test

Skyping with Alex D.

After AP Test Mini projects

Tuesday, April 2, 2013

Back from Spring Break.

4/8
SWBAT: Calculate and Determine importance of surface area to volume ratios.

4/9
SWBAT: Describe how nitrogen flows through an ecosystem and interactions between nitrogen and hemoglobin proteins.

4/10:
SWBAT: Measure Nitrates in well water and whiteboard the connection to the rest of biology

4/11
SWBAT: Describe the use of spectrophotometry by experimenting with different food dyes and chlorophyll.  Isolating Chlorophyll and analyzing spectrophotometry.

4/12
SWBAT: Describe spectrometry, and make connections between proteins and environment.

4/15
SWBAT: Complete Enzyme Experiment using glucose test strips

4/16
SWBAT: Analogize Primary Productivity and make predictions about which ecosystems have the highest productivity.

SWBAT: Describe water potential calculations and how water will move in different situations.

4/17
SWBAT: Describe water potential calculations and how water will move in different situations.

4/18
SWBAT: complete transpiration lab determining the rate of transpiration.

4/19
SWBAT: Quiz over primary production, nitrates in well water, biotechnology, bacterial transformation, gel electrophoresis

SWBAT: make connections between water potential, transpiration, and nitrates in well water.

4/22-4/23 6 questions in folder activity

4/24 Evaluating other people's answers and points and argue about them.

Monday, March 18, 2013

End of Feb. to March

End of Feb to mid March:
AP Practice,
Fish Experimentation
Making wikipages for AP Ideas
5 Dissections and Comparisons of Organisms Structure and Function
Bacterial Transformation

March 18-22
Bacterial Transformation
Fish Experimentation
AP Practice
Agar Diffusion Lab
Photosynthesis Respiration Review

March 25-29
Animal Behavior Lab
AP Practice
Experimental Design.

Spring Break: AP Review Questions.


Wednesday, February 13, 2013

Finish Nervous System, Dissections, Sub Week

M-W: Develop and Refine the Model of Neuron

Thursday: Mussel Dissection

Friday: Presentation of Nervous System Data-Model Revision, Research the next dissection

Monday: Next Dissection

Tuesday: Turn in nervous system lab report. Research next dissection

Wednesday: Next Dissection

Thursday: Going over sub assignment, getting started on it and dealing with questions.

Friday Next Dissection

Monday and Tuesday: Working on Wikispace.

Wednesday: Sit and practice a free response test.

Thursday and Friday: Finish working on wikispace.

Monday back: Going over each other's wikispaces and taking their quizzes. Research Next dissection.

Tuesday: Final Dissection


Tuesday, December 18, 2012

Back from Break, Immune System

Monday: Start Each Day with Practice Question...
Negative Feedback Graphs and Story Telling

Tuesday
Going over Final Exam

Wednesday
Combining Gametes to look at next generation

Thursday
Immune System Start

Friday
Immune System Continue, Reading, Notes
Nobel Prize Game Play

Monday
Immune System Continue, Paragraph, Devise Experiment

Tuesday
Immune System Experimentation