Biology Unit 2, Structure of Life, Lab Activity 2-3

Similar documents
APBiology Unit 2, Chapter 8

C 6 H 12 O 6 + 6O 2 6H CO kilocalories of energy/mole of glucose

Aerobic Respiration. Evaluation copy

LABORATORY INVESTIGATION

Before doing this lab you should understand:

AP Biology. Investigation 6: Cellular Respiration. Investigation 6: Cellular Respiration. Investigation 6: Cellular Respiration

1. Read the overview. What is the difference between germinating and nongerminating

Boyle s Law: Pressure-Volume Relationship in Gases

Vapor Pressure of Liquids

Lab 5- Cellular Respiration

Boyle s Law: Pressure-Volume. Relationship in Gases

What factors affect the rate of cellular respiration in multicellular organisms?

Vapor Pressure of Liquids

Evaluation copy. Vapor Pressure of Liquids. computer OBJECTIVES MATERIALS

Boyle s Law: Pressure-Volume Relationship in Gases

Evaluation copy. Interdependence of Plants and Animals. computer OBJECTIVES MATERIALS

PRESSURE-TEMPERATURE RELATIONSHIP IN GASES

LAB 06 Organismal Respiration

AP Biology Lab - Cell Respiration

EXPERIMENT 12 GAS LAWS ( BOYLE S AND GAY-LUSSAC S LAW)

Ball Toss. Vernier Motion Detector

Dissolved Oxygen in Water. Evaluation copy. Table 1. Temperature Range ( C) Trout Smallmouth bass Caddisfly larvae

Boyle s Law VC 09. Experiment 9: Gas Laws. Abstract

C6Hi (g) 6 H2O + 6 C02(g) + energy

Evaluation copy. Effect of Vascularity on Skin Temperature Recovery. Computer

Exploring the Properties of Gases

AP Biology 12 Cellular Respiration Lab

Lab #12:Boyle s Law, Dec. 20, 2016 Pressure-Volume Relationship in Gases

Evaluation copy. Wind Chill. computer OBJECTIVES MATERIALS

Experiment AMe-1: Small Animal Respiratory Exchange Ratio (RER)

Exploring the Properties of Gases. Evaluation copy. 10 cm in diameter and 25 cm high)

Vapor Pressure of Liquids

Exp. 5 Ideal gas law. Introduction

Experiment AMe-1: Small Animal Respiratory Exchange Ratio (RER)

Cell Respiration Laboratory PSI Biology

Modeling Diffusion Rates of a Gas in an Enclosed Space

Lab 4: Transpiration

Boyle s Law: Pressure-Volume Relationship in Gases

Ideal gas law. Introduction

BIL 151 Laboratory Enzymes: Practicing the Protocol

Vapor Pressure of Liquids

Name Student Activity

Vapor Pressure of Liquids

Transpiration. DataQuest OBJECTIVES MATERIALS

SOLUBILITY OF A SOLID IN WATER

The Decomposition of Hydrogen Peroxide

LABORATORY INVESTIGATION A Study of Yeast Fermentation - Teacher Instructions

Purpose: Hypothesis: Procedure:

The Gas Laws: Boyle's Law and Charles Law

Objectives. Materials TI-73 CBL 2

Gas Pressure Sensor (Order Code GPS-BTA)

Gas Laws: Boyle s and Amonton s Laws Minneapolis Community and Technical College v.9.08

Respiratory Response to Physiologic Challenges. Evaluation copy

1. Photosynthesis and Light. See real-time evidence that light causes photosynthesis to occur!

CBL Lab GAS PRESSURE & VOLUME MATHEMATICS CURRICULUM. High School. Florida Sunshine State Mathematics Standards

Lab 3. The Respiratory System (designed by Heather E. M. Liwanag with T.M. Williams)

Experiment 11: The Ideal Gas Law

Boyle s Law. Pressure-Volume Relationship in Gases. Figure 1

Fun with Gas Laws. Prepared by Vance O. Kennedy and Ross S. Nord, Eastern Michigan University PURPOSE

Laboratory Inquiry 2: Enzymes: Materials and Methods

MBL BIOLOGY INVESTIGATIONS

Ozobot Bit Classroom Application: Boyle s Law Simulation

Exploring the Properties of Gases

TEMPERATURE S RELATIONSHIP TO GAS & VAPOR PRESSURE

Introduction. Objectives. Hazards. Procedure

SS32L Dissolved O 2 Probe

The University of Hong Kong Department of Physics Experimental Physics Laboratory

Supporting inquiry based teaching and learning. Respiration. Student Name: Class:

Exercise & Cellular Respiration

Boyle s Law: Pressure-Volume Relationship in Gases. PRELAB QUESTIONS (Answer on your own notebook paper)

Experiment C-6 Gas Solubility

where ρ f is the density of the fluid, V is the submerged volume of the object, and g is the acceleration due to gravity.

29 Pressure, Temperature relationship of a gas

What is photosynthesis? Photosynthesis II: Dissolved O2

Experiment P18: Buoyant Force (Force Sensor)

PRODUCT SHEET. Order probe only as RXPROBE02

Lab: The Effect of Exercise on Cellular Respiration

ISE-730 Oxygen Electrode and DO2-100 Currentto-Voltage

Procedure 1: Volume vs. Pressure 1.) Using the lap tops, go to the Physics Education Technology from the University of Colorado at:

In addition to reading this assignment, also read Appendices A and B.

Experiment B-3 Respiration

SOLUBILITY OF A SOLID IN WATER

Name: Period: Date: PHOTOSYNTHESIS, CELLULAR RESPIRATION AND EXERCISE LAB / 38

Gas Laws: Boyle s and Amonton s Laws MCTC Chemistry v.9.17

QUICK WARM UP: Thursday 3/9

Inquiry Investigation: Factors Affecting Photosynthesis

What a Drag! Evaluation copy. Make observations and predictions about shoes. Measure the force needed to pull different shoes across a surface.

The Oxygen Sensor can be connected to all types of einstein Tablets, einstein LabMate, and einstein LabMate +.

Aerobic and Anaerobic Respiration Revision 4

GA-300 Gas Analyzer. Technical Note. Overview. Front Panel. iworx Systems, Inc. GA-300

CLASS COPY-DO NOT WRITE ON

DISSOLVED OXYGEN SENSOR BT34i

Introduction to ChemSense

LAB 13: FLUIDS OBJECTIVES

Gas Pressure and Distance The Force of the Fizz Within, By Donell Evans and Russell Peace

Bay Area Scientists in Schools Presentation Plan

Air Ball! Evaluation copy

STRUCTURED INQUIRY: Investigating Surface Area to Volume Ratio in Cells

INSTRUCTOR RESOURCES

MARK SCHEME for the October/November 2013 series 9700 BIOLOGY. 9700/53 Paper 5 (Planning, Analysis and Evaluation), maximum raw mark 30

Transcription:

Biology Unit 2, Structure of Life, Lab Activity 2-3 Cellular respiration is the release of energy from organic compounds by metabolic chemical oxidation in the mitochondria within each cell. Cellular respiration involves a series of enzyme-mediated reactions. The equation below shows the complete oxidation of glucose. Oxygen is required for this energy-releasing process to occur. A mole is a measure of the number of molecules. The energy released is captured by organisms as ATP or released as heat. C6H12O6 + 6 O2 6 CO2 + 6 H2O + 686 kilocalories of energy/mole of glucose oxidized By studying the equation above, you will notice there are three ways cellular respiration could be measured. You could measure the: 1. Consumption of O2. (How many moles of O2 are consumed in cellular respiration?) 2. Production of CO2. (How many moles of CO2, are produced in cellular respiration?) 3. Release of energy during cellular respiration. In this experiment, the relative volume of 02 consumed (option #1) and the production of CO2 (option #2) by germinating and non-germinating (dry) peas at two different temperatures will be measured. The rate of plant respiration will then be compared to the rate of respiration in an animal. Research Question What factors control the rate of cellular respiration in plants and animals? Write your answer to the research question AFTER completing all parts of the lab. PROTOCOL MATERIALS Computer 250 ml respiration chamber Computer interface Logger Pro software ice cubes thermometer O2 and CO2 Gas Sensor two beakers 25 germinating peas 10 live crickets 25 non-germinating peas

Procedure Data collection for this lab is to be completed as a lab table group. Data reporting and questions are to be completed individually. Part I Germinating and non-germinating peas, room temperatures 1. Connect the CO2 Gas Sensor to Channel 1 and the O2 Gas Sensor to Channel 2 of the Vernier computer interface. 2. Prepare the computer for data collection by opening the file 11D Cell Respiration (CO2 and O2) from the Biology with Computers folder of Logger Pro. 3. Obtain 25 germinating peas and blot them dry between two pieces of paper towel. Measure the room temperature. Record the temperature in Table 1. 4. Place the germinating peas into the respiration chamber. 5. Place the O2 Gas Sensor into the rubber gasket on the side of the respiration chamber. Insert the sensor snugly. The O2 Gas Sensor should remain vertical (this side up) throughout the experiment. Place the CO2 Gas Sensor into the top of the respiration chamber. The CO2 Gas Sensor will not be damaged if it remains horizontal. Do not twist the shaft of the CO2 Gas Sensor or you may damage it. Calibrate the O2 sensor if readings are not close to 210 ppt O2 for room oxygen content. Calibrate the CO2 sensor if readings are much below 0.350 ppt. (your teacher will show you how). Answer Stop question #1 before collecting data 6. Wait one minute for readings to stabilize, then begin collecting data by clicking. Collect data for ten minutes and click. 7. When data collection has finished, remove the both sensors from the respiration chamber. Place the peas in a 250 ml beaker filled with cold water and ice. 8. Fill the respiration chamber with water and then empty it. Thoroughly dry the inside of the respiration chamber with a paper towel. 9. Determine the rate of respiration: a. Click anywhere on the CO2 graph to select it. Click the Linear Fit button to perform a linear regression. A floating box will appear with the formula for a best fit line. b. Record the slope of the line, m, as the rate of respiration for germinating peas at room temperature in Table 2. c. Close the linear regression floating box. d. Repeat Steps 9a c for the O2 graph. 10. Move your data to a stored run. To do this, choose Store Latest Run from the Experiment menu. 11. Obtain 25 non-germinating peas and place them in the respiration chamber Answer Stop question #2 before continuing 12. Repeat Steps 5 10 for the non-germinating peas. Portions adapted from Advanced Biology with Vernier by permission Page 2 of 7

Part II Germinating peas, cool temperatures 13. Remove the peas from the cold water and blot them dry between two paper towels. Answer Stop question #3 before collecting data 14. Repeat Steps 5 9 to collect data with the germinating peas at a cold temperature. 15. To print a graph of concentration vs. volume showing all three data runs: a. Click anywhere on the CO2 graph. Label all three curves by choosing Text Annotation from the Insert menu, and typing Room Temp Germinated (or Room Temp Non-germinated, or Cold Germinated ) in the edit box. Then drag each box to a position near its respective curve. Adjust the position of the arrow head. b. Print a copy of the graph for each lab member (select File>Print Graph), with all three data sets and the regression lines displayed. Enter your name(s) and the number of copies of the graph you want. c. Click on the O2 graph and repeat the process to print copies of the O2 graph. Answer Stop question #4 before continuing Part III Animal Respiration 16. Repeat steps 1-10 and 13-15 using 10 crickets instead of peas. Do not immerse the crickets in cold water, step 7, following data collection (they don't like that). Instead of placing them in cold water put then in the refrigerator for 5 minutes. You will only have two runs (room temperature and cold) for the cricket respiration graphs. 17. Rinse the chambers thoroughly and set them to dry when you are done. Answer Stop question #5 before collecting data Now that you have read these procedures construct a flow chart on the following page. Portions adapted from Advanced Biology with Vernier by permission Page 3 of 7

Flow Chart Lab 2-3 Respiration Portions adapted from Advanced Biology with Vernier by permission Page 4 of 7

Data DATA Table 1 Condition Temperature ( C) Room Cold water Peas Germinating, room temperature Non-germinating, room temperature Germinating, cool temperature Table 2 CO2 Rate of respiration (ppt/min) O2 Rate of consumption (ppt/min) tape pea respiration graphs (CO2 and O2) here tape cricket respiration graphs (CO2 and O2) here They will overlap like this when you have them taped in Portions adapted from Advanced Biology with Vernier by permission Page 5 of 7

Stop Questions 1) Predict what will happen with the dry peas. Will they be using any oxygen or producing any CO2 at all? Explain your reasoning (your explanation is what you will get credit for) 2) Is it important to calibrate the sensors? Would the rate be the same if the sensor read a lower %? Explain your reasoning (your explanation is what you will get credit for) 3) Predict what will happen with the cold peas. Will the respiration rate be higher or lower? Explain your reasoning (your explanation is what you will get credit for) 4) Did the results you collected agree with your predictions? Support your answer with specific data from the experiment. 5) Predict what will happen with the crickets. Will there rate of respiration be higher or lower than the germinating peas? Explain your reasoning (your explanation is what you will get credit for) Analysis Questions 1. The peas are green. They are plants. Do you think they are also producing oxygen? Explain your reasoning (your explanation is what you will get credit for) 2. What part of the plant and animal cells is using the oxygen? 3. Is the oxygen really gone from the chambers? If Yes, where did it go? If No, where is it? 4. Why do the peas use oxygen? 5. Why do the crickets use oxygen? 6. In the chambers the oxygen level drops. In our atmosphere it stays pretty constant at around 21%. What process replenishes the oxygen in our atmosphere that all of the plants and animals use? Conclusion Design an experiment that would compare the respiratory rate of a 25 gram reptile and a 25 gram mammal at 10 C. Include a graph of your expected results and explain why you would expect the results you presented. Your graph will have two lines, one for the reptile and one for the mammal. Experimental Design Manipulated Variable Responding Variable Constants,, Experimental setup Portions adapted from Advanced Biology with Vernier by permission Page 6 of 7

Oxygen gas O2 (%) Carbon Dioxide gas CO2 (ppm) Predicted Graph of Results for Conclusion 450 400 350 Explanation (not a description) of graphed results Portions adapted from Advanced Biology with Vernier by permission Page 7 of 7

2024 © sportdocbox.com Privacy Policy | Terms of Service | Feedback