Investigation 6 - cellular respiration

BleierBiology

15 Oct 201317:40

Summary

TLDRThis video tutorial provides a comprehensive overview of a cellular respiration lab experiment, detailing methods to measure the rate of respiration in organisms. It emphasizes the importance of controlling environmental factors, such as temperature and gas concentrations, to ensure accurate results. Key techniques include using sealed chambers, potassium hydroxide to absorb carbon dioxide, and careful pipet measurements. The tutorial also covers the necessity of using a control group of glass beads to account for non-respiration-related changes in gas volume. Overall, it guides viewers through the experimental process and data analysis required for understanding cellular respiration.

Takeaways

😀 The lab aims to measure the rate of cellular respiration in organisms by observing oxygen consumption.
😀 Oxygen consumption will be measured in milliliters per minute using sealed glass chambers.
😀 Carbon dioxide produced during respiration can affect measurements; potassium hydroxide will be used to absorb it.
😀 Accurate reading of the pipet is crucial; each large mark represents one-tenth of a milliliter.
😀 To maintain consistent results, the volume of solids in each chamber will be kept constant using glass beads.
😀 A control group with only glass beads will help isolate gas volume changes unrelated to respiration.
😀 Chambers should equilibrate to water bath temperature for seven minutes before starting measurements.
😀 Cumulative changes in gas volume will be calculated to analyze respiration rates.
😀 Adjustments based on the control group's data allow for the calculation of a corrected difference.
😀 The lab encourages careful consideration of experimental conditions to ensure accurate and reliable results.

Q & A

What is the primary objective of the cellular respiration lab?
-The primary objective is to measure the rate of cellular respiration in an organism and to investigate how various factors affect this rate.
How can the rate of respiration be measured in this lab?
-The rate of respiration can be measured by determining the amount of oxygen consumed, the amount of carbon dioxide produced, or the temperature change during respiration.
Why is it important to limit the amount of gas available to the organism during the experiment?
-Limiting the gas available helps ensure that any changes in gas volume are solely due to the organism's respiration rather than fluctuations in environmental air.
What role does potassium hydroxide play in the experiment?
-Potassium hydroxide absorbs carbon dioxide produced during respiration, preventing it from affecting the volume measurements of oxygen consumption.
How should the pipet be read to avoid measurement errors?
-The pipet should be read by looking at it from the correct angle, ensuring that the water mark is accurately aligned with the graduated markings to avoid misreading the volume.
What is the purpose of using glass beads in the experiment?
-Glass beads are used to maintain a constant volume of solids within the chamber, which helps control for variations in gas volume changes due to factors other than respiration.
What is meant by 'corrected difference' in the context of the lab?
-Corrected difference refers to the adjustment made by subtracting the volume changes observed in the glass beads group from those in the living organisms, isolating the effects of cellular respiration.
Why is it necessary to equilibrate the chambers before taking measurements?
-Equilibrating the chambers allows the air inside to reach the same temperature as the water bath, which minimizes erratic changes in gas volume due to temperature fluctuations.
What could cause changes in gas volume unrelated to cellular respiration?
-Changes in temperature and pressure can affect gas volume; thus, these factors must be controlled or accounted for to ensure accurate respiration measurements.
What can be concluded if the rate of oxygen consumption increases?
-An increase in the rate of oxygen consumption typically indicates heightened cellular respiration, which may be influenced by factors such as temperature, substrate availability, or organism activity.