Lab (1)+(2)+(3)_General Biology PDF

Summary

This document provides information on general biology lab (1), (2), and (3), focusing on safety procedures, equipment descriptions, and general genetics equipment.

Full Transcript

GENERAL BIOLOGY
LAB (1)
Biology Lab Safety, Lab Notebook, Basic Biology
Laboratory Equipment

College of Applied Sciences
Biology Department
 General Safety Rules

1. Listen to or read instructions carefully before attempting to do anything.

2. Place bags, lab coats, books etc. in specified locations NEVER ON THE BENCH TOPS.

3. There are many different types of protective glove, Use the correct ones for the job you
will be doing.

4. Never eat, drink or smoke in a laboratory
5. If you have an allergy to lab materials or suffer from a Medical condition(eg: diabetes or
epilepsy), ensure that your supervisor knows.

6. Do not touch broken glassware with your hands, Dispose off broken glass in appropriate
receptacles.

7. Do not dispose of hazardous or noxious chemicals in laboratory sinks. Use proper
containers in fume hood.
 General Safety Rules

8- Dispose of all biological waste into appropriate place (Orange Biohazard bags).

9- Keep your workplace tidy, Clear up waste, and washing up things.

10 - Clean up your lab area at the conclusion of the laboratory period.

11-Remove your gloves before using telephone, and leaving the laboratory.

12- After handling chemicals and before leaving the lab, always wash your hands with soap
and water.
 What are the general hazards in a laboratory?

▪ Fire.
▪ Breakage of glassware.
▪ Sharps.
▪ Spillages.
▪ Pressure equipment & gas cylinders.
▪ Extremes of heat & cold.
▪ Chemical hazards.
▪ Biological hazards.
▪ Electrical
▪ Radiation.
 Dressing for Lab

Tie back long hair Don’t wear sandals or open
Roll up loose sleeves. shoes

Wear laboratory coats Protective disposable glove Appropriate safety glasses
 General Laboratory Tools

No Equipment Names Function
1- Beaker To measure liquids
2- Erlenmeyer Flask To measure liquids and mix them
3- Mortar and pestle used to grind solids into fine powders to speed the
mixing or reaction process.
4- Graduated Cylinder To Accurately measure
5- Test Tube To mixing liquids to observe their reaction.
6- Thermometer Used to measure temperature in degrees Celsius or
Fahrenheit.
7- Dropper / Micro To transfer small amount of liquids
pipette
8- Wash bottle Used to rinse or wash with water or alcohol
9- Spatula Used to transfer solid chemicals
10- Petri Dish To grow bacteria and fungi
11- Test tube rack Used to hold test tubes
No Equipment Names Function
3
1- Scissors Cuts tissue during dissection.
2- Microscope Slide Used to prepare specimen for Microscope examined.
1 2 4
3- Cover slip Cover spedmen on the slide.
4- Watch glass Used to cover an evaporating dish or beaker.
5- Teasing Needle Used as a probe in dissection.
6- Scalpel Make precise cuts. 5 6 7 8
7- Stirring rod Used to stir, assist in pouring liquid.
9 10
8- Glass Dropper Bottles Store and disperse a variety of liquids.
9- Bunsen burner or Used for heating.
alcohol lamp
10- Filter Paper Used to absorbed an extra liquid from the material.
11- Slide Box Used to store slide for long time.
12- Staining dishes Used for staining chromosome or washing with 12
alcohol or water. 11
 General Genetics Equipment's
No Equipment Names Function
1- Sensitive Balance Used to weight small amount of solid chemical or powder.
2- Magnetic Stirrer Used to mixing and keeping the chemical solutions and mixtures at a
certain time and temperature by the help of a magnetic bar.
3- Centrifuge Used in cell culture, nucleic acid isolation to separate two liquids in
emulsion form or suspended solids in liquids.
4- Incubator Used to grow microbiological cultures or cell cultures, and maintains
optimal temperature, humidity and other conditions such as carbon di
oxide and oxygen content of atmosphere inside.
5- Autoclave Used to sterilize materials and media under pressure and steam.
6- Thermo Water Bath Uses water to heat or maintain a constant temperature of laboratory
materials or equipment.
7- Electrically heated Used to remove water or other solvents from chemical samples and to
ovens dry laboratory glassware.

8- pH meter Is an electronic device used for measuring the pH. The pH will
indicate if the solution is acidic or basic
 General Genetics Equipment's

Sensitive Balance Magnetic Stirrer
pH meter
Image result for water bath Centrifuge

Incubator Autoclave
Water Bath Dry ovens
 GENERAL BIOLOGY
LAB (2)
Scientific Investigation Laboratory

College of Applied Sciences
Biology Department
 Scientific Investigation Laboratory

Questions and Hypotheses Exercise

Designing Experiments to Test Hypotheses Exercise

Designing an Experiment Exercise

Presenting and Analyzing Results Exercise

Interpreting and Communicating Results
 The question formulated from the observation must be
logical and answerable.

Hypotheses developed from questions must be based
on relevant information, testable, and falsifiable.

Experiments should be designed to minimize
variability, meaning only small details/variables
(preferably only one) should be altered to test the
hypothesis. These controlled experiments are best
when only one variable is changed. Lastly experiments
must be repeatable to help ensure there is no bias in
the results.
 Questions and Hypotheses Exercise

1. What is the hypotheses?

2. What is the dependent variable?

3. What is the independent variable?

4. What were the constant variables?

5. What was the control treatment?

6. How many replicates were conducted?

Why?
Controlled variables are the aspects of the experiments that remain the same through every variation of the
experiment. For example, a researcher testing the effect of soil conditions on plant growth will give each plant the
same amount of water, sunlight, air conditions, temperature etc.

The independent variables are the aspects of the experiment that the researcher changes in order to test the
hypothesis. In the above example, the differing soil condition is the independent variable. Ideally only one variable is
changed when addressing a hypothesis.

The dependent variables are the aspects of the experiment that are measured, and the data obtained is carefully
recorded. For example, the researcher measuring the effect of soil
What was the control treatment?

In biological experimental, the cell
or any organ in it would be that
sample in the group that get no
treatment in an experiment. Say
there is a scientist testing how a
new drug causes cells to grow?!
One group, the experimental group
would receive the drug and the
other would receive a placebo. The
group that received the placebo is
the control group
 How many replicates were conducted? Why?

 Replicate: A replicate is one experimental unit in one
treatment. The number of replicates is the number of
experimental units in a treatment.

 Normally we design experiment with 3 replicates,
each replicate has like 10 samples/treatment (so total
number of samples n = 30/treatment). Then we
average the results of these 10 samples to get 1
number/replicate and use these 3 numbers/treatment
to performing statistical analysis.

 Replicates can be used to measure variation in the
experiment so that statistical tests can be applied to
evaluate differences. Averaging across
replicates increases the precision of gene
expression measurements and allows smaller
changes to be detected.
 Presenting and Analyzing Results
Exercise
All scientific results must eventually be analyzed and presented to others.
A. Basics
Numerical results must be recorded and presented with proper units, an estimate of uncertainty and the correct
number of significant figures.

B. Error analysis and propagation
The uncertainty recorded for a measurement depends on a careful analysis of all the factors that may cause
the measurement to deviate from the true value, either randomly or systematically. Error propagation methods
are used to find the uncertainties in any quantities calculated using the raw measurements.

C. Curve fitting
It is often desirable to compare experimental data with a function derived from theory. This usually requires
choosing some parameters in the theoretical expression so as to best describe the data. That is, the
observations (xi, yi) are claimed to follow a function y=f(x) provided that the constants in f(x) are chosen
properly. The usual procedure is to adjust the parameters to minimize the sum of the squares of the differences
between the expected value of the function and the actual data:
 Presenting and Analyzing Results
Exercise
D. Testing agreement
Because of the uncertainties in all data, deciding whether or not the observations agree with expectations becomes
a problem in probability estimation. The basic idea is to decide how likely it is that the observed deviations are due
to chance, rather than a real difference. If the deviation is large it becomes so unlikely to occur by chance that we
claim the difference is real.

E. Graphing
Graphs are used in the analysis of data and the presentation of results to others. Certain conventions, which differ
among the disciplines, have been developed to ensure that graphs are clear and meaningful for their intended use.
 Interpreting and Communicating Results

 It is important to share what you have
learned with others.
 Scientists often find solutions to problems
by knowing the results of other scientists'
experiments.
 Communicating your results is often the first
step to clearly identifying a problem and
beginning to think about possible solutions.
 There are four frames of references for
interpreting test scores are
explained: Ability, growth, norm, and
criterion referenced interpretations.
 GENERAL BIOLOGY
LAB (3)
Microscopes and Cells Laboratory

College of Applied Sciences
Biology Department
Microscopes and Cells Laboratory

The Compound Light Microscope Exercise

Basic Microscope Techniques Exercise

The Stereoscopic Microscope Exercise

The Organization of Cells
 Type of Microscope

A) Compound Microscope.

B) Electron Microscope.

C) Fluorescent Microscope.
 Microscope Structure

HELP SCIENTISTS
STUDY OBJECTS & MAGNIFIES OBJECTS
LIVING THINGS (MAKES OBJECTS
TOO SMALL TO LOOK BIGGER).
SEE WITH THE
NAKED EYE.
 PARTS OF MICROSCOPE

A general biological microscope mainly consists of an :

1.Ocular (lens) eyepiece: the lens of the microscope that you look through.

2. Course adjustment: the large knob on the microscope that you turn to bring the object into
focus.

3. Fine adjustment: the small knob on the microscope that brings the image into focus.

4. Arm: the part of the microscope supporting the body tube.

5. Body tube: the part that holds the eyepiece and the objective lenses.

6. Nosepiece: the part at the bottom of the body tube that holds the objective lenses and
allows them to be turned.
 PARTS OF MICROSCOPE

7. High power objective lens: the lens that magnifies the object the greatest amount. (usually
40x).

8. Low power (scanner) objective lens: the lens that magnifies the object the least amount
(usually used to find the object; magnifies only 3x or 4x).

9. Middle power objective lens: the lens that usually magnifies the object more than the scanner
lens, but less than the high power lens (usually 10x to 20x).

10. Stage: the flat part below the objectives lens where the slide is placed.

11. Clip: the part that holds the slide in place so it doesn’t move.

12. Diaphragm: the part that controls the amount of light entering the field of view.
 PARTS OF MICROSCOPE

13. light source: the lamp (or mirror) under the stage that sends light.
through the object being viewed.

14. base: the bottom part that supports the rest of the microscope.
The Stereoscopic Microscope Exercise
Compound VS Electron Microscopes

Fluorescence Microscope
Fluorescent light, laser.
X 400-700 nm

Living or dead

Time- consuming and need
Biological fluorescent stains
Expensive
 The Organization of Cells

Most organisms have functional parts with
five levels: cells, tissues, organs, organ
systems and whole organisms.

Based on the organization of their cellular
structures, all living cells can be divided into
two groups: prokaryotic and
eukaryotic (also spelled procaryotic and
eucaryotic). Animals, plants, fungi,
protozoans, and algae all possess eukaryotic
cell types. Only bacteria have prokaryotic cell
types.