GTB106 Laboratory Science Tutorial PDF

Summary

This document is a tutorial on GTB106 Laboratory Science, covering various topics such as physical, chemical, and biological hazards, personal protective equipment (PPE), and methods of decontamination and disposal. It also discusses laboratory acquired infections.

Full Transcript

GTB106 Laboratory
Science
Tutorial 1

Dr Shuhaila Mat Sharani
Physical, Chemical and
Biological hazards
 Physical Hazards
Hazards present in ordinary laboratory equipment and surroundings:

Electrical Laboratory Fire Glassware
(wiring and instruments
appliances)

Safety signs are
posted in appropriate
places as reminders to
laboratory users
Personal Protective Equipment (PPE)

Students are provided with PPE to protect against identified hazards.
Safety equipment's include:
▪ Eye, face, and skin: masks, goggles, or protective shield.
▪ Inhalation: respirator or fume hood to protect against inhalation of fumes.
▪ Skin, hands, and arms: gloves (rubber/asbestos).
▪ Body: laboratory coat/apron and appropriate attire (long pants/skirt).
▪ Feet: closed non-slippery shoes.
▪ Hair: tie back long hair
 Chemical Hazards

Chemicals present a variety of hazards:
▪ Flammable

▪ Toxic

▪ Caustic

▪ Corrosive

▪ Carcinogenic

▪ Mutagenic

▪ Radioisotopes
 Chemical Labels
Blue Red Yellow White
environmentally acute gas
1
hazardous toxicity2 cylinder3
indicates indicates indicates indicates
health fire hazard reactive or reactivity
hazards or or unstable with water
toxics flammability chemicals or contact
such as hazards
oxidizers explosive
6
flamable
corrosive4 5

Colour-coded labeling system for identifying and warning of
chemical hazards
→ NFPA (National Fire Protection Association) health
oxidizing serious9health
hazard7 8 hazard
 Methods of decontamination and disposal

Method of decontamination: Methods of disposal:

▪ Boiling (disinfection) ▪ Burial (waste pit or landfill)

▪ Chemical disinfectant ▪ Incineration for solid waste

▪ Autoclaving (sterilization)
 Substances recognized as having the potential to transmit
pathogens Blood Organs

Blood products Sweat
Human blood & blood products Semen Breast milk
Microorganisms culture & wastes
Peritoneal fluid Synovial fluid
Animal waste/carcass
Human body fluids/tissues Amniotic fluid Vaginal secretions
Sharps waste Cerebrospinal Pleural fluid
Pathological wastes fluid
Unfixed tissue
Urine specimens

Pericardial fluid Saliva in dental
settings where
bleeding occurs
Standard Precautions handle biological hazards
It includes the use of safe work practices:
▪ Wash hand properly before and after
▪ Used of safety needles
▪ Proper PPE (Gown, Mask, Gloves ,Eye and mucous
membrane protection )
▪ Working in Biosafety Cabinet/ laminar flow
 Laboratory acquired infections

1 2
Infection through skin & eyes Infection through mouth

Cuts and scratches from skin Ingestion during mouth pipetting
Hands through contaminated benches Oral-contaminated fingers (eating)
& equipment
Cigarettes/pipes
Hands to face & eyes
Eyes through sample splashing
 Laboratory acquired infections

3 4
Infection through the respiratory tract Infection of the general public
Many common lab procedure release Route of infection – from laboratory or
aerosols (infected airborne droplets) hospital settings
‘Droplet's nuclei’ contains bacteria or
Contact with patients or hospital staff
viruses
Inhaled particle size ≤10 µm will not Contact with infectious waste,
get trapped discarded or effluent materials
 Classification of infective microorganisms

Risk group Risk group
Present low risk to lab staff & public Present moderate risk to lab staff & public
▪ Unlikely to cause diseases ▪ Can cause serious disease but not serious hazard
▪ Examples: ▪ Effective preventive measures & treatment available
Food spoilage bacteria ▪ Risk spread in community is limited
Common moulds Bacteria: gram + cocci, enterobacteria, clostridia,
Yeasts vibrio
Viruses: adenoviruses, polioviruses, hepatitis,
coxsackieviruses, coronavirus
Fungi: Blastomyces
Protozoa: toxoplasma, Leishmania
 Classification of infective microorganisms

Risk group Risk group
▪ Present high risk to lab workers ▪ Present high risk to lab worker
▪ Present low risk to community ▪ Present high risk to community
▪ Do not spread rapidly among individual ▪ Cause serious diseases
▪ There are effective vaccines and treatment ▪ Disease easily transmitted among individual
▪ Examples: ▪ Effective treatment and preventive
Mycobacterium tuberculosis, salmonella measures are not usually available
Arboviruses, HIV ▪ Examples:
Histoplasma COVID-19
SARS
Haemorrhagic fever
Glassware and
Plasticware
 Glass Type and properties
Glass Brand Properties Purpose
Kimax or Pyrex Borosilicate - inert Multipurpose
Borosilicate glass beaker, conical flask, tube test, etc
heat resistant until 510˚C
Vycor 96% silica, low alkali, high resistant to Optical use
Aluminosilicate heat shock Cuvette, thermometer, etc
High silica High temperature 900-1200˚C

Corex Aluminosilicate glass 6-10 times more Use in stressful condition
Aluminosilicate resistant than ordinary 'borosilicate' High thermometer temperature 250˚C,
glass; anti scratch and alkali resistant centrifuge tube stable until 670˚C

Boron free Soft, not heat resistant, withstand strong Strong alkaline solution storage
alkaline solution

Low actinic Contains reddish yellow material Storage and handling of light -sensitive
substances (eg bilirubin, carotene and
vitamin A)
Pipette and pipetting
technique
Meniscus
 Pipette classification

To Deliver (TD) – Blow-out –has Measuring or

Type
Design

Drainage characteristics
deliver exact continuous etched graduated –
amount rings (frosted / two Serological, Mohr,
Bacteriologic, Bell,
To Contain (TC) – thin rings) on top of
Kolmer and Kahn and
hold particular pipette automatic micropipette
volume but not Self-draining – drain Volumetric or Transfer
dispense the exact by gravity and do –volumetric/Ostwald-
volume not touch liquid in Folin, Pasteur pipette,
container automatic macro-
pipette (start at 1 ml) or
micropipette (between
0.1 and 1000µl)
 Micropipette Technique
Method 1: Method 2:
Rest plunger Rest plunger

Forward pipetting First stop
A B C
Reverse pipetting First stop
A D E F
Second stop Second stop
D E B C

C C
A E F
A B
E
D D
B

Normal liquid High viscosity

https://www.microlit.us/micropipette-product-guide/
 Cleaning and Proper Care of a micropipette
Wipe with alcohol or
laboratory cleaning agent Solution Types Process to clean
by letting on micropipette For aqueous solutions, Rinse the contaminated parts with distilled
for 10 minute before wiping organic solvents and water or 70 percent ethanol and air dry at
off. proteins approximate 60°F temperature.
Place in upright position at
specific rack if not use For infectious liquids Autoclave the lower section at a
temperature of 120°C for 15-20 minutes
then allow it to return at room temperature
before reassembling.
For radioactive Place the pipette in a solution like Decon
substances and then rinse and air dry.
Boil lower parts of micropipette in glycine/
For nucleic acids HCI buffer (pH2) for 10 minutes, rinse with
distilled water, and air dry.

https://www.pipette.com/pipettestands
Laboratory Calculation
and Reagent
Preparation
Molarity
 Moles and Molarity
Origin of mole: the need for a universal unit of measurement to connect the mass of an
atom/molecule with the number of atoms/molecules in any given compound.
Mole (mol): SI unit of a quantity of a given molecule.
A define mass of an element (its atomic weight) contains an exact number of atoms
(Avogadro number).
Thus, for any given molecule, one mole of a substance has a mass (grams) equal to the
atomic mass of the molecule.

No. moles (n) = Mass of substance (m) m
Relative Formula Mass (RFM)
Mr n
 Molarity
Molar solution: a molar solution is one which contain 1gram
molecular weight of (solute) in 1 liter of (solution). n
○ Importance: a fundamental and convenient way of expressing
the concentration of a compound in solution (liquid). M V
○ A one molar solution (1M) means: one mole of a given
substance in a liter of a solution (1 mol /L).

Number of moles (n) = molarity (M) X volume (V) (in liters)

○ Molal solution: a molal solution is one which contain 1gram
molecular weight of (solute) in 1 kg of (solvent).
Molality
 Molarity vs Molality
Molarity (M) = moles of solute (n) Molality(m) = mole of solute
liters of solution (V) kg of
solvent
solute and solvent Solvent by itself
combined

1 moles CaCl2 = 111.0g

111.0g CaCl2
111.0g CaCl2

1kg water
1L solution
Understanding Mass, Weight, Volume and
Density
Important measures to quantify biomolecules – mass, weight, volume
and concentration.

Mass is the quantity of matter in each object and independent of
gravity.

Weight is the force of gravity on a given object and calculated as mass
multiplied by gravity.

Weight = Mass X Acceleration due to gravity
 Volume and Density
Volume : the space that mass in each object occupies.
Density: a comparison of an object’s mass to its volume. It gives an
indication of ‘how big’ something is.

Density (ρ) = Mass (m)
Volume (v)

The formula dictates that objects of high density have a lot of mass occupying
a relatively small volume.

m
ρ v
Example:
Volume and Density
What is the density of an object with a mass of 20 grams and
volume 8 cm3 ? m
Density = Mass = 20 g = 2.5g/ cm3
Volume 8 cm3 ρ v
What is the volume of a liquid with a mass of 10 grams and
density 3.5g/ml?
Volume = Mass = 10 g = 2.86 ml
Density 3.5 g/ml

1 ml = 1 cm3
 Example:
Volume and Density
Q1 : What is the density of an object with a mass of 25
grams and volume 12 cm3 ?

Q2: What is the volume of a liquid with a mass of 18 grams
and density 2.5 g/ml?
 Dilution
Adding more solvent without addition of more solute
A two-fold dilution → reduces the concentration of a solution by a factor of two
that is reduces the original concentration by one half

1:2 1:4

1:8 1:16
Using a Concentrated Solution to Make a
Dilute Solution
It is sometimes necessary to prepare a dilute solution from a
concentrated solution.
Example:
Preparing 0.1 M HCl from a concentrated HCl solution. Using a
general formula;
M1 X V1 = M2 X V2 M1 initial molar
Q: Prepare 100 ml of 0.1 M HCL using 1.0 M HCL
V1 initial volume
M2 final molar
V2 final volume
 Using a Concentrated Solution to Make a
Dilute Solution
It is sometimes necessary to prepare a dilute solution from a
concentrated solution.
Example:
Preparing 0.1 M HCl from a concentrated HCl solution. Using a
general formula;
M1 initial molar
M1 X V1 = M2 X V2
V1 initial volume
Q: Prepare 100 ml of 0.1 M HCL using 1.0 M HCL M2 final molar
1.0M X V1 = 100ml X 0.1M V2 final volume
V1 = 100 X 0.1 = 10 ml
1.0
10ml of 1.0M HCL is added to 90ml of H 2O to make 100ml of 0.1M HCL solution
Using Percentage to Prepare Solutions
Percent solution – one type of expressing concentration.
In the lab, percent solutions usually refer to grams of solute per 100 ml of
solution.
Three way of preparing percent solutions:
○ Weight to volume (w/v): weight in gram of solute per 100 ml of soln.
○ Volume to volume (v/v): mL of solute per 100 ml of soln.
○ Weight to weight (w/w): weight in grams of solutes per 100g of soln.

Preparation of the solutions in percentage are given in the next two slides.
 Moles, Molarity & Molality

No. moles (n) = Mass of substance (m)
m
Relative Formula Mass (RFM)
Mr n
Molarity (M) = moles of solute (n) Molality(m) = mole of solute
liters of solution (V)

solute and solvent
kg of solvent
Solvent by itself
n
combined

M V
 Preparing Molar Solutions

Preparing 200 ml of approximately 0.20 M NaOH
using solid NaOH
 Preparing Molar Solutions
Preparing 200 ml of approximately 0.20 M NaOH
using solid NaOH
Molar (M) = moles (n)
Volume in liter (V)

Moles (n) = Molar (M) x Volume in liter
Volume (V) (V)
in liter
=MxV = 200 ml
= 0.20 M x 0.2 L 1000 ml
= 0.04 mol = 0.2 L
 Preparing Molar Solutions – Continue …

Moles (n) = mass (m)
Molar mass (Mr)

Mass (m) = Moles (n) x Molar mass (Mr)
= 0.04 mol x (23 + 16 + 1) g/mol
= 0.04 mol x 40g/mol
= 1.6 g
m
Mr n
Balance
Analytical Balance

Principle Calibration and
“Magnetic force restoration” that uses an standardization
electromagnet to determine an object’s mass
Calibrate to maintain accuracy and precision

Extremely Accurate Cleaning
The mass can be measuring high degree Clean the weighing pan before and after use to
precision and accurately of 0.0001 to 0.00001g ensure that the weighing sample does not get
(0.1 mg to 0.01 mg) contaminated.
 Weighing using Analytical Balance
1. It is preferable to preheat it for an hour before using it.
2. Set the analytical balance to zero in the no-load condition by pressing the “tare”
button.
Chamber
3. Place the weigh boat, weigh paper, or other vessel or container in the center of the
weighing pan and then shut the glass door of the weighing chamber.
4. Check the value that was displayed after it was stabilized. The appearance of the Chamber Pan Digital
stability mark indicates a stable state. door display
handle
5. To exclude container mass from the measurement, the ‘TARE’ button is pressed to
reset the mass to zero.
6. Add the substance to be weighed after removing the container from the balance.
Avoid putting things in the balance pan because doing so can contaminate the Tare button

balance.
7. Reset the container’s balance, then wait 5-10 seconds (up to a minute) for the mass
Fig 1 Analytical balance
reading to stabilize. https://scales-measuring.com/3739-large_default/kern-
abj- 220-4nm-analytical-balance.jpg
Double Beam Balance
Zero indicator

Pan Pan

100g beam Zero adjust knob
10g beam

Main and
supplementary rider

Fig 2 Double beam balance
http://ecx.images-
amazon.com/images/I/41GypGFDPGL._SL500_AA300_.jpg
Double Beam Balance

Feature Principle Measurement
double pan balance, is a With a two-pan design based on the Featuring single weighing
scale that acts like a classic Roberval balance principle, unit and application
see-saw and gets its Double Beam Balances feature the mode. Angled beams and
name from the two additional advantages of magnetic pointer are easy to read
pans or balances on damping, beams with sliding and help reduce operator
either side of a fulcrum weights and a variety of weighing errors.
platforms.
 Weighing using Double Beam Balance
Zero indicator
1. Setup the main and supplementary rider to utmost
left end.
Pan Pan
2. Adjust the zero adjust knob (fine-tuning balancing)
knob at the right end of the beam, set the pointer of
100g beam Zero adjust
the Balance to equilibrium position zero. knob
10g beam
3. To estimate the weight of the object on the left pan
and then add suitable standard weights on the right Main and supplementary
rider
pan.
4. Move the main rider, supplementary rider to make
the pointer to equilibrium position zero.

Note: If the balance is not in use, don't put anything on the pans.
 Medium size (10 - 100g) Triple Beam Balance
Largest size (100 - 500g)
Smallest (0 - 10g)

Rider Beam
Pan Balance pointer (0
mark )

Zero adjustment
knob

Fig 3 Triple beam balance

https://tse1.mm.bing.net/th?id=OIP.TlyHOqVPs1mP-em-
L7JPnAHaEN&pid=Api&w=1050&h=596&rs=1&p=0
Triple Beam Balance

Features Measurement Weighing
Has three beams including the
1. The middle beam which is
and use 1. Riders on beam is move to leftmost
position before measure and twist
the largest size (100-500g) measure mass very precisely the zero-adjustment knob until
from 0g – 500g with reading error balance pointer with zero mark
2. The front beam which is the of +/- 0.05 gram
smallest size (0-10g) 2. Put the object and start weight from
middle beam to the front beam
3. The far beam which is the measure mass directly from the
(largest to smallest) and stop until
medium size (10-100g). objects, find mass by difference the pointer line up with zero mark.
for liquid, and measure out a
substance.
 Triple Beam Balance
The triple beam balance is an instrument used to measure mass very precisely. The device has reading
error of +/- 0.05 gram.
The name refers to the three beams including the middle beam which is the largest size (100-500g), the
front beam which is the smallest size (0-10g), and the far beam which is the medium size (10-100g).
The difference in size of the beams indicate the difference in weights and reading scale that each beam
carry. Riders on beam is move to leftmost position before measure and twist the zero-adjustment knob
until balance pointer with zero mark.
Put the object and start weight from middle beam to the front beam (largest to smallest) and stop until
the pointer line up with zero mark.
The triple beam balance can be used to measure mass directly from the objects, find mass by difference
for liquid, and measure out a substance.
pH meter
 The term pH is derived from “p,” the
mathematical symbol for negative logarithm,
and “H,” the chemical symbol for Hydrogen.

pH The formal definition of pH is the negative
logarithm of Hydrogen ion activity.

pH = -log[H+]
 Electrode in pH meter

1. pH Electrode (Measuring Electrode) 2. Reference Electrode
Components: Components:
Glass Membrane: Allows H⁺ ions to pass, Reference Junction: A porous tip for slow KCl
creating a voltage related to the hydrogen ion leakage, creating a stable interface for
concentration. measurement.
Internal Solution: Contains potassium chloride Internal Solution: Contains KCl for consistent
(KCl) for stability. contact with the solution.
Internal Electrode: Silver/silver chloride Internal Electrode: Ag/AgCl, generating a
(Ag/AgCl), in contact with the internal stable reference voltage.
solution and glass membrane, generates Function:
potential based on H⁺ concentration. Provides a constant reference potential for
Function: comparison, ensuring accurate and stable pH
Sensitive to H⁺ ions, generating an electrical readings.
potential that varies with pH, enabling pH
measurement.
 pH meter

In a combination pH probe,
the most widely used
variety, there are
actually two electrodes in
one body. One portion is
called the measuring pH
electrode, the other the
reference electrode. The
potential generated at the
junction site of the
measuring portion is due to
the free hydrogen ions
present in solution.
 pH meter

If the H+ concentration is higher
than OH- the material is acidic.
If the OH- concentration is higher
than H+ the material is basic.
7 is neutral, < is acidic, >7 is basic
 Make sure the meter is set to pH mode and adjust the temperature
to 25C

Rinse the electrode with distilled water in waste beaker

Calibration of Prepare buffer solution with 3 range of pH / pH 7, pH 4 and pH 10.

pH meter Place the electrode in the buffer solution and press measure
button

The pH of the buffer appears in the display and make sure to
record after the display stabilize

Rinse the pH electrode with distilled water before and after use
and wipe with tissue to dry the electrode

Repeat with different buffer solution and record the pH
 Application of pH measurement
Agriculture → avoid toxic if pH too low
Brewing pH 3.9-4
Corrosion prevention – pH < 4.3
Dairy industry –cheese production pH 4.7-4.9
Fermentation
Fertilizer → prevent waste of acid
Pharmaceutical → antibiotic produce from molds are grown at
precise pH →cause poison