ELECTROPHORESIS

Question 1

Seen in diagnostic laboratories

Answer 1

ELECTROPHORESIS

Question 2

migration of charged solutes or particles in a solid medium under the influence of an electrical field/current.

Answer 2

ELECTROPHORESIS

Question 3

Two types of electrophoresis:

Answer 3

Zone electrophoresis
Iontophoresis

Question 4

– separation of macromolecules on an electromagnetic field or support medium under the influence of electric current

Answer 4

Zone electrophoresis

Question 5

– separation of small particles such as ions or electrolytes (Ex. Separation of Calcium ions in a substance)

Answer 5

Iontophoresis

Question 6

– most important macromolecule

Answer 6

Protein

Question 7

Zwitterion

Answer 7

AMPHOLYTE

Question 8

amphoteric pH (can act as either acid+cathode or base-anode) depending upon the support medium where they are found

Answer 8

AMPHOLYTE (Zwitterion)

Question 9

takes a positive charge (binds protons) at an acidic pH and migrates toward the cathode

Answer 9

Cathode

Question 10

negative electrode

Answer 10

Cathode

Question 11

it tends to bind with proton = receives a proton = carries a positive charge

Answer 11

Cathode

Question 12

takes a negative charge (loses protons) at an alkaline pH and migrates toward the anode - more common

Answer 12

Anode

Question 13

positive electrode

Answer 13

Anode

Question 14

it tends to donate and give up proton = loses a proton = carries a negative charge

Answer 14

Anode

Question 15

generated from electrophoresis

Answer 15

ELECTROPHORETOGRAM

Question 16

display of protein zones, each one (fraction) sharply separated from neighboring zones on the support medium/material

Answer 16

ELECTROPHORETOGRAM

Question 17

Per column represents one [?] (serum or any biological sample).

Answer 17

sample

Question 18

Different fractions per column represents one [?].

Answer 18

protein fraction

Question 19

The thicker the protein zone, the higher the [?].

Answer 19

protien concentration

Question 20

FACTORS AFFECTING MIGRATION:

Answer 20

Net electrical charge of molecule (pH of buffer)
MW of the particle
Strength of the electrical field
Type of support medium

Question 21

The heavier the protein, the slower it migrates

Answer 21

MW of the particle

Question 22

Ex. Serum protein electrophoresis – smallest protein founf in normal serum: [?], which migrates the fastest

Answer 22

Albumin

Question 23

Constantly maintained

Answer 23

Strength of the electrical field

Question 24

A strip of paper can be moistened using a specific buffer to be used for electrophoresis.
The specific sample subjected to electrophoresis will be applied.
The filter paper can be placed between two glass slides.
Both ends of the filter paper (electrodes) must be in contact with the electrolyte solution found in the two chambers (containers)
Electric current will be applied to facilitate the separation of proteins placed on the paper.

Answer 24

PAPER ELECTROPHORESIS

Question 25

PAPER ELECTROPHORESIS DRAWBACKS

Answer 25

excessive background failing
electrophoresis time may be longer when paper is utilized

Question 26

too many shadows found per fraction instead of very distinct, clearly demarcated zones

Answer 26

excessive background failing

Question 27

Type of support medium

Answer 27

1. Paper
2. Starch (starch gel)
3. Cellulose acetate
4. Agarose gel
5. Polyacrylamide Gel

Question 28

medium is prepared before electrophoresis

Answer 28

Starch (starch gel)

Question 29

greater resolution

Answer 29

Cellulose acetate

Question 30

faster & permanent

Answer 30

Cellulose acetate

Question 31

distinct zones are separated

Answer 31

Cellulose acetate

Question 32

most commonly used in electrophoresis

Answer 32

Cellulose acetate

Question 33

most commonly used in electrophoresis

Answer 33

Agarose gel

Question 34

High Resolution Electrophoresis

Answer 34

Polyacrylamide Gel

Question 35

most commonly used medium in isoelectric focusing

Answer 35

Polyacrylamide Gel

Question 36

• 45 minutes to 1 hour

Answer 36

AGAROSE GEL ELECTROPHORESIS

Question 37

1. Mix the agarose with the buffer of choice
2. Heated in a microwave until such time that the buffer agarose is completely dissolved
3. The agarose mixture will be poured into the mould
   4 . At one end of the mould, a comb is inserted

Answer 37

AGAROSE GEL ELECTROPHORESIS

Question 38

TYPES OF BUFFER

Answer 38

1. Barbital (pH 8.6)
2. Citric Acid – PO4 (pH 6.0-6.2)
3. Tris-Boric EDTA (pH 8.4-8.6)

Question 39

Buffer: Citric Acid
Solid support: Agarose Gel

Answer 39

Citrate-agar electrophoresis
Citrate-phosphate-agar electrophoresis

Question 40

Buffer: Alkaline solution
Solid support: Cellulose acetate

Answer 40

Tris-Boric EDTA (pH 8.4-8.6)
Tris-EDTA-Boric

Question 41

• for preservation

Answer 41

FIXATIVE

Question 42

TYPES OF FIXATIVE

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1. Methanol
2. Cyclohexanol
3. Acetic acid
4. Dioxane

Question 43

• to allow visualization of the protein zones that have been separated

Answer 43

STAINS

Question 44

Protein stains:

Answer 44

• Amido black or Naphthol blue black
• Bromphenol blue
• Coomasie Brilliant blue
• Nigrosin
• Ponceau S dye

Question 45

Isoenzymes:

Answer 45

• Nitrotetrazoleum Blue

Question 46

Lipoproteins (HDL, LDL, VLDL):

Answer 46

• Fat Red 7B (Sudan Red)
• Oil Red O
• Sudan Black B

Question 47

are separated based on their isoelectric pH

Answer 47

Proteins

Question 48

are made up of amino acids

Answer 48

Proteins

Question 49

is determined by the type of amino acid that predominates in their structure on the basis of acidity (neutral, acidic, basic)

Answer 49

isoelectric pH

Question 50

An electrophoretic method in w/c proteins are separated on the basis of their

Answer 50

pI (isoelectric pH)

Question 51

Makes use of the property of proteins that their net charges are determined by the [?] of their local environment

Answer 51

pH

Question 52

net electrical charges

Answer 52

(+), (-) or (0)

Question 53

If the # of acidic groups (in protein) exceeds # of basic groups, the pI of the protein will be at a [?] pH (ACIDIC PROTEIN)

Answer 53

low

Question 54

If the basic group > acidic groups, pI will be [?] (BASIC PROTEIN)

Answer 54

high

Question 55

Proteins show considerable variation in pI, but pI values fall in the range pH [?] (many having pIs between pH 4-7)

Answer 55

3-12

Question 56

REQUIREMENTS FOR ISOELECTRIC FOCUSING

Answer 56

1. Establishing pH gradient
2. Gel for Isoelectric Focusing

Question 57

1. Establishing pH gradient

Answer 57

a. Carrier Ampholytes (Amphoteric electrolytes)
b. Acrylamide buffers

Question 58

2. Gel for Isoelectric Focusing

Answer 58

a. Polyacrylamide Gel

Question 59

most commonly used in isoelectric focusing to maintain a pH gradient

Answer 59

Acrylamide buffers

Question 60

• Mixtures of molecules containing multiple aliphatic amino & carboxylate groups (buffer molecules)

Answer 60

a. Carrier Ampholytes (Amphoteric electrolytes)

Question 61

• Included directly in IEF gels

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a. Carrier Ampholytes (Amphoteric electrolytes)

Question 62

• Derivatives of Acrylamide containing both reactive double bonds & buffering groups

Answer 62

b. Acrylamide buffers

Question 63

• Covalently incorporated in PAG at the time of casting

Answer 63

b. Acrylamide buffers

Question 64

• polymerized with an initiator system including Riboflavin (initiator) for photo-polymerization

Answer 64

a. Polyacrylamide Gel

Question 65

• large-pore convective matrices

Answer 65

a. Polyacrylamide Gel

Question 66

1. A stable pH gradient is established in the gel after application of an electric field.
2. A protein solution is added and an electrical field is reapplied.
3. After staining, proteins are to be distributed along a pH gradient, according to pH values

Question 67

Addition of carrier ampholyte or acrylamide buffers into the support medium

Answer 67

1. A stable pH gradient is established in the gel after application of an electric field.

Question 68

Allow the support medium to solidify = POLYACRYLAMIDE GEL

Answer 68

2. A protein solution is added and an electrical field is reapplied.

Question 69

Available locations for electric current to flow through the medium.

Answer 69

2. A protein solution is added and an electrical field is reapplied.

Question 70

On the surface of the solidified polyacrylamide gel, place the protein solution.

Answer 70

2. A protein solution is added and an electrical field is reapplied.

Question 71

Followed by the application of electric current.

Answer 71

2. A protein solution is added and an electrical field is reapplied.

Question 72

After appropriate separation time;

Answer 72

2. A protein solution is added and an electrical field is reapplied.

Question 73

Stains are used to visualize protein zones that have been separated

Answer 73

3. After staning, proteins are to be distributed along a pH gradient, according to pH values

Question 74

AUTOMATION ADVANTAGES:

1. [?] results
2. Increase in the [?] performed
3. Saves [?]
4. Eliminates the need for [?]
5. [?]
   6 . Errors in [?] are reduced
6. Better [?]

Answer 74

Rapid
number of tests
time and effort
personnel increase
Economical
calculations & transcriptions
precision & accuracy

Question 75

• introductory of the first automated analyzer by Technicon

Answer 75

1957

Question 76

: sequential batch analyzer capable of providing single test result on approximately 40 samples per hour

Answer 76

Continuous flow

Question 77

• Technicon instruments w/c were next developed

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Simultaneous Multiple Analyzer (SMA)

Question 78

With multiple channels (for diff. tests)

Answer 78

Simultaneous Multiple Analyzer (SMA)

Question 79

6-12 test results simultaneously at the rate of 360 - 720 tests per hour

Answer 79

Simultaneous Multiple Analyzer (SMA)

Question 80

• specialty area w/ rapidly developing arsenal of analyzers

Answer 80

IMMUNOCHEMISTRY

Question 81

Immunological techniques (application of antigen antibody reaction) for assaying drugs, specific proteins, tumor markers & hormones

Answer 81

Fluorescence Polarization
Immunoassay
Nephelometry
Chemiluminescent Detection

Question 82

BASIC APPROACHES OF AUTOMATED ANALYZERS

Answer 82

I. CONTINUOUS - FLOW
II. CENTRIFUGAL ANALYSIS
III. DISCRETE ANALYSIS

Question 83

• Liquids (reagents, diluents & samples) are pumped through a system of continuous tubing

Answer 83

I. CONTINUOUS - FLOW

Question 84

• Samples are introduced in a sequential manner, following each other through the same network

Answer 84

I. CONTINUOUS - FLOW

Question 85

• Batch analysis can be used (e.g. large # of specimen in one run)

Answer 85

I. CONTINUOUS - FLOW

Question 86

• More sophisticated continuous flow anayzers
  Use parallel single channels to run multiple tests on each sample (e.g. SMA & SMAC)

Answer 86

I. CONTINUOUS - FLOW

Question 87

• Major drawbacks: significant carry-over problems & wasteful use of continuously flowing reagents

Answer 87

I. CONTINUOUS - FLOW

Question 88

• More sophisticated continuous flow anayzers

Answer 88

I. CONTINUOUS - FLOW

Question 89

• Use parallel single channels to run multiple tests on each sample (e.g. SMA & SMAC)

Answer 89

I. CONTINUOUS - FLOW

Question 90

• Uses the force generated by centrifugation to transfer & then contain liquids in separate cuvets for measurement

Answer 90

II. CENTRIFUGAL ANALYSIS

Question 91

• Capable of running multiple samples, one test ata time, ina batch

Answer 91

II. CENTRIFUGAL ANALYSIS

Question 92

• MAJOR ADV.: batch analysis (e.g. COBAS - Bio by Roche Diagnostics)

Answer 92

II. CENTRIFUGAL ANALYSIS

Question 93

• Most popular & versatile

Answer 93

III. DISCRETE ANALYSIS

Question 94

• Separation of each sample & accompanying reagents in a separate container

Answer 94

III. DISCRETE ANALYSIS

Question 95

• Capability of running multiple tests one sample at a time OR multiple samples one test ata time
• Random access, stat capabilities

Answer 95

III. DISCRETE ANALYSIS