Directorship

Question 0

How much time does a laboratory have to correct a Phase __ deficiency?

A. I.
B. II.

Answer 0

A. By the next internal inspection.

B. 30 days.

Question 1

Which agency is responsible for assigning levels of complexity to laboratory tests?

Answer 1

The FDA.

Question 2

For proficiency testing, how long must a laboratory deal with same vendor before switching to another?

Answer 2

One year.

Question 3

Waived tests:

A. Definition.
B. Examples.

Answer 3

A. Simple, relatively foolproof tests of which incorrect performance would not significantly harm the patient.

B. Urine dipstick, fecal occult blood.

Question 4

Waived testing:

A. Requirement.
B. Certificate.

Answer 4

A. One must follow the manufacturer’s instructions.

B. Certificate of waiver.

Question 5

Non-waived tests: Types.

Answer 5

Moderate-complexity.

High-complexity.

Question 6

Moderate-complexity test:

A. Example.
B. What can make it a high-complexity test.

Answer 6

A. Automated procedure (most).

B. Modification.

Question 7

High-complexity test: Example.

Answer 7

A test that has a significant manual component, e.g. identification of parasites.

Question 8

Non-waived tests: Regulatory requirements.

Answer 8

Qualified laboratory director and testing personnel.

Written procedures for testing.

Positive and negative controls on each day of testing.

Proficiency testing.

Stipulations concerning record-keeping.

Inspection every other year.

Question 9

Provider-performed microscopy: Complexity.

Answer 9

Moderate.

Question 10

Provider-performed microscopy:

A. When?
B. Method.
C. Indication.

Answer 10

A. During the patient’s visit.

B. Bright-field or phase-contrast microscopy.

C. The delay of taking the specimen to the laboratory would compromise the specimen.

Question 11

Provider-performed microscopy: Examples (4).

Answer 11

Direct wet mounts for microorganisms.

KOH preparations.

Examinations for pinworms.

Ferning tests.

Question 12

Levels of review of medical devices by the FDA.

Answer 12

Clearance.

Approval.

Question 13

Clearance of medical devices: Required form and its intent.

Answer 13

Premarket notification or 510(k): Filed by the manufacturer in order to document that the device is substantially equivalent to some FDA-approved device.

Question 14

Approval of medical devices: Required form and its intent.

Answer 14

Premarket application filed by the manufacturer as a formal validation.

Question 15

Requirements to be met by medical devices that are exempt from review by the FDA (4).

Answer 15

Proper labeling, including a statement that of device is not cleared or approved by the FDA.

Listing.

Reporting of device malfunction.

Good manufacturing practices.

Question 16

The FDA’s classification of medical devices.

Answer 16

Based on the risk associated with use of the device:

Class I, Class II, Class III.

Question 17

Branch of the FDA that regulates blood products.

Answer 17

Center for Biologics Evaluation and Research.

Question 18

Medicare: Intended beneficiaries (3).

Answer 18

Those who are

Over 65 years of age, or

Permanently disabled, or

In end-stage renal disease.

Question 19

Medicare: Parts that address reimbursement.

Answer 19

Part A: Inpatient care, home health care, and care in hospice or a skilled-nursing facility, apart from physicians’ services.

Part B: Outpatient services and inpatient physicians’ services.

Question 20

Medicare, Part B: System of reimbursement.

Answer 20

Fee-for-service.

Question 21

Medicare: Usual processors of claims.

Answer 21

Part A: Fiscal intermediaries.

Part B: Carriers.

Question 22

ICD:

A. Basis of coding.
B. Version used in billing.

Answer 22

A. Diagnoses.

B. International Coding of Diseases - Clinical Modification (ICD-CM).

Question 23

Health Care Procedural Coding System:

A. Basis of coding.
B. Levels.

Answer 23

A. Rendered services.

B. Level I consists of CPT codes, Level II is used for all other services.

Question 24

Medicare: Which billing codes must be provided in order to get reimbursed?

Answer 24

Both ICD and HCPCS codes.

Question 25

Medicare: Information required for reimbursement of pathology services.

Answer 25

Documentation of medical necessity in the form of an ICD code provided by the clinician.

Question 26

Medicare: What is the DRG?

Answer 26

Diagnosis-related group: A type of reimbursement which provides a fixed payment according to the inpatient diagnosis, regardless of the length of stay.

Question 27

Medicare: How different components of pathology services get reimbursed.

Answer 27

Professional component: Coded separately from the laboratory billing schedule.

Technical component: Covered by the DRG payment.

Question 28

Medicare: What happens when a claim for an ___ laboratory test is denied?

A. outpatient
B. inpatient

Answer 28

A. The patient may get billed; an advanced beneficiary notice (ABN) must be filed.

B. The patient does not get billed.

Question 29

Medicare: What determines payments for physicians’ services?

Answer 29

The Physician Fee Schedule, which is based on the Resource-Based Relative-Value Scale.

Question 30

Medicare: Examples of “unbundling” of laboratory services.

Answer 30

Billing separately for tests in a panel.

Billing separately for the cervix and corpus of a uterus.

Question 31

Medicare: Direct-billing law as it applies to laboratories.

Answer 31

Medicare must be billed directly by the laboratory that provides the service.

Question 32

Medicare: Stark law:

A. Synonym.
B. Intent.

Answer 32

A. Physician-self-referral law.

B. To prevent the use of “shell laboratories” that only refer testing to real laboratories but bill Medicare directly.

Question 33

Medicare: Components of the anti-kickback law.

Answer 33

A laboratory may not use items of value to induce clinicians to use their services.

When trying to attract non-Medicare patients, the laboratory may not charge less than the cost of the testing.

Question 34

Fixed vs. variable costs: Definitions.

Answer 34

Fixed costs are unaffected by the total number of tests performed. However, the fixed cost per test decreases as more tests are performed.

Variable costs are affected by the total number of tests performed. However, the variable cost per test does not change.

Question 35

Fixed costs: Examples.

Answer 35

Purchase of instruments, utilities, rent, wages.

Question 36

Direct vs. indirect costs: Definitions.

Answer 36

Direct costs are incurred directly from the performance of tests; indirect costs are not.

Question 37

Direct vs. indirect costs: Examples.

Answer 37

Direct costs: Purchase of instruments, reagents.

Indirect costs: Rent, utilities, custodial services, depreciation.

Question 38

Over which costs does a laboratory director have the greatest control?

Answer 38

Over direct costs and variable costs.

Question 39

Unit cost:

A. Definition.
B. Derivation.

Answer 39

A. The total cost per test.

B. The sum of the variable costs and fixed costs per test.

Question 40

Break-even point:

A. Definition.
B. Relevance.

Answer 40

A. The number of tests to be performed in order for costs to balance revenue, i.e. where net income equals zero.

B. Can help determine whether to offer a test or send it out.

Question 41

Break-even point: Formula.

Answer 41

N = FC ÷ (R − VC).

N is the number of tests performed.
FC is the fixed cost.
VC is the variable cost (per test).

Question 42

Allowances and bad debt: Definitions.

Answer 42

Allowances: Not getting reimbursed as much as expected.

Bad debt: Not getting reimbursed at all.

Question 43

Estimation of revenue based on allowances and bad debt.

Answer 43

Revenue = total charges − allowances − bad debt.

Question 44

Budgeting: When does it begin?

Answer 44

About 6 months before the beginning of the budgeted year.

Question 45

Budget: Components (4).

Answer 45

Capital budget.

Personnel budget.

Operating budget.

Allocation budget.

Question 46

Capital budget:

A. Purpose.
B. How to operate when it is restricted.

Answer 46

A. The purchase of more expensive items such as analyzers.

B. If an analyzer is leased instead of purchased, the cost of the analyzer can be accounted for in the operating budget instead.

Question 47

Personnel budget: How typically expressed.

Answer 47

As full-time equivalents.

Question 48

Operating budget:

A. Purpose.
B. Examples of covered items.

Answer 48

A. To account for day-to-day operations.

B. Reagents, send-out tests, blood products.

Question 49

Allocation budget: Purpose.

Answer 49

To account for the laboratory’s share of the hospital’s fixed costs, e.g. utilities, administration.

Question 50

Gaussian distribution: Adjective used to describe it.

Answer 50

Parametric, i.e. expressible by a mathematical equation.

Question 51

Mean, median, and mode: Definitions.

Answer 51

Mean: Arithmetic average of all data points.

Median: Middle value of the range of values.

Mode: Most frequently occurring value.

Question 52

Mean, median, and mode:

A. In a perfect Gaussian distribution.
B. In a positively skewed distribution.

Answer 52

A. Mean = median = mode.

B. Mean > median > mode.

Question 53

Standard deviation: Relevance to the shape of the Gaussian curve.

Answer 53

Narrow curve: Small standard deviation.

Wide curve: Large standard deviation.

Question 54

Standard deviation: Formula.

Answer 54

SD = √[Σ(xi − mean)² ÷ (n − 1)]

Question 55

Standard deviation: Relevance to percentiles in the Gaussian curve.

Answer 55

−1 SD to +1 SD: 68.2% of the population.

−2 SD to +2 SD: 95.5% of the population.

−3 SD to +3 SD: 99.7% of the population.

Question 56

Analytical accuracy vs. diagnostic accuracy.

Answer 56

Analytic accuracy: Extent to which a test result approximates the “true value”.

Diagnostic accuracy: Ability of a test to distinguish between groups of patients.

Question 57

Analytical accuracy:

A. Quantification.
B. How to control it.

Answer 57

A. It has no numerical value.

B. Through periodic calibration.

Question 58

Precision:

A. Definition.
B. What influences it.
C. How to control it.

Answer 58

A. The reproducibility of a test result.

B. The random variability inherent in a process.

C. Through daily testing of QC reagents.

Question 59

Precision within a run:

A. Determinant.
B. Expected value.

Answer 59

A. Concentration of the analyte, with low concentrations causing lower precision.

B. 1 to 10%.

Question 60

Precision between runs: Determinants (2).

Answer 60

Changing environmental conditions.

Changing technologists (operator bias).

Question 61

Coefficient of variation:

A. Purpose.
B. Formula.

Answer 61

A. To express the precision.

B. CV = SD/mean × 100%.

Question 62

Clinical sensitivity: Formula.

Answer 62

Sensitivity = TP/(TP + FN).

Question 63

Clinical specificity: Formula.

Answer 63

Specificity = TN / (TN + FP).

Question 64

Analytical sensitivity:

A. Synonym.
B. Definition.

Answer 64

A. Limit of detection.

B. The lowest detectable concentration of analyte.

Question 65

Analytical specificity: Definition.

Answer 65

Ability of the assay to detect a certain analyte in the presence of many other substances.

Question 66

Positive predictive value:

A. Definition.
B. Formula.

Answer 66

A. The percentage of positive results that actually indicate disease.

B. PPV = TP / (TP + FP).

Question 67

Negative predictive value:

A. Definition.
B. Formula.

Answer 67

A. The probability of no disease when the test is negative.

B. NPV = TN / (TN + FN).

Question 68

Prevalence:

A. Effect on PPV and NPV.
B. Effect on sensitivity and specificity.

Answer 68

A. A low prevalence decreases PPV and increases NPV; the converse is also true.

B. No effect.

Question 69

Relative risk: Definition.

Answer 69

The ratio of the risk, in the presence of a risk factor, to the baseline risk.

Question 70

Relative risk: Formula.

Answer 70

RR =

(Number with X who develop Y ÷ Number with X) / (Number in population who develop Y ÷ Number in population).

Question 71

Scales:

A. Interval.

B. Ordinal.

C. Nominal.

Answer 71

A. The numbers have their usual mathematical values, e.g. 135 mg/dL.

B. The numbers have assigned values, e.g. 1+, 4+.

C. Categories are used, e.g. positive, negative.

Question 72

Graphs used for illustrating diagnostic accuracy (2).

Answer 72

Receiver-operating-characteristic curve.

Dot diagram.

Question 73

ROC curve: Axes.

Answer 73

Y-axis: Sensitivity.

X-axis: 1 − specificity.

Question 74

ROC curve: How it is used (2).

Answer 74

Points along the curve: Estimation of diagnostic accuracy (sensitivity and specificity) at different cutoffs.

Area under the curve (the c statistic): Quantitation of diagnostic accuracy.

Question 75

ROC curve: Slope and area under curve of a ___.

A. test with perfect discrimination.
B. test with no discrimination.

Answer 75

A. Infinity; 1.0.

B. 1.0; 0.5.

Question 76

Dot diagram: How constructed.

Answer 76

Quantitative results are expressed as dots, each of which is placed in one of two columns: “disease” or “no disease”.

One can then see how well the test distinguishes at various cutoffs (horizontal lines).

Question 77

Reference intervals: Number of values required.

Answer 77

The minimum number required for 90% confidence at the limits of the 95th percentile (2.5% of individuals will be below this range, 2.5% above it).

In practice, at least 20 healthy individuals who are representative of the population being tested.

Question 78

How a laboratory can obtain a reference interval for an analyte (2).

Answer 78

Establish its own reference interval.

Take a published or manufacturer’s recommended reference interval and verify it for that particular laboratory.

Question 79

Examples of tests for which population-based reference intervals are not useful (2).

Answer 79

Serum lipid levels: Range is based on medical decision-points.

MCV: Varies much between individuals but little within an individual.

Question 80

How new methods or instruments are evaluated before implementation (2).

Answer 80

FDA-approved test: Verification.

Non-approved: Validation.

Question 81

Method verification: Requirements (3).

Answer 81

The laboratory must

Verify that it can reproduce manufacturer’s claims for precision, accuracy, and reportable range.

Verify reference intervals.

Establish parameters for calibration and QC.

Question 82

Method verification: How the laboratory might go about meeting the requirements (2).

Answer 82

Correlation study between the new instrument and an existing one or an outside reference laboratory.

Correlation between new instruments of the same model.

Question 83

Method validation: Requirements (2).

Answer 83

The laboratory must

Meet all the requirements of method verification.

Assess sensitivity, specificity, and PPV.

Question 84

Parts of a complete validation plan (3).

Answer 84

Validation elements.

Number of specimens to suffice for each element.

Predetermined points of passing or failing.

Question 85

Calibration:

A. Definition.
B. When performed.

Answer 85

A. Adjusting the instrument to report the known concentration of analyte in a calibrator.

B. At least every 6 months.

Question 86

Calibrators: Examples (4).

Answer 86

Samples from patients.

Commercial calibrators.

Samples from proficiency tests.

Controls.

Question 87

Accuracy: How assessed?

Answer 87

By comparison with a previously validated method or with a reference method.

Question 88

Bias: Definition.

Answer 88

The difference between the measured value and the “true” value.

Question 89

Proportional bias:

A. Appearance on a correlation study.
B. Relevance to values of analyte.

Answer 89

A. The y-intercept is the same as that of the reference method, but the slope is different.

B. Bias is clinically less significant at lower values.

Question 90

Types of method validation.

Answer 90

Primary: Based on a previously validated assay or a reference method.

Secondary: Validation between instruments.

Question 91

Analytic specificity: How to test it.

Answer 91

Perform a “recovery” experiment, in which a known quantity of analyte must be detected in the presence of interfering substances such as bilirubin, lipids, free hemoglobin.

Question 92

Analytical sensitivity: Determination.

Answer 92

Measure a blank sample (no analyte) 20 times.

Calculate the mean and the SD.

The value at 2-3 standard deviations above zero is considered the analytical sensitivity.

Question 93

Functional sensitivity:

A. Synonym.
B. Definition.

Answer 93

A. Limit of quantitation.

B. The lowest reliably quantified concentration of analyte, reliability being determined by the CV (often 20%).

Question 94

Carryover studies: When performed.

Answer 94

When the analyte has a wide range of concentration, e.g. β-hCG.

Question 95

Carryover studies: How performed.

Answer 95

Six samples are used, four of low concentration (samples 1, 2, 3, and 6) and two of high concentration (samples 4 and 5).

Carryover = result of sample 6 − (average of results of 1, 2, and 3 ÷ average of results of 4 and 5).

Question 96

Carryover studies: Desirable result.

Answer 96

A carryover of <0.015 (1.5%).

Question 97

Analytical measuring range:

A. Synonym.
B. Definition.

Answer 97

A. Linear range.

B. The range over which reliable measurements can be obtained.

Question 98

Analytical measurement range: Determination.

Answer 98

Measuring serially diluted samples that contain the analyte of interest.

Question 99

Clinical reportable range:

A. Definition.
B. Relationship to the AMR.

Answer 99

A. The highest and lowest values that can be reported accurately.

B. CRR and AMR typically have the same lower limit, but the CRR may have a higher upper value, depending on the feasibility of dilution of samples.

Question 100

Specimen stability: Definition.

Answer 100

How long a stored specimen continues to produce reliable results.

Question 101

How often must the medical director review procedures (3)?

Answer 101

Initially.

With each change.

Annually.

Question 102

Reagents for quality control:

A. Where obtained?
B. How designed?

Answer 102

A. From the manufacturer.

B. They are directed to values at or near the cutoffs.

Question 103

Quality control: What is done when a new lot of control reagents is received (4)?

Answer 103

It is reconstituted.

It is run at least 20 times on the instrument.

The results are used to calculate mean and SD.

The mean and the SD are used to make a Levey-Jennings chart.

Question 104

Quality control: Commutable reagents.

Answer 104

Those that are biologically similar to patients’ samples.

Most QC reagents are non-commutable.

Question 105

Quality control: According to the CLIA, how often must it be performed in the laboratory?

Answer 105

Two levels of QC every 24 hours, or more often if recommended by the manufacturer.

Question 106

Quality control:

A. When is a result considered in control?
B. What is done with other results?

Answer 106

A. When it falls within 2 SD of the mean.

B. Westgard’s rules are applied in order to determine whether the result is in control.

Question 107

The 1:3s rule:

A. Definition.
B. Purpose.

Answer 107

A. One value is found to be 3 SD from the mean.

B. To detect imprecision.

Question 108

The 2:2s rule:

A. Definition.
B. Purpose.

Answer 108

A. Two consecutive values are found to be >2 SD from the mean, on the same side of it.

B. To detect imprecision and systematic bias.

Question 109

The R:4s rule:

A. Definition.
B. Purpose.

Answer 109

A. Two values are separated by >4 SD.

B. To detect random error.

Question 110

The 4:1s rule:

A. Definition.
B. Purpose.

Answer 110

A. Four consecutive values are found at >1 SD from the mean, on the same side of it.

B. To detect systematic bias.

Question 111

The 10:mean rule:

A. Definition.
B. Purpose.

Answer 111

A. Ten consecutive values are found to be on the same side of the mean.

B. To detect systematic bias.

Question 112

Causes of error: Systematic (4).

Answer 112

Poor calibration.

Defective blanks.

Degraded reagents or instrument components.

Question 113

Causes of error: Random (4).

Answer 113

Bubbles.

Under-filled tubes.

Error by technologist.

Question 114

Addressing results that are out of control: First two steps.

Answer 114

1. Check the reagents and the instrument.
2. Repeat testing on a new aliquot of QC reagent. Significant correction suggests deterioration of the previously used QC reagent.

Question 115

Addressing results that are out of control: Next three steps.

Answer 115

Thorough recheck of instrument and reagents and correction of problems.

Retesting of QC reagents.

Retesting of patients’ samples before reporting.

Question 116

Addressing results that are out of control: What to do if all troubleshooting fails.

Answer 116

Take the instrument offline and call for formal maintenance.

Question 117

Constant bias:

A. Appearance on a correlation study.
B. Relevance to values of analyte.

Answer 117

A. The slope is the same as that of the reference method, but the y-intercept is different.

B. Bias is clinically less significant at higher values.

Question 118

Type of error that corresponds with

A. A widening distribution of results.
B. A shift of drift of results.

Answer 118

A. Random error or imprecision.

B. Systematic bias.

Question 119

Proficiency testing:

A. How many times a year?
B. How many samples per survey?
C. Passing score.

Answer 119

A. Three.

B. Five.

C. 80%.

Question 120

Proficiency testing: What happens if the laboratory fails a survey (2)?

Answer 120

The laboratory must exceed 80% on the next 2 surveys or face possible suspension of certification.

The cause of the failure must be found and corrected.

Question 121

Proficiency testing: Possible causes of failure (2).

Answer 121

Problems with reagents: Check reagent logs.

Problems with instrument: Check calibration and maintenance log.

Question 122

Standard deviation index: Formula.

Answer 122

SDI = (laboratory’s result − mean for peer group) ÷ SD for peer group.

Question 123

Proficiency testing: Screening rule.

A. Question.
B. Implication.

Answer 123

A. Do 2 or more of the 5 results exceed 1 SDI?

B. Proceed to evaluate the data according to the remaining rules.

Question 124

Proficiency testing: Mean rule.

A. Question.
B. Implication.

Answer 124

A. Does the average of the 5 SDIs exceed 1.5?

B. Systematic error is significant.

Question 125

Proficiency testing: 3 SDI rule.

A. Question.
B. Implication.

Answer 125

A. Is any result beyond 3 SDIs?

B. Random error is significant.

Question 126

Proficiency testing: 4 SDI rule.

A. Question.
B. Implication.

Answer 126

A. Are any 2 results >4 SDI apart?

B. Random error is significant.

Question 127

Proficiency testing: What is a “split” sample?

Answer 127

A patient’s sample that is divided between two laboratories as an alternative means of proficiency testing.

Question 128

Proficiency testing: How are target ranges assigned for ___ samples?

A. commutable

B. non-commutable

Answer 128

A. Based on a reference method.

B. Based on the mean and SD of data from the peer group, using the SD index.

Question 129

Which phase of testing accounts for most of the errors in laboratory medicine?

Answer 129

The pre-analytical phase.

Question 130

Pre-analytical errors: Examples (5).

Answer 130

Patient’s age.

Selection of test.

Identification of patient.

Collection of specimen.

Integrity of sample.

Question 131

How often does a patient’s test tube contain a sample from a different patient?

Answer 131

About 1 time in 2500.

Question 132

What should be done with a sample when a plasma-based test cannot be performed within 1-2 hours?

Answer 132

It should be centrifuged within 1 hour and stored at 4-6 degrees.

Question 133

Why must serum or plasma be separated from red cells for many tests?

Answer 133

To prevent spurious results due to continued metabolism, e.g. low glucose, high lactate.

Question 134

Red-top tube:

A. Additive.
B. Purpose.

Answer 134

A. Silica (plastic tubes) or none (glass tubes).

B. Serum chemistry, serology.

Question 135

Green-top tube:

A. Additive.
B. Purpose.

Answer 135

A. Heparin.

B. Plasma chemistry (e.g. CK, troponin).

Question 136

Blue-top tube:

A. Additive.
B. Purpose.

Answer 136

A. Citrate.

B. Coagulation tests.

Question 137

Black-top tube:

A. Additive.
B. Purpose.

Answer 137

A. Citrate.

B. Erythrocyte-sedimentation rate.

Question 138

Lavender-top tube:

A. Additive.
B. Purpose.

Answer 138

A. EDTA.

B. Cell counts.

Question 139

Yellow-top tube:

A. Additive.
B. Purpose.

Answer 139

A. Citrate and dextrose.

B. Blood-bank tests, HLA typing.

Question 140

Gray-top tube:

A. Additive.
B. Purpose.

Answer 140

A. Sodium fluoride.

B. Glucose, lactate.

Question 141

Order of draw: Plastic tubes (5).

Answer 141

1. Culture.
2. Blue-top.
3. Red-top.
4. Serum-separator tube.
5. Additive tubes: Green, lavender, gray.

Question 142

Order of draw: Glass tubes (5).

Answer 142

Same as for plastic tubes, except that red-top precedes blue-top.

Question 143

Analyte that can seem alarmingly high in healthy adolescents.

Answer 143

Alkaline phosphatase.

Question 144

Changes in analytes that come with advanced age (4).

Answer 144

Decreased creatinine clearance.

Decreased glucose tolerance.

Increased lipids.

Increased releasing hormones.

Question 145

Analytes that are affected by eating (5).

Answer 145

Glucose.

Triglycerides.

Bilirubin.

Gastrin, insulin.

Question 146

Changes in analytes that are brought about by prolonged fasting.

Answer 146

Increased: Ketones, bilirubin.

Decreased: Albumin, potassium, magnesium.

Question 147

Analytes that may be increased by ___ exercise.

A. Recent (3).
B. Vigorous.

Answer 147

A. CK, LDH, AST.

B. Neutrophil count.

Question 148

Types of analyte that increase when the patient is standing (3).

Answer 148

Proteins.

Substances bound to proteins, e.g. calcium.

Formed elements, e.g. red blood cells.

Question 149

Analytes that are affected by fist-clenching or prolonged tourniquet time (2).

Answer 149

Potassium, lactate.

Question 150

Analytes that are increased in ___.

A. Serum (4).
B. Plasma.

Answer 150

A. Calcium, magnesium, LDH, potassium.

B. Plasma proteins, esp. fibrinogen.

All of these occur secondary to clotting.

Question 151

Analytes whose concentrations may be factitiously changed by paraproteinemia (5).

Answer 151

Decreased: Bilirubin, albumin, uric acid, sodium.

Increased: Calcium.

Question 152

How paraproteinemia may lead to hypercalcemia (3).

Answer 152

Factitious hypercalcemia due to the turbidity of the paraprotein.

True total hypercalcemia due to increased transport of calcium by the paraprotein (ionized calcium remains normal).

True total and ionized hypercalcemia due to the myeloma itself.

Question 153

Factitious hyperkalemia caused by leukocytosis or thrombocytosis: Serum vs. plasma.

Answer 153

Potassium is significantly higher in the serum.

With true hyperkalemia, there should be little or no difference.

Question 154

Chemical analyte that is increased with CML.

Answer 154

B₁₂.

Question 155

Post-analytical errors: Examples (4).

Answer 155

Errors in

Issuing the report.

Reading (or hearing) the report.

Interpreting the report.

Responding to the report.

Question 156

Estimation of body surface area: Formula.

Answer 156

BSA ≈ √(height × weight ÷ 3600).

Question 157

β₂

Answer 157

β₂