#TheCheckPointOnline ~ Med Tech Online Review

Posted on May 2, 2020March 1, 2023 by Doc Kriz

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Source: https://www.prc.gov.ph/sites/default/files/2022-1589_2023calendarSchedule.pdf

MEMORY CELL EDITION (MCE)

Description:

A course that aims to provide a comprehensive review of topics PER BOARD EXAM SUBJECT based on the PRC Table of Specifications.

Highlights and Inclusions:

REVIEW STYLE OPTIONS:
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  - See our schedule below
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  - Enhancement Exams with rationalization
  - Mastery Sessions
  - Drills
  - Special lectures for selected subjects
  - *MolBio will only include pre/post-test, lecture, and enhancement exams
- GENERAL ACTIVITIES
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Schedule and Review Fees for AUGUST 2023 MCE:

Dates include INDEPENDENT STUDY TIME (ISTs) or FREE DAY
NO SUNDAY CLASSES
You may actually enroll now and use the currently available review materials and then join again when the new batch intended for August 2023 starts in May without paying another fee.
UNDERGRADUATES ARE WELCOME TO ENROLL
AUGUST 2023 MCE REVIEW WILL START ON 2nd/3rd week of May.

ACTIVITY	TARGET DATES	REVIEW FEE
REFRESHMENT WEEK	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
GENERAL ORIENTATION & MENTORING	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
OPENING WORSHIP NIGHT	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
MENTAL HEALTH SESSION	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
CC	TO BE ANNOUNCED	P3100
BMVP (Bacte, MycoViroPara)	TO BE ANNOUNCED	P3100
CM	TO BE ANNOUNCED	P1600
HEMA	TO BE ANNOUNCED	P3100
ISBB	TO BE ANNOUNCED	P3100
HTMLE	TO BE ANNOUNCED	P1600
MOLECULAR BIOLOGY*	TO BE ANNOUNCED	P1600
Drills	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
MOCK BOARDS	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
Co-MEMORY-Ate	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
GRAND WORSHIP DAY AND SEND-OFF	TO BE ANNOUNCED	FREE FOR ALL MEMORY CELLS AND END CELLS
TOTAL FEE	All schedules inclusive of lecture days, ISTs, exams, ratio, and mastery sessions except MolBio (only includes lectures, notes, and enhancement exams)	P17,200

TARGET SCHEDULE OF ACTIVITIES FOR AUGUST 2023 MTLE REVIEW

SEE THE SCHEDULE HERE: MARCH 2023 MCE SCHEDULE

AUGUST 2023 MCE REVIEW WILL START ON
2nd/3rd week of May.
Please wait for the official announcement soon.

Watch this for a more detailed explanation of the MCE review course.

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WHO CONDUCTS THE LECTURES?

Dra. Krizza-Almond S. Aguilar-Salido will handle most of the subjects but there will be invited special lecturers for a few subjects.

For a list of special lecturers, please click this.

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Lecture Notes

Med Tech Mycology Notes

Posted on April 29, 2020May 6, 2020 by Doc Kriz

FUNGI

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CHARACTERISTICS:

Eukaryotic
Thallophytes
- have true nuclei
- heterotrophic members of the plant family that lack stems and roots
Lack chlorophyll
Larger and with more complex morphology than the bacteria
Chitin in the cell wall
Ergosterol in the cell membrane
Saprophytic nature (derive nutrition from organic materials)
Lack of susceptibility to antibacterial antibiotics

TWO PHASES:

Multicellular MOLD – fluffy, cottony, woolly, or powdery mycelial mass, grows at 25°C
Unicellular YEAST – moist, creamy, opaque or pasty, resembling bacterial colony, grows from 35°C to 37°C

DIMORPHIC FUNGI – capable of two phases
Mold at 25°C to 30°C – INFECTIVE TO MAN
Yeast at 37°C – TISSUE/IN VIVO/INVASIVE

PARTS:

MYCELIUM – intertwining structure composed of tubular filaments known as HYPHAE
- Vegetative portion or thallus – grows in or on a substrate and absorbs water and nutrients
- Reproductive or aerial part – contains fruiting bodies that produce reproductive structures (conidia or spores); extends above the agar surface

HYPHAE – microscopic unit of fungi
- Septate – contain cross-walls
  - All fungi except Zygomycetes
- Aseptate/Coenocytic – continuous, without cross-walls
  - ZYGOMYCETES (Rhizopus, Mucor)

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FUNGAL REPRODUCTION:

SEXUAL – meiosis (reduction division of two fertile cells) followed by merging of the cells and nuclear fusion occurs
- PERFECT FUNGI – fungi that exhibit sexual phase
- ASCOSPORES – contained in a saclike ASCUS
  - CLEISTOTHECIUM – large, round, multicellular structure that surrounds the asci until it ruptures, releasing ascospores
- BASIDIOSPORES – contained in a club-shaped BASIDIUM
- OOSPORES – fusion of cells from two separate, nonidentical hyphae
- ZYGOSPORES – fusion of two identical cells arising from the same hypha
ASEXUAL – involves only mitosis with nuclear and cytoplasmic division
- IMPERFECT FUNGI – do not exhibit sexual phase
- SPORANGIOSPORES – asexual spores contained in sporangia (sacs) and produced terminally on sporangiophores or aseptate hyphae
  - UNIQUE TO THE ZYGOMYCETES
- CONIDIA – asexual spores produced either singly or multiply in long chains or clusters by specialized vegetative hyphae (conidiophores)
  - MACROCONIDIA – large, usually septate
    - Club, oval, or spindle shaped
    - Thick or thin walled
    - Spiny (echinulate) or smooth surface
  - MICROCONIDIA – small, unicellular
    - Round, elliptical, or pyriform (pear) shape
- BLASTOCONIDIA or BLASTOSPORES
  - Develop as daughter cell buds off the mother cell and is pinched off
  - Blastoconidia of yeasts (including Candida) may elongate to form pseudohyphae
- CHLAMYDOCONIDIA or CHLAMYDOSPORES
  - Thick-walled, resistant, resting spores produced by “rounding up” and enlargement of the terminal hyphal cells
  - Germinate into a new organism when favorable environmental conditions exist
    - Terminal – form at the hyphal tip
    - Sessile – form on the hyphal sides
    - Intercalary – form within the hyphal strand
- ARTHROCONIDIA or ARTHROSPORES
  - Simple fragmentation of the mycelium at the septum into rectangular-, cylinder-, or cask-shaped spores
  - Thick walled spores which may be adjacent or alternate (empty spaces or disjunctor cells in between each arthrospores) in arrangement
  - Useful identification characteristic of Coccidioides immitis and Geotrichum candidum

CLASSIFICATION

Botanical Taxonomy

Zygomycota –Mucor, Absidia, Rhizopus
Ascomycota
Basidomycota
Deuteromycota – most medically important fungi
- With septate hyphae
- Asexual reproduction

Type of Mycoses

Superficial and cutaneous mycoses
Subcutaneous mycoses
Systemic mycoses
Opportunistic mycoses

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IDENTIFICATION METHODS

MICROSCOPIC

SALINE MOUNT – quick and simple method to observe fungal elements (budding yeast, hyphae, pseudohyphae)
- Major disadvantage: Lack of contrast

10% KOH PREPARATION – rapid and simple method to examine hyphae, budding yeast and spherules
- KOH dissolves keratin in skin, hair, or nail
- Chitin is resistant to effects of KOH
- Hair can be examined to determine type of infection
  - ENDOTHRIX – fungal invasion within the hair shaft
  - ECTOTHRIX – infection outside the hair shaft
- Disadvantage: Lack of contrast

CELLUFLUOR – chemofluorescent brightening agent
- Can be added to the KOH solution
- Binds to the chitin in fungal cell wall
- Provides excellent contrast when examined with a fluorescent microscope
- Fungi fluoresce intense apple green

INDIA INK/NIGROSIN – used to identify hyaline capsule of the yeast Cryptococcus neoformans
- Capsules do not stain with India ink and appear as clear halos against a dark background
- May be difficult to interpret; WBCs and artifacts can be mistaken for yeast or capsules
- Cryptococcus may be capsule negative in immunodeficiency
- Replaced by direct antigen testing for the cryptococcal capsular protein

LACTOPHENOL COTTON BLUE (LPCB) (AMAN) – imparts blue color to the fungal cell wall
- Slides can be permanently sealed for later study with either Permount or clear nail polish
- Can also be used in the tease preparation (wet mount) and slide cultures

HUCKER MODIFICATION OF GRAM STAIN – recommended for mycology
- Fungi generally stain gram positive
- Oval or budding yeast, hyphae, arthrospores generally stain well
- C. neoformans may appear pale lavender with blue inclusions (capsule prevents adequate staining)
- Fungi are 2 to 3x the size of gram-positive cocci
- Hyphae are 2 to 3x wider than gram-positive bacilli

GIEMSA or WRIGHT’S STAIN – used for the detection of intracellular Histoplasma capsulatum in blood smears, lymph nodes, lung, liver, or bone marrow
- H. capsulatum appears as small, oval yeast cell staining light to dark blue
- C. neoformans also stain well

METHENAMINE SLIVER NITRATE STAIN – useful for screening of clinical specimens
- Provides good contrast and staining for fungal elements
- Fungi appear outlined in black, with an inner dark rose to black color against a pale green background
- Viable and nonviable fungi are stained using this method
- GOMORI METHENAMINE SILVER (GMS) NITRATE MODIFICATION – used in histology to detect fungi in specimens

PERIODIC ACID SCHIFF (PAS) – stains hyphae of molds and yeast
- Periodic acid oxidizes the hydroxyl in the carbohydrates of the cell walls to form aldehydes which react with basic fuchsin dye to form a pink-purple complex
- Counterstain of fast green can be used to provide contrast
- Useful in staining tissue in histology

CULTURE

Must include a source of nitrogen (nitrite, nitrate, amino acids, or urea) and a carbon source (usually glucose)
Incubated at 30°C or RT (25-30°C)
Chloramphenicol – inhibits bacteria
Cycloheximide – inhibits saprophytic, contaminating fungi

PRIMARY ISOLATION MEDIA

SABOURAUD DEXTROSE AGAR (SDA)
Main general isolation medium Primary recovery of saprobic and pathogenic fungi Primary agar for initial culture Contains peptone and glucose Inhibitor for bacteria: ACIDIC pH (5.6)

SDA WITH CYCLOHEXIMIDE AND CHLORAMPHENICOL (SDA-CC) Recovery of pathogenic fungi Bacteria and saprophytic fungi inhibited Available commercially as Mycosel or Mycobiotic medium

MYCOSEL OR MYCOBIOTIC AGAR
Isolation of dermatophytes from hair, skin, and nail specimens Contains the inhibitory agents, cycloheximide and chloramphenicol Similar to DTM

DERMATOPHYTE TEST MEDIUM (DTM)
Can be substituted for SDA-CC for the recovery of dermatophytes from specimens contaminated with fungi or bacteria Isolation of dermatophytes from hair, skin, and nail specimens Dermatophytes produce alkaline metabolites, which raise the pH and change the color of the indicator from yellow to red Indicator: PHENOL RED Antibiotics inhibit saprophytic fungi and bacteria

BRAIN-HEART INFUSION (BHI) AGAR
Isolation of saprophytic and pathogenic fungi from sterile sites Bacteria also grown in BHI Can be supplemented with blood

BHI AGAR WITH ANTIBIOTICS, CYCLOHEXIMIDE AND CHLORAMPHENICOL
Isolation of pathogenic fungi exclusive of dermatophytes; useful for specimens that may be contaminated with bacteria or saprophytic fungi

BHI BIPHASIC BLOOD CULTURE BOTTLES
Recovery of fungi from blood or bone marrow

DIFFERENTIAL MEDIA

BIRDSEED (NIGER SEED) AGAR/ STAIB’S MEDIUM
Isolation of Cryptococcus neoformans: brown to black colonies in 4 to 7 days C. neoformans produces phenol oxidase which breaks down the medium resulting in the production of melanin Similar to caffeic acid agar

CORNMEAL AGAR WITH TWEEN 80
Stimulation of conidiation and chlamydospore production in Candida species; useful for species differentiation of Candida Cornmeal agar + 1% glucose: differentiates T. rubrum from T. mentagrophytes based on PIGMENTATION

COTTONSEED AGAR
Conversion of mold phase of Blastomyces dermatitidis to its yeast phase

NITRATE REDUCTION MEDIUM
Confirmation of nitrate reduction in C. neoformans

POTATO DEXTROSE AGAR
Stimulation of conidia production in fungi Useful in slide culture Also demonstrates pigment production of Trichophyton rubrum

RICE MEDIUM Identification of Microsporum audouinii

TRICHOPHYTON AGARS
Nutritional requirement tests for the differentiation of
Trichophyton #1: casein agar base (vitamin free)
#2: casein agar base and inositol
#3: casein agar base, inositol, and thiamine
#4: casein agar base and thiamine
#5: casein agar base and nicotinic acid
#6: ammonium nitrate agar base
#7: ammonium nitrate agar base and histidine

UREA AGAR
Detection of urease production by C. neoformans and differentiation of Trichophyton mentagrophytes from T. rubrum

YEAST ASSIMILATION MEDIA (CARBON OR NITROGEN)
Detection of carbohydrate assimilation through utilization of carbon (or nitrogen) by yeast in the presence of oxygen

YEAST FERMENTATION BROTH
Identification of yeasts by fermentation reactions with various carbohydrates

ORGANISMS AND THEIR DESCRIPTION TO FOLLOW 🙂

Lecture Notes

Clinical Microscopy – REAGENT STRIPS

Posted on April 10, 2020December 6, 2022 by Doc Kriz

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TEST PRINCIPLE TIME	REAGENTS	FALSE (+)	FALSE (-)
Glucose (correlated with ketones) Double sequential enzyme reaction ENZYMES: Glucose oxidase Peroxidase 30 s	M – glucose oxidase, peroxidase, potassium iodide C – glucose oxidase, peroxidase, tetramethylbenzidine CHROMOGENS: O-toluidine (pink to purple) Potassium iodide (blue to brown) Aminopropryl-carbazol (yellow to orange-brown) Tetramethylbenzidine (yellow to green)	Contamination by oxidizing agents and detergents	High levels of ascorbic acid, ketones, specific gravity Low temperature Improperly preserved specimens
Ketones (correlated with glucose) Sodium nitroprusside reaction 40 s	M – sodium nitroprusside (acetoacetic acid) C – sodium nitroprusside + glycine (acetoacetic acid & acetone)	Phthalein dyes, highly pigmented red urine, levodopa Medications containing free sulfhydryl groups (MESNA)	Improperly preserved specimens
Specific Gravity pKa change of polyelectrolyte pKa = dissociation constant 45 s	M – poly (methy lvinyl ether/maleic anhydride) bromthymol blue C – ethyleneglycol-Bis (aminoethylether) bromthymol blue	High concentrations of proteins because of protein anions	Highly alkaline urines (>6.5) Add 0.005 to S.G. readings
pH (correlated with Nitrite, LE, microscopic) Double-indicator system 60 s	Methyl red Bromthymol blue	None	Runover from the adjacent CHON pad may lower pH
Protein (correlated with blood, nitrite, LE, microscopic) Protein error of indicators 60 s	M – tetrabromphenol blue C – tetrachloropenol tetrabromosulfonphthalein ACID BUFFER: Citrate	Highly buffered alkaline urine High specific gravity pigmented specimens, phenazopyridine quaternary ammonium compounds (detergents) antiseptics, chlorhexidine loss of buffer from prolonged exposure of reagent strip to the specimen	Proteins other than albumin
Blood (correlated with protein and microscopic) Pseudo-peroxidase activity of hemoglobin 60 s	M – diisopropylbenzenedehydroperoxide tetramethylbenzidine C – dimethyldihyroperoxide- tetramethylbenzidine spotted blue for intact RBCs uniform blue for Hb and myoglobin	Strong oxidizing agents, bacterial peroxidases menstrual contamination	High specific gravity/ crenated cells high concentration of nitrite formalin, captopril, ascorbic acid > 25mg/dl unmixed specimens
Bilirubin (correlated with urobilinogen) Diazo reaction 60 s	M – 2,4-dichloro-analine diazonium salt C -2,6-dichorobenzene-diazonium-tetrafluoroborate	Highly pigmented urines, phenazopyridine, indican metabolites of Lodine	Specimen exposure to light, ascorbic acid >25 mg/dL, high concentration of nitrite
Urobilinogen (correlated with bilirubin) Ehrlich’s reaction 60 s	M – para-dimethylaminobenzaldehyde C – 4-methoxybenzenediazonium-tetrafluroborate	M – Porphobilinogen, indican, p-aminosalicyclic acid, sulfonamides, methyldopa, procaine, chlorpromazine, highly pigmented urine C – highly pigmented urine	M – old specimens, preservation in formalin C – old specimens, preservation in formalin, high concentration of nitrite
Nitrite (correlated with protein, LE and microscopic) Greiss reaction 60 s	M – p-arsanilic acid Tetrahydrobenzo(h)-quinolin-3-ol C – Sulfanilamide, hydroxytetrahydro benzoquinoline	Improperly preserved specimens Highly pigmented urine	Nonreductase-containing bacteria insufficient contact between bacteria and urinary nitrate (should be 4 hours) lack of urinary nitrate, large quantities of bacteria converting nitrite to nitrogen, presence of antibiotics, high concentration of ascorbic acid high specific gravity
Leukocytes (correlated with protein, nitrite and microscopic) Leukocyte esterase 120 s	M – derivatized pyerole amino acid ester, diazonium salt C – indoxylcarbonic acid ester diazonium salt	Strong oxidizing agents, Formalin, highly pigmented urine, nitrofurantoin	High concentration of protein, glucose, oxalic acid, ascorbic acid, gentamicin, cephalosporins, tetracyclines

Lecture Notes

Clinical Microscopy – Automation

Posted on April 5, 2020May 6, 2020 by Doc Kriz

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WHAT’S IN HERE?

Principles Used in Automated Urinalysis and Microscopy
Automated Urinalysis Systems
Automated Body Fluid Analysis Systems

Principles Used in Automated Urinalysis and Microscopy

REFLECTANCE PHOTOMETRY
- Used by automated reagent strip readers
- Measure the light reflected from the reagent strip color pads and compare the amount of reflected light with a known standard
- PRINCIPLE: light reflected from the colored reagent pads DECREASES in DIRECT PROPORTION to the INTENSITY OF THE COLOR produced by the reaction with the specific substance in the urine sample
  - the darker the color, the less light reflected
  - the lighter the color, the more light reflected
- The concentration of a specific substance and concentration units are displayed on the reader’s display

LASER-BASED FLOW CYTOMETRY, IMPEDANCE & LIGHT SCATTER
- Identify sediment elements in a urine sample
- measures sediment conductivity and light scatter
  - Conductivity is based upon the impedance (the amount of resistance that occurs when a sediment passes through an electrical ﬁeld) of sediments and counts the numbers of pulses (sediments).
    - The size of the pulse indicates the size of the sediment.
  - Light scattering characteristics of the sediments are determined by their movement through the laser light beam.
    - Identiﬁcation depends on how the light is scattered by the sediment.

HARMONIC OSCILLATION
- Assesses SPECIFIC GRAVITY
- Method based upon densitometry in which a sound wave of a specific frequency changes in proportion to the density of the urine sample
- Change in wave frequency is measured by a microprocessor and translates the reading to speciﬁc gravity

HYDRODYNAMIC FOCUSING
- Identifies specific sediments
- involves the movement of single urine sediments past the optics of a microscope to allow sediments to ﬂow in several planes plane past the microscope objective
- A ﬂow cell also measures sediment conductivity, size, and light scattering traits
- Questionable ﬁndings are viewed on a monitor for operator identiﬁcation and conﬁrmation

Automated Urinalysis Systems

INDIVIDUAL STRIP READERS
SEMIAUTOMATED ANALYZERS
- dependent on an operator for specimen mixing, test strip, dipping, and inputting of physical and microscopic results
FULLY AUTOMATED CHEMISTRY ANALYZERS
- add urine to the reagent strip
AUTOMATED URINE CELL ANALYZERS
- mix, aspirate, dilute, and stain urine to classify urine sediment particles
COMPLETELY AUTOMATED SYSTEMS
- perform a complete urinalysis that includes the physical, chemical, and microscopic parts of a routine urinalysis

WAIVED URINE CHEMISTRY INSTRUMENTS

Roche Diagnostics Criterion II Siemens Medical Solutions Diagnostics Clinitek®50 Siemens Medical Solutions Diagnostics Clinitek®101 Siemens Medical Solutions Diagnostics Clinitek®Status

SEMIAUTOMATED URINE CHEMISTRY INSTRUMENTS

Dirui Urine Analyzer H-50, 100, 200 Iris Diagnostics Division iChem®100 Roche Diagnostics URISYS®1800 Roche Diagnostics Chemstrip Criterion II Siemens Medical Solutions Diagnostics Clinitek®200, 200+, 500

FULLY AUTOMATED URINE CHEMISTRY INSTRUMENTS

Iris Diagnostics Division AUTION MAX® Iris Diagnostics Division iChem® VelocityTM Roche Diagnostics URISYS 2400® Siemens Medical Solutions Diagnostics Clinitek® Atlas

AUTOMATED SEDIMENT ANALYSIS

Iris Diagnostics Division iQ®200ELITE^TM Iris Diagnostics Division iQ®200SELECT^TM Iris Diagnostics Division iQ®200SPRINT^TM Sysmex UF-100® Urine Cell Analyzer

TOTALLY AUTOMATED URINALYSIS SYSTEMS

Iris Diagnostics Division iQ®200 Automated Urinalysis System iRICELL2000 (iChem® Velocity^TM plus iQ®200ELITE^TM) iRICELL3000 (iChem® Velocity^TM plus iQ®200SPRINT^TM) Siemens Medical Solutions Diagnostics ADVIA Urinalysis WorkCell System (Clinitek® Atlas plus the Sysmex UF-100)

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DESCRIPTION OF SOME SELECTED INSTRUMENTS

CLINITEK 50 & CLINITEK STATUS
- well suited for small volume laboratories and physician’s offices
- Memory storage for test results -100 for Clinitek 50 and 200 for Clinitek Status
- automated reading of microalbumin-to-creatinine and protein-to-creatinine ratios and human chorionic gonadotropin (hCG)

CLINITEK 200
- For medium-volume to large-volume urinalysis laboratories and features a high specimen output of one strip every 10 seconds.
- Multistix reagent test strips are used, and the instrument has the ability to report semiquantitative (mg/dL) results or plus (+) and SI units.
- The reﬂectometer is calibrated daily and maintenance is required each day for all areas in contact with urine test strips

SYSMEX UF-SERIES
- Fully automated sample analysis with automatic classification of all 10 formed element groups with SCATTERGRAMS and HISTOGRAMS for reference
- Laser-based FLOW CYTOMETRY along with impedance detection, forward light scatter, and fluorescence
- Sample is stained with 2 dyes
  - PHENATHRIDINE – orange dye, stains DNA
  - CARBOCYANINE – green dye, stains nuclear membranes, mitochondria, and negatively charged cell membranes

SYSMEX UF-SERIES
- Stained sample is passed through the flow cell, where it is HYDRODYNAMICALLY FOCUSED and presented to a laser light beam that produces fluorescence and light scatter
- Particles are identified by measuring the change in impedance of the sediment elements, as well as the height and width of the fluorescent and light scatter signals, which are presented in scattergrams and histograms

iQ 200 Automated Urine Microscopy Analyzer (IRIS)
- Automatically analyses and classifies urine particles into 12 categories
- Uses AUTO PARTICLE RECOGNITION (APR) software that classifies urine particles in the photographs based on size, shape, texture, and contrast

Automated Body Fluid Analysis Systems

cells are first mixed with reagent ﬁxative and then counted
differentials counting enumerates numbers of neutrophils, lymphocytes, monocytes, and eosinophils
automated cell counters use larger numbers of cells, enhancing precision and accuracy

BODY FLUID ANALYZERS	FDA APPROVED FOR USE WITH THESE FLUIDS:
Iris iQ Body Fluid Module	CSF, Pleural & Peritoneal Peritoneal lavage, peritoneal dialysate, pericardial, general serous fluids, synovial
Siemens Medical Solutions Diagnostics ADVIA120 and 2120	CSF
Sysmex XE-5000 Automated Hematology System	CSF Serous body fluids Synovial fluid
Medical Electronic Systems	Semen

ADVIA120 Hematology System

First automated instrument with an FDA-approved automated CSF assay
- Uses flow cytometry, light scatter, and absorbance to count the RBCs, WBCs, and performs a WBC differential that includes percentages and absolute numbers of mononuclear cells and PMNs on samples with >20WBCs/µL

AUTOMATION OF SEMEN ANALYSIS

SQA-V automates sperm counts and motility
- has a two-channel measurement system that interacts with a specially designed testing capillary that contains the semen sample
- one channel “measures” light absorption and refraction in sperm cells and translates this into concentration
- one channel “counts” light interruptions (signals) caused by sperm cells moving across the ﬁeld of light
- In approximately 1 minute, thousands of signals are “read” resulting in exceptional accuracy and precision.
- Automating the motility analysis eliminates reader subjectivity and variance among technologists.

AUTOMATION OF URINE PREGNANCY

Quantitative human chorionic gonadotropin (HCG) is one such test that is interpreted by the VEDALAB Easy Reader.
- Immunochromatographic rapid test cards are read by the meter using a high-resolution CCD camera.
- Integrated software analyzes the images and records the results.

Lecture Notes

Clinical Chemistry – Carbohydrates

Posted on April 3, 2020December 28, 2020 by Doc Kriz

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WHAT’S IN HERE?

Carbohydrates
Glucose and Its Metabolism
Hyperglycemia
Hypoglycemia
Genetic Defects in Carbohydrate Metabolism
Laboratory Analysis of Glucose
References

DEFINITION

Compounds containing C, H and O with general formula C_x(H₂O)_y
Contain C=O and –OH functional groups
Derivatives can be formed by addition of other chemical groups such as phosphates, sulfates and amines
Commonly called “SUGARS” and use the suffix –ose

CLASSIFICATION

Based on four different properties
SIZE OF THE BASE CARBON CHAIN
- TRIOSES: with three (3) carbons
- TETROSES: with four (4) carbons
- PENTOSES: with five (5) carbons
- HEXOSES: with six (6) carbons
LOCATION OF THE CO FUNCTION GROUP
- ALDOSE: has a terminal carbonyl group (O=CH^–) called an aldehyde group
- KETOSE: has carbonyl group (O=CH^–) in the middle linked to two other carbon atoms called a ketone group
STEREOCHEMISTRY OF THE COMPOUND
- STEREOISOMERS: have the same order and types of bonds but different spatial arrangements and different properties
- ENANTIOMERS: images that cannot be overlapped and are non-superimposable
  - L-isomer: if the configuration of the highest-numbered asymmetric carbon is on the LEFT or if hydroxyl group farthest from the carbonyl carbon is on the LEFT
  - D-isomer: if the configuration of the highest-numbered asymmetric carbon is on the RIGHT or if hydroxyl group farthest from the carbonyl carbon is on the RIGHT
NUMBER OF SUGAR UNITS
- MONOSACCHARIDES
  - Simple sugars that cannot be hydrolyzed to simpler form
  - Examples: glucose, fructose, galactose
- DISACCHARIDES
  - Formed by two monosaccharides joined by glycosidic linkage
  - Hydrolyzed by disaccharide enzymes (i.e., lactase) produced by the microvilli of the intestine
  - Examples:
    - Maltose = 2 β-D-glucose in 1→4 linkage
    - Lactose = glucose + galactose
    - Sucrose = glucose + fructose
  - OLIGOSACCHARIDES
    - Chaining of 2 to 10 sugar units
  - POLYSACCHARIDES
    - Linkage of many monosaccharide units
    - Yield more than 10 monosaccharides upon hydrolysis
    - Examples: starch, glycogen

MODELS USED TO REPRESENT CARBOHYDRATES

FISCHER: linear formula where the aldehyde or ketone is at the top of the drawing and can be depicted in the D- or L- form
HAWORTH: cyclic form that is more representative of the actual structure and is formed when the carbonyl group reacts with an alcohol group on the same sugar to form a ring and can be depicted in the α or β form

CHEMICAL PROPERTIES

REDUCING SUBSTANCES
- Contain a ketone or aldehyde group
- WITH FREE ANOMERIC CARBON
- Can reduce other compounds
- Examples: glucose, maltose, fructose, lactose, galactose
NON-REDUCING SUBSTANCES
- Do not have an active ketone or aldehyde group
- NO FREE ANOMERIC CARBON
- Will not reduce other compounds
- Example: sucrose (table sugar)

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Glucose and Its Metabolism

End product of carbohydrate digestion in the intestine
- Enzymes involved
  - AMYLASE (salivary & pancreatic) – digests nonabsorbable polymers to dextrins and disaccharides
  - MALTASE (from the intestine) – digests disaccharides to monosaccharides
  - SUCRASE & LACTASE – hydrolyze sucrose & lactose respectively
- FUNCTIONS:
  - Provides energy for life processes
  - The only CHO that can be directly used for energy or stored as glycogen
- FORMS: ~35% alpha & 65% beta
- MAJOR METABOLIC PATHWAYS
  - EMBDEN-MEYERHOFF PATHWAY or GLYCOLYSIS
    - Substrate: D-glucose
    - End-products: 2 moles of PYRUVIC ACID, 2 moles NADH and 2 moles of ATP
    - Can occur aerobically or anaerobically
      - If aerobic, pyruvate is formed
      - If anaerobic, lactate is formed
    - Other substrates can enter this pathway at various points
      - Glycerol (from TAG) enters at 3-phosphoglycerate
      - Fatty acids, ketones and some amino acids are converted to acetyl-CoA
      - Other amino acids enter as pyruvates or as deaminated α-ketoacids and α-oxoacids
    - HEXOSE MONOPHOSPHATE SHUNT OR AEROBIC/OXIDATIVE PATHWAY
      - G6P is converted to 6-phosphogluconic acid which permits the formation of NADPH (important to red cells because they lack mitochondria thus incapable of TCA cycle)
      - End-products: pentose phosphate, CO₂ and NADPH
    - GLYCOGENESIS
      - Stores glucose as glycogen
      - Converts G6P to G1P
      - G1P → uridine diphosphoglucose→ glycogen by glycogen synthase
      - GLYCOGENOLYSIS – conversion of glycogen to G6P

PATHWAYS IN GLUCOSE METABOLISM
Glycolysis	Metabolism of glucose molecule to pyruvate or lactate for production of energy
Gluconeogenesis	Formation of G6P from noncarbohydrate sources
Glycogenolysis	Breakdown of glycogen to glucose for use as energy
Glycogenesis	Conversion of glucose to glycogen for storage
Lipolysis	Decomposition of fats
Lipogenesis	Conversion of carbohydrates to fatty acids

MAJOR HORMONES CONTROLLING BLOOD GLUCOSE
- PANCREATIC HORMONES
  - INSULIN – primary hormone for DECREASING blood glucose levels
    - Responsible for the entry of glucose into the cells by enhancing membrane permeability to cells in the liver, muscle and adipose tissues
    - synthesized by β-cells of the pancreas
      - released when glucose levels are high/increased
      - not released when glucose levels are low/decreased
    - EFFECTS:
      - increases glycogenesis, lipogenesis, and glycolysis
      - inhibits glycogenolysis
    - INSULIN IS THE ONLY HORMONE THAT DECREASES GLUCOSE LEVELS and can be referred to as a hypoglycemic agent
  - GLUCAGON – primary hormone for INCREASING blood glucose levels
    - released in response to stress and fasting states
    - synthesized by α-cells of the pancreas
      - released when glucose levels are low/decreased
      - not released when glucose levels are high/increased
    - EFFECTS:
      - increase glycogenolysis and gluconeogenesis
    - can be referred to as a hyperglycemic agent
  - SOMATOSTATIN
    - produced by δ cells of the pancreas
    - EFFECTS: inhibition of insulin, glucagon, growth hormone, and other endocrine hormones.
  - ADRENAL HORMONES
    - CORTISOL
      - produced by the adrenal cortex on stimulation by ACTH
      - EFFECTS: decreases intestinal entry into the cell and increases gluconeogenesis, liver glycogen and lipolysis
    - EPINEPHRINE
      - produced by the adrenal medulla
      - EFFECTS: inhibits insulin secretion, increase glycogenolysis and lipolysis
      - Released during times of stress
    - ANTERIOR PITUITARY HORMONES
      - GROWTH HORMONE
        EFFECTS: decreases the entry of glucose into the cells
      - ACTH
        EFFECTS: stimulates the adrenal cortex to release cortisol, increases glycogenolysis and gluconeogenesis
      - THYROID HORMONES
        T3 & T4
        EFFECTS: increases glycogenolysis, gluconeogenesis and intestinal absorption of glucose

HORMONAL ACTIVITY AFFECTING SERUM GLUCOSE LEVELS
HORMONE	SOURCE	EFFECT	ACTION
Insulin	β cells of pancreas	↓	stimulates glucose uptake by cells
Glucagon	α cells of pancreas	↑	glycogenolysis
ACTH	Anterior pituitary	↑	insulin antagonist, glycogenolysis & gluconeogenesis
Growth Hormone	Anterior pituitary	↑	insulin antagonist & glycolysis
Cortisol	Adrenal cortex	↑	insulin antagonist, gluconeogenesis & lipolysis
HPL	Placenta	↑	insulin antagonist
Epinephrine	Adrenal medulla	↑	inhibits insulin secretion, glycogenolysis & lipolysis
T₃ & T₄	Thyroid gland	↑	glycogenolysis, gluconeogenesis & intestinal absorption of glucose
Somatostatin	δ cells of pancreas	↑	inhibits insulin, glucagon, GH

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Hyperglycemia

Increase in plasma glucose levels caused by imbalance of hormones
DIABETES MELLITUS
- Group of metabolic diseases characterized by hyperglycemia resulting from defects in insulin secretion, insulin action or both
- Categories of Diabetes (According to the ADA/WHO guidelines)
  - Type 1 Diabetes
  - Type 2 Diabetes
  - Other specific types of diabetes
  - Gestational Diabetes Mellitus (GDM)
PRIMARY DIABETES MELLITUS

Points of Difference	TYPE 1	TYPE 2
Former names	Insulin Dependent Diabetes Mellitus (IDDM) Juvenile Onset DM Brittle DM Ketosis-prone DM	Non-Insulin Dependent Diabetes (NIDDM) Maturity Onset DM Stable DM Ketosis-resistant DM Receptor Deficient DM
Onset	Before 20 y/o	Over 40 y/o
Measurable circulating insulin	NONE	Low
Insulin receptor	Normal	↓ or ineffective
Beta cell mass	Markedly ↓	Moderately ↓
C-peptide levels	Undetectable	Detectable
Incidence	10-15%	85% (common)
Ketoacidosis*	Common	Rare
Physique/Stature**	Normal or thin	Often overweight
Pathogenesis	-β-cell destruction -Absolute insulin deficiency -Autoantibodies	-Insulin resistance with insulin secretory defect -Relative insulin deficiency
Treatment	Parenteral insulin administraion	Oral hypoglycemic agent

SECONDARY DIABETES MELLITUS – associated with secondary conditions
- Genetic defects of β-cell function
- Pancreatic disease
- Endocrine disease
  - Cushing syndrome – excessive cortisol
  - Pheochromocytoma – epinephrine excess
  - Acromegaly – growth hormone excess
- Drug or chemical induced
- Insulin receptor abnormalities
- Other genetic syndromes
  - Maturity onset diabetes of youth (MODY) – rare; autosomal dominant
GESTATIONAL DIABETES MELLITUS (GDM)
- any degree of glucose intolerance with onset or first recognition during pregnancy
- due to metabolic or hormonal changes
- Infants born to mothers with this kind of diabetes are at increased risk to respiratory distress syndrome, hypocalcemia & hyperbilirubinemia

Laboratory Findings in Hyperglycemia

INCREASED glucose (plasma & urine), urine specific gravity, serum and urine osmolality
Ketonemia and ketonuria
DECREASED blood and urine pH (acidosis)
Electrolyte imbalance (↓Na⁺, Cl^– and ↑K⁺)

DIAGNOSTIC CRITERIA FOR DIABETES MELLITUS

RPG ≥200 mg/dl (11.1 mmol/L) + symptoms of diabetes

Fasting PG ≥126 mg/dL (7.0 mmol/L)

2-h PG ≥200 mg/dl (11.1 mmol/L) during OGTT

CATEGORIES OF FASTING PLASMA GLUCOSE

Normal fasting glucose FPG <110 mg/dL

IMPAIRED fasting glucose FPG ≥110 mg/dl but <126 mg/dl

Provisional diabetes dx FPG ≥126 mg/dl

CATEGORIES OF ORAL GLUCOSE TOLERANCE

Normal glucose tolerance 2h PG <140 mg/dL

Impaired gluc. tolerance 2h PG ≥140 mg/dl but <200 mg/dl

Provisional diabetes dx 2h PG ≥200 mg/dl

Screening test for GDM
- Only high-risk patients should be screened for GDM
  - Age older than 25 years
  - Overweight
  - Strong family history of diabetes
  - History of abnormal glucose metabolism
  - History of a poor obstetric outcome
  - Presence of glycosuria
  - Diagnosis of PCOS
  - Member of an ethnic/racial group with a high prevalence of diabetes (e.g. Hispanic American, Native American, Asian American, African American, Pacific Islander)
- METHODS:
  - ONE-STEP APPROACH – immediate performance of a 3h OGTT without prior screening
  - TWO-STEP APPROACH – initial measurement of plasma glucose at 1-hour postload (50g)
    - IF value ≥140 mg/dL (7.8 mmol/L) then do 3-hour OGTT using 100g glucose
    - GDM is diagnosed when any two of the following values are met or exceeded:
      - Fasting: >95 mg/dl
      - 1 hour: ≥180 mg/dl
      - 2 hours: ≥155 mg/dl
      - 3 hours: ≥140 mg/dl

Hypoglycemia

Decrease in plasma glucose levels
- 65-70 mg/dl (3.6-3.9 mmol/L) – plasma glucose concentration at which glucagon and other glycemic factors are released
- 50-55 mg/dl (2.8-3.0 mmol/L) – symptoms of hypoglycemia appear
- Warning S/S are all related to CNS
Types of Hypoglycemia (Old)
- Post-absorptive (Fasting) – MORE SERIOUS
  - Islet cell insulinoma
  - Insulin-producing tumors
  - Ethanol induced
  - Propanolol & salicylate
Post-prandial (Reactive) – MILD FORM
- there is spontaneous recovery of glucose level as a result of insulin level returning to normal
- Excessive release of insulin
- Gastro-intestinal surgery

CAUSES OF HYPOGLYCEMIA
Patient Appears Healthy
No coexisting disease	Drugs Insulinoma Islet hyperplasia or NESIDIOBLASTOSIS Factitial hypoglycemia from insulin or sulfonylurea Severe exercise Ketotic hypoglycemia
Compensated coexistent disease	Drugs
Patient Appears ILL
Drugs Predisposing illness Hospitalized patient

Diagnostic criteria for INSULINOMA
- Change in glucose level of ≥25 mg/dl coincident with an insulin level of ≥6 μU/ml
- C-peptide levels of ≥0.2 nmol/L
- Proinsulin levels of ≥5 pmol/L
- β-hydroxybutyric acid of ≤2.7 mmol/L
Diagnostic tests for HYPOGLYCEMIA
- 72 hour fast which requires the analysis of glucose, insulin, C-peptide and proinsulin at 6-hour intervals
- POSITIVE RESULT: <45 mg/dl; hypoglycemic symptoms appear after 72 hours had elapsed

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Genetic Defects in Carbohydrate Metabolism

Glycogen Storage Diseases – deficiency of a specific enzyme that causes alteration of glycogen metabolism

Types	Enzyme Deficient	Clinical Features
von Gierke’s dse Type I	Glucose-6-phosphatase	Severe fasting hypoglycemia Lactic acidosis
Pompe’s dse Type II	α-1,4-glucosidase	Accumulation of ↑ amount of glycogen on all organs Presence of abnormally LARGE LYSOSOMES
Forbe’s dse Type III	Debrancher enzyme	Hypoglycemia, hepatomegaly, seizures and mental retardation
Andersen’s dse Type IV	Brancher enzyme	Progressive liver enlargement or cirrhosis and muscular weakness by age 2 Absence of storage glycogen Unbranched AMYLOPECTIN

Other enzyme defects/deficiencies that cause hypoglycemia: glycogen synthase, fructose-1-6,biphosphatase, phosphoenolpyruvate carboxykinase and pyruvate carboxylase.

Galactosemia – a cause of failure to thrive syndrome in infants; congenital deficiency of one of three enzymes involved in galactose metabolism, resulting in increased plasma galactose levels
- Galactose-1-phosphate uridyl transferase – MOST COMMON enzyme deficiency
- Fructose-1-phosphate aldolase deficiency

Laboratory Analysis of Glucose

SPECIMEN COLLECTION AND HANDLING
- Glucose concentration in whole blood is approximately 15% lower than in plasma or serum.
- Glucose levels decrease approximately 10 mg/dL (7%) per hour in whole blood.
- Serum or plasma must be separated within 1 hour (Bishop) to prevent substantial loss of glucose by the cellular fraction, particularly if WBC count is elevated. (within 30 minutes – Henry)
- Glucose is metabolized at a rate of 7 mg/dl/h at room temperature; and 2 mg/dl/h at 4°C
- Refrigerated serum or plasma is stable up to 48 hours.
- Sodium fluoride (2 mg/mL) prevents glycolysis (gray top tube) for up to 48 hours.
- Glycolysis decrease serum glucose by approximately 5-7% per hour (5-10 mg/dl) in normal, uncentrifuged coagulated blood at room temperature.
- Fasting blood glucose should be obtained after an approximately 10-hour fast (not >16 hours)
- Fasting plasma glucose values have a diurnal variation with the mean FBG higher in the morning than in the afternoon.
- Fasting reference range for serum or plasma is 70-110 mg/dL
- In the fasting state, arterial (capillary) values are 5 mg/dL higher than the venous concentration.
- Urine glucose analysis (in 24h urine glucose) may be stabilized by addition of a preservative; should be stored at 4°C during collection because 40% of glucose is lost after 24 hours at room temperature.
- CSF glucose analysis (if will be delayed) must be centrifuged and stored at 4°C-20°C
- In normal CSF, values are two-thirds (approximately 60-70%) of plasma level.
- RENAL THRESHOLD for glucose: 180 mg/dl
TYPES OF SPECIMEN FOR GLUCOSE ANALYSIS
- Fasting Blood Sugar – blood collected after 8-10 hours of fasting (NV: 74-106 mg/dl)
- Random Blood Sugar – test for INSULIN SHOCK (NV: <200 mg/dl)
- 2 hour Postprandial Blood Sugar
  - Standard load of glucose: 75 grams
  - Glucose measurement taken 2 hours later
  - (NV : <120 mg/dl)
- Glucose Tolerance Test – multiple blood and urine glucose test
  - Oral GTT
    - Janney-Isaacson (Single Dose)
    - Exton Rose (Divided Oral dose or Double Dose)
    - Not recommended for routine use
    - Fasting and 2h sample are measured except for pregnant patients
    - Adult load is 75g; children: 1.75 g/kg to 75g
    - Factors that affect tolerance
      - Medications (salicylates, diuretics, anticonvulsants, oral contraceptives and corticosteroids)
      - GI surgery
      - Vomiting
      - Endocrine dysfunction
    - Requirements:
      - Patient should be ambulatory
      - Patient must be in unrestricted diet of 150 grams CHO/day for 3 consecutive days prior to the test
      - Patient must be free from undue stress or severe illness
      - Alcohol intake and smoking are not allowed prior to the test
      - Patient should be fasting at least 10 hours and not more than 16 hours
      - Test should be performed in the morning because of hormonal diurnal effect on glucose
    - IVGTT – blood sample is collected every 10 minutes for 1 hour
      - 5g glucose/kg body weight (given within 3 minutes) administered intravenously
      - fasting is also required
      - NV: 1.4 – 2.0 %
      - Indications of IVGTT
        
        Patients who are unable to tolerate large CHO load
        
        Patients with altered gastric physiology or GI d/o
        
        Patients with malabsorption syndrome
Self-Monitoring of Blood Glucose (SMBG)
- Type 1 DM – should monitor blood glucose 3-4 times per day
- Type 2 DM – optimal frequency is unknown
Glycosylated hemoglobin/Glycated hemoglobin/HbA1C
- hemoglobin compound formed when glucose reacts with amino group of hemoglobin
- test for long term diabetic control
- reflects the average blood glucose level for the previous 2-3 months
- for every 1% change in HbA1c value there is 35 mg/dl (2 mmol/L) change in the mean
- in presence of hemoglobinopathies, there will be less time for glucose to
- binding of glucose to HbA1 is irreversible
- preferred anticoagulant is EDTA
- NV: 4.5-8.5%

Methods of HBA_1c Measurement
Methods based on STRUCTURAL DIFFERENCES
Immunoassays	Polyclonal or monoclonal antibodies toward the glycated n-terminal group of the β chain of Hgb
Affinity chromatography	Separates based on chemical structure using borate to bind glycosylated proteins	Not affected by temperature and other hemoglobins
Methods based on CHARGE DIFFERENCES
Ion-exhange chromatography	Positive-charge resin bed	Highly affected by temperature and hemoglobinopathies HbF – ↑ HbS and C – ↓
Electrophoresis	Separation is based on differences in charge	HbF values >7% interferes
Isoelectric focusing	Type of electrophoresis using isoelectric point to separate	Pre-hb A_1c interferes
HPLC	Form of ion-exchange chromatography	Separates all forms of glycol Hb (a,b,c)

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METHODS FOR ANALYSIS
- CHEMICAL
  - REDUCTION
    - Cupric Ion Reduction
      - FOLIN-WU – measure of ALL REDUCING SUBSTANCES in the blood
        
        Reagent that binds with Cu⁺: phosphomolybdic acid
        
        End product: phosphomolybdenum blue
        
        End color: blue
      - NELSON SOMOGYI – MEASURE OF TRUE GLUCOSE
        
        Reagent that binds with Cu⁺: arsenomolybdic acid
        
        End product: arsenomolybdenum blue
        
        End color: blue
      - NEOCUPROINE
        
        Reagent that binds with Cu⁺: neocuproine
        
        End product: cuprous-neocuproine complex
        
        End color: yellow/yellow orange
      - Ferric Ion Reduction – Inverse Colorimetry – reduction of yellow ferricyanide to a colorless ferrocyanide by glucose
        
        HAGEDORN JENSEN
- CONDENSATION
  - Orthotoluidine (DUBOWSKI method)
    - can be also used for urine and CSF without protein precipitation
    - Absorbance: 630 nm
    - Reagent: aromatic amine, glacial acetic acid
    - End color: green
    - Interfering substances: galactose and mannose
- Polarographic Glucose Oxidase
  - measures oxygen consumption with PO2 electrode (Clark)
  - used to avoid interference made by strong oxidizing agents in GOD
  - Molybdate – catalyzes the oxidation of iodide to iodine by H₂O₂
  - Catalase – catalyzes oxidation of ethanol by H2O2 forming acetaldehyde and H₂O
- Hexokinase
  - Generally accepted as the REFERENCE METHOD
  - MORE ACCURATE THAN HEXOKINASE
    - coupling reaction using G6PD is highly specific
  - Measured by quantitating reduced NADPH formation
  - NADPH is measured directly at 340 nm or coupled to chromogen and measured in visible range
  - Interfering substances: gross hemolysis & extremely elevated bilirubin (cause ↓ values)
  - May be performed using serum or plasma (heparin, EDTA, fluoride, oxalate & citrate)
  - Excellent for glucose determination in urine, CSF and serous fluids

OTHER IMPORTANT TESTS

KETONES
- Produced by the liver through metabolism of fatty acids to provide ready energy source from stored lipids at times of low carbohydrate availability
- THREE KETONE BODIES
  - Acetone (2%)
  - Acetoacetic acid (20%)
  - Β-hydroxybutyric acid (78%)
- Causes of increased ketone levels
  - Diabetes Mellitus
  - Starvation/fasting
  - High-fat diets
  - Prolonged vomiting
  - Glycogen storage diseases
- KETONEMIA – accumulation of ketones in the blood
  - KETONURIA – accumulation of ketones in the urine
  - MEASUREMENT OF KETONES
    - For patients with Type 1 Diabetes, it is recommended during acute illness, stress, pregnancy, or elevated blood glucose levels above 300 mg/dL or when patients have signs of ketoacidosis
    - SPECIMEN: FRESH SERUM or URINE tightly stoppered and analyzed immediately
    - METHODS FOR ANALYSIS:
      - GERHARDT’S TEST – historical test
        
        Used FERRIC CHLORIDE reacted with ACETOACETIC ACID to produce a RED color
- SODIUM NITROPRUSSIDE – more common method
  - Uses SODIUM NITROPRUSSIDE which reacts with ACETOACETIC ACID in an ALKALINE pH to form a PURPLE COLOR
  - If GLYCERIN is also added, ACETONE will be detected
  - Used in urine reagent strips and Acetest tablets
- ENZYMATIC – newer method adapted in some automated intstruments
  - Uses β-HYDROXYBUTYRATE DEHYDROGENASE to detect either β-HYDROXYBUTYRIC ACID or ACETOACETIC ACID depending on the pH of the solution
    - pH of 7.0 causes the reaction to proceed to the right (decreasing absorbance)
    - pH of 8.5 to 9.5 causes the reaction to proceed to the left (increasing absorbance)

MICROALBUMINURIA

Defined as persistent albuminuria in the range of 30 to 299 mg/24 h or an albumin-creatinine ratio of 30 to 300 g/mg
Clinical proteinuria or macroalbuminura is established with an albumin-creatinine ratio of ≥300 mg/24h or ≥300 µg/mg
Powerful predictor for future development of diabetic nephropathy
Annual assessment of kidney function by the determination of urinary albumin is recommended for diabetic patients
METHODS FOR MICROALBUMINURIA SCREENING
- RANDOM SPOT TEST – preferred method
- 24-HOUR COLLECTION
- TIMED 4-HOUR OVERNIGHT COLLECTION
A patient is determined to have microalbuminuria when two of three specimens collected within a 3- to 6-month period are abnormal.
Factors that may elevate the urinary excretion of albumin include exercise within 24 hours, infection, fever, congestive heart failure, marked hyperglycemia, and marked hypertension

ISLET AUTOANTIBODY AND INSULIN TESTING

Not currently recommended for routine screening for diabetes diagnosis but in the future it might identify at-risk, prediabetic patients

TESTS FOR CARBOHYDRATE DISORDERS
DIAGNOSTIC TESTS	ACTION
Fasting Blood Sugar	Normal – 70-110 mg/dl Diabetes – >126 mg/dl
2hr Post Prandial Blood Sugar (PPBS)	Normal – <126 mg/dl Diabetes – >200 mg/dl
Post-Loading Glucose	Similar to PPBS Glucose load is standardized Diabetics ≥200 mg/dl
Glucose Tolerance Test (GTT) Standard dose = 75g	Diagnostics of diabetes mellitus >150 mg/dl after 2 hours* >200 mg/dl after 2 hours *Perform if FBS and PPBS are normal
Intravenouse Glucose Tolerance Test (IVGTT)	Poor absorption (flat curve with OGTT) Patient who cannot tolerate large glucose load (vomiting)
O’Sullivan Test (for gestational diabetes)	Standard dose 50g Probable gestational diabetes >150 mg/dl at 1 hour *Follow up with OGTT
TESTS FOR MONITORING	NOTES
Glycosylated hemoglobin	Assessment of long term control Average glucose level over 60 days (1-2 months)
Microalbumin	*Detects small amounts of protein in urine of diabetic patients to assess renal damage
C peptide of Insulin (reflects pancreatic insulin secretion)	Normal 1:1 (insulin:C-peptide) Diabetes > 1:1 C-Peptide ↓after insulin injection

REFERENCES:

Bishop, Michael L., et.al., Clinical Chemistry Techniques, Principles, Correlations, Sixth Edition
PER Handbook
Theriot, Betty, Clinical Laboratory Science Review: Bottom Line Approach
McPherson, Richard, et.al., Henry’s Clinical Diagnosis and Management by Laboratory Methods, 22e