1. Laboratory tests Interpreting results

2. Why tests are needed Detection, Diagnosis and Treatment of diseases in patients Presence, extent, or absence of disease Monitor the effectiveness of treatment 60 to 70 percent of all decisions regarding a patient's diagnosis and treatment, hospital admission and discharge are based on laboratory test results.

3. Chemical, biological, hematological, immunologic, microscopic and bacteriological tests Microscopic examination and chemical analysis of blood, body fluids (e.g., urine, peritoneal fluid, cerebrospinal fluid), tissues and cells as glucose and cholesterol Identification of bacteria, parasites and other microorganisms Cross match blood for transfusion. Perform differential cell counts for abnormal cells to aid in the diagnosis of anemia and leukemia Utilize sophisticated equipment and instruments which can perform a number of tests simultaneously, as well as microscopes, cell counters, and other high-precision laboratory equipment

4. The primary purpose of a clinical chemistry laboratory is to: – facilitate the correct performance of analytic procedures that yield accurate and precise information, aiding patient diagnosis and treatment.

5. Units of Measure Any meaningful quantitative laboratory result consists of two components: – the first component represents the number related to the actual test value – label identifying the units. The unit defines the physical quantity or dimension, such as mass, length, time, or volume. System of international units Conventional units

6. System of International units is preferred in scientific literature Clinical laboratories is the only system employed in many countries. This system was devised to provide the global scientific community with a uniform method of describing physical quantities.

8. Reagents little need for reagent preparation by the clinical laboratory reagents in ready-to-use form or in a “kit” form requiring only the addition of water or buffer to the prepackaged reagent components for reconstitution

9. Chemicals Analytic chemicals exist in varying grades of purity: – analytic reagent (AR) – Ultrapure – chemically pure (CP); – United States Pharmacopeia (USP) – National Formulary (NF)and technical or commercial grade

10. A committee of the American Chemical Society established specifications for AR grade chemicals, and chemical manufacturers will either meet or exceed these requirements. Labels on reagents state the actual impurities for each chemical lot or list the maximum allowable impurities. The labels should be clearly printed with the percentage of impurities present and either the initials AR or ACS or the term For laboratory use or ACS Standard-Grade Reference Materials.

11. Chemicals of this category are suitable for use in most analytic laboratory procedures. Ultrapure chemicals have been put through additional purification steps for use in specific procedures such as chromatography, atomic absorption, immunoassays, molecular diagnostics, standardization, or other techniques that require extremely pure chemicals. These reagents may carry designations of HPLC (high-performance liquid chromatography) or chromatographic on their labels

12. USP and NF grade chemicals are used to manufacture drugs not being injurious to individuals. Chemicals in this group may be pure enough for use in most chemical procedures; however, it should be recognized that the purity standards are not based on the needs of the laboratory and, therefore, may or may not meet all assay requirements.

13. CP or pure grade indicate that the impurity limitations are not stated and that preparation of these chemicals is not uniform. Melting point analysis is often used to ascertain the acceptable purity range. It is not recommended that clinical laboratories use these chemicals for reagent preparation unless further purification or a reagent blank is included. Technical or commercial grade reagents are used primarily in manufacturing and should never be used in the clinical laboratory.

14. Occupational Safety and Health Administration (OSHA) Clearly indicate – the lot number, plus any – physical or biologic health hazard and – precautions needed for the safe use and storage of any chemical. A manufacturer is required to provide technical data sheets for each chemical manufactured on a document called a Material Safety Data Sheet (MSDS).

15. Standards Primary standard – a highly purified chemical that can be measured directly to produce a substance of exact known concentration and purity. The – ACS purity tolerances for primary standards are 100 + 0.02%. Because most biologic constituents are unavailable within these limitations, the National Institute of Standards and Technology certified standard reference materials (SRMs) are used

16. Secondary standard A secondary standard is a substance of lower purity, with its concentration determined by comparison with a primary standard. The secondary standard depends not only on its composition, which cannot be directly determined, but also on the analytic reference method. Once again, because physiologic primary standards are generally unavailable, clinical chemists do not by definition have “true” secondary standards.

17. Water Specifications Distilled water made by only distillation Deionized water Water purified by ion exchange RO water Reverse osmosis, which pumps water across a semipermeable membrane. Water can also be purified by ultrafiltration, ultraviolet light, sterilization, or ozone treatment. Laboratory requirements generally call for reagent grade water (Clinical and Laboratory Standards Institute (CLSI)), is classified into one of six categories based on the specifications needed for its use rather than the method of purification or preparation.

18. Clinical laboratory reagent water (CLRW), Special reagent water (SRW) Instrument feed water, Water supplied by method manufacturer Autoclave and wash water Commercially bottled purified water.

19. Variables that may affect test results