Assay example sentences

"Assay" Example Sentences

1. Scientists conducted assays to determine the compound's effects.
2. The biologist performed an immunoassay to detect the antibodies.
3. They performed biochemical assays on the tissue samples.
4. The pharmacologist ran enzyme assays as part of the research project.
5. The chemist used assays to measure the concentration of elements.
6. The laboratory technician conducted assays on the blood and urine samples.
7. They performed functional assays to determine if the protein was active.
8. The geneticist ran gel electrophoresis assays to analyze DNA samples.
9. The toxicologist performed toxicity assays on the chemical compound.
10. The microbiologist tested bacteria in growth inhibition assays.
11. They assayed the metal ores to determine their gold content.
12. The alchemist assayed the metals to determine their purity.
13. The geologist assayed the rock samples to identify mineral deposits.
14. The metallurgist assayed the alloys to determine their properties.
15. The coin dealer assayed the antique coins to determine their purity and value.
16. They assayed the soil to determine mineral content and pH.
17. They assayed the ore to determine the percentage of precious metal.
18. The gemologist assayed the precious stones to determine their value.
19. The researcher assayed the compounds using high-throughput screening.
20. The scientist assayed the mixture using a colorimetric assay.
21. They assayed the cells under different conditions.
22. They assayed the serum samples for biomarkers.
23. They assayed the compounds using calcium flux assays.
24. The scientists assayed his blood to determine exposure levels.
25. They assayed the mixture to determine its composition.
26. The field biologist assayed the soil samples for nutrients.
27. They assayed the groundwater for environmental contaminants.
28. The technician assayed the substance using a titration analysis.
29. The chemist assayed the product to ensure it met specifications.
30. They assayed the extract to determine its activity and potency.
31. The assay showed promising results for the new drug compound.
32. The food scientist assayed the product to determine nutrient content.
33. They assayed the enzymes to determine their activity levels.
34. The metallurgist assayed the gold to determine its purity and fineness.
35. They assayed the mixture to determine concentrations of reactants.
36. The researcher assayed cells under a variety of conditions.
37. The lab technician assayed urine samples for drug metabolites.
38. Scientists assay compounds to determine biological activity.
39. Pharmacists assay medications to ensure potency and purity.
40. They assayed the metal alloys for strength and durability.
41. The jeweler assayed the gemstones to determine their carat weight.
42. They assayed the wine to determine alcohol content.
43. The biologist assayed the tissue samples for signs of damage.
44. They assayed the water samples for contaminants.
45. Forensic scientists assay evidence to aid in investigations.
46. They assayed the drug cocktail to determine therapeutic dose.
47. The doctors assayed blood samples to measure hormone levels.
48. Scientists assay substances using a variety of techniques.
49. They assayed the nutrients in produce to monitor quality.
50. The quality control technician assayed samples to test compliance.
51. The medical lab technician assayed blood samples for known biomarkers.
52. Chemists assay substances for quantity of known compounds.
53. Miners assay ore samples to determine mineral composition.
54. Pharmacologists assay drugs to determine efficacy, safety and dosage.
55. Historians assay artifacts to determine age and origin.
56. The process of assaying involves measuring and testing.
57. Assays are used to determine the properties of compounds.
58. Druggists historically assayed medications for purity and strength.
59. Assays provide quantitative or qualitative data on a substance.
60. Assays are a fundamental tool in science and research.

Common Phases

1. The researchers performed an enzyme-linked immunosorbent assay to test for the presence of antibodies.
2. The samples will be analyzed using standardized assays that have been validated for accuracy and reproducibility.
3. We determined glucose concentration by colorimetric assay.
4. Cells were lysed and protein concentration was determined by Bradford assay.
5. We used a luciferase reporter assay to measure transcriptional activity.
6. This new immunoassay method produces more accurate results with smaller sample volumes.
7. The chemiluminescent assay allowed for greater sensitivity in detection of the target protein.
8. The DNA was purified and quantified using spectrophotometric assay.
9. An ELISA assay was used to detect the presence of the antigen in serum samples.
10. The bioassay determined effective concentration at the 50% inhibition level.
11. The scientists worked to develop an improved assay for detecting biomarkers of disease.
12. A cytotoxicity assay was performed to measure cell viability.
13. The mineral content was determined through chemical assay procedures.
14. The new quantitative assay was able to detect even trace amounts of the toxin.
15. The serum samples were tested using an automated fluorescent immunoassay system.
16. We compared results from the new assay with the established method for validation purposes.
17. The plaque reduction assay confirmed that the compound inhibited viral replication.
18. A hemolytic assay was used to measure blood type.
19. Researchers are working to develop more sensitive assays for early disease detection.
20. The results of the colorimetric assay were confirmed through an independent validation study.
21. The potency of the drug was determined through bioassay procedures.
22. A growth inhibition assay was performed to study antibacterial activity.
23. They estimated mercury concentration using an atomic absorption assay.
24. We tested the peptide's activity using a cell-based functional assay.
25. The microbiological assay procedure requires fewer reagents and less equipment.
26. A ligand binding assay confirmed that the compound interacted with the biological target.
27. Antigenicity was assessed using an assay with polyclonal antibodies.
28. The soil samples were analyzed using a colorimetric assay for heavy metals.
29. The new assay is designed to be easy to perform with minimal training.
30. The dose-response curve was plotted based on assay results.
31. Physicians routinely order immunoassay tests as part of a diagnostic workup.
32. A fluorogenic assay was developed for real-time monitoring of enzyme activity.
33. The metal content of the alloys was determined through wet chemical assay methods.
34. An automated assay platform was used for high-throughput screening of chemical libraries.
35. The biological activity of the samples was assessed by functional assay.
36. The researcher developed a highly sensitive and specific radioactive assay.
37. They tested the compound using both in vitro and in vivo assay methods.
38. Blood glucose levels were measured using a colorimetric assay.
39. The gold nanoparticle-based assay provided faster results with lower costs.
40. The pharmacokinetic parameters were derived from assay data.
41. Vitamin levels were determined through microbiological assay.
42. The substrate for the enzymatic assay was synthesized in the laboratory.
43. The results of the two assays correlated well with each other.
44. Pharmacological activity was evaluated using an in vitro receptor binding assay.
45. Radioimmunoassay tests are highly sensitive but require specialized equipment and handling.
46. Various assay methods were evaluated to determine which was most appropriate.
47. Samples were diluted based on assay sensitivity requirements.
48. Assay performance characteristics were assessed for accuracy, precision, and reproducibility.
49. The selectivity of the assay was determined through interference studies.
50. Multiple quality control samples were run with each assay to monitor accuracy.
51. The radioenzymatic assay allows for detection of very low analyte levels.
52. They used a spectrophotometric assay to calculate enzyme activity.
53. An electrochemical assay was developed that does not require fluorescent labels.
54. The new multiplexed assay can detect up to eight analytes simultaneously.
55. Results from an in vivo assay confirmed the mechanism discovered in earlier studies.
56. The assay was performed in triplicate to obtain mean values.
57. An internal standard was added during sample preparation for the immunoassay.
58. The enzyme activity units were calculated based on calibration curves from the assay.
59. Researchers developed an immunoassay chip for automated diagnostic testing.
60. The half maximal effective concentration was calculated from assay dose-response data.