100 Examples of sentences containing the noun "cytometry"

Definition

Cytometry is a scientific technique used to measure the characteristics of cells, such as their size, shape, and the presence of specific cellular markers. It often utilizes flow cytometry, which involves suspending cells in a fluid and passing them through a laser beam to analyze their properties.

Synonyms

• Cell analysis
• Cell counting
• Flow cytometry
• Cell sorting
• Quantitative cytology

Antonyms

• Qualitative analysis
• Non-cytometric analysis

Examples

1. Researchers often use cytometry to quantify immune cell populations.
2. The lab specializes in cytometry techniques for cancer diagnostics.
3. Cytometry allows for the detailed analysis of cell morphology.
4. Many biomedical applications rely on the accuracy of cytometry.
5. The introduction of new reagents has improved the efficiency of cytometry.
6. In clinical settings, cytometry can help identify disease markers.
7. Advanced cytometry methods can analyze thousands of cells per second.
8. The accuracy of results in cytometry depends on proper calibration.
9. Cytometry is crucial for studying cellular responses to treatments.
10. The researchers are pioneering new methods in cytometry.
11. Using cytometry, scientists can differentiate between healthy and diseased cells.
12. The development of multiplex cytometry has enhanced diagnostic capabilities.
13. Cytometry plays a vital role in vaccine development and testing.
14. Learning to operate cytometry equipment takes time and practice.
15. The field of cytometry is rapidly evolving with technological advancements.
16. Cytometry can provide valuable insights into cell signaling pathways.
17. The study of apoptosis often utilizes cytometry techniques.
18. Cytometry is essential for monitoring cellular responses in immunotherapy.
19. Flow cytometry has revolutionized the way we analyze blood samples.
20. Researchers are exploring new applications for cytometry in regenerative medicine.
21. Cytometry techniques can be applied to both plant and animal cells.
22. The results from cytometry can lead to improved therapeutic strategies.
23. In cytometry, fluorescent markers are often used to identify specific cell types.
24. The lab's focus on cytometry has opened new avenues for research collaboration.
25. Cytometry can be used to assess cell viability in various experiments.
26. The integration of AI in cytometry is changing data analysis approaches.
27. Advances in mass cytometry allow for the analysis of many parameters simultaneously.
28. Cytometry is a key tool in understanding immune system functions.
29. The accuracy of cytometry results is critical for clinical decisions.
30. Cytometry techniques have broad applications in drug development.
31. The training program includes hands-on experience with cytometry.
32. Cytometry can help identify rare cell populations in a sample.
33. Researchers often publish their findings related to cytometry in leading journals.
34. The versatility of cytometry makes it suitable for a range of scientific disciplines.
35. Cytometry can be complex, requiring specialized knowledge and skills.
36. The workshop will cover the latest trends in cytometry research.
37. Cytometry has enhanced our understanding of cellular heterogeneity.
38. The lab conducts routine cytometry analyses for various studies.
39. Cytometry data can be visualized using sophisticated software tools.
40. Collaborations in cytometry have led to groundbreaking discoveries in immunology.
41. The precision of cytometry instruments is critical for accurate measurements.
42. Cytometry is utilized in both research and clinical laboratories.
43. The seminar will focus on new developments in cytometry technology.
44. Cytometry methods vary depending on the type of cells being analyzed.
45. The impact of cytometry on cancer research cannot be overstated.
46. Cytometry enables scientists to study cell interactions in real-time.
47. The field of cytometry is known for its rapid technological advancements.
48. Cytometry applications extend to environmental monitoring of microbial populations.
49. The researchers are exploring the use of cytometry in studying stem cells.
50. Cytometry is often paired with microscopy for comprehensive analysis.
51. The effectiveness of therapies can be monitored using cytometry.
52. The use of cytometry in clinical trials is becoming more common.
53. Cytometry helps in the identification of pathogens in clinical samples.
54. The principles of cytometry can be applied in various fields of biology.
55. Cytometry allows for the rapid assessment of cellular responses.
56. The scientists are developing new protocols for high-throughput cytometry.
57. Cytometry can be utilized to study cell cycle dynamics.
58. The future of cytometry looks promising with ongoing innovations.
59. The workshop will include practical sessions on cytometry.
60. Cytometry has applications in pharmacodynamics and pharmacokinetics.
61. The integration of robotics in cytometry is streamlining workflows.
62. Cytometry is a powerful tool for studying the immune system.
63. The accuracy of cytometry can be affected by sample preparation methods.
64. The researchers are investigating new fluorescent dyes for cytometry.
65. Cytometry is essential for understanding the mechanisms of diseases.
66. The collaboration aims to enhance cytometry techniques for better diagnostics.
67. The efficiency of cytometry can be improved with automation.
68. Cytometry can be used to evaluate the effects of environmental toxins on cells.
69. The lab's focus on cytometry has attracted funding for new projects.
70. Cytometry can provide insights into cellular aging and senescence.
71. The role of cytometry in vaccine research is increasingly recognized.
72. Cytometry techniques are being adapted for point-of-care testing.
73. The evolution of cytometry has led to the development of new biomarkers.
74. The accuracy of cytometry measurements is crucial for research outcomes.
75. Cytometry allows for the comprehensive profiling of cell populations.
76. The researchers are publishing their findings on novel cytometry methods.
77. Cytometry can aid in understanding tumor microenvironments.
78. The advancements in cytometry are contributing to personalized medicine.
79. The principles of cytometry are applicable in various research contexts.
80. The lab's commitment to cytometry research has garnered attention in the field.
81. Cytometry is essential for monitoring disease progression in patients.
82. The integration of cytometry data with genomics is a growing trend.
83. The course will cover advanced techniques in cytometry.
84. Cytometry can be utilized to assess the efficacy of new drug candidates.
85. The flexibility of cytometry methods enables diverse applications.
86. The impact of cytometry on public health research is significant.
87. The research team's expertise in cytometry is widely recognized.
88. Cytometry provides a quantitative approach to studying cells.
89. The use of cytometry is becoming standard in many laboratories.
90. Understanding the limitations of cytometry is crucial for accurate interpretation.
91. The integration of machine learning in cytometry is a promising development.
92. Cytometry can reveal important information about cell signaling networks.
93. The future of cytometry will likely involve more multi-parameter analysis.
94. The researchers are presenting their findings on the application of cytometry.
95. Cytometry is valuable for studying the effects of treatments on cell populations.
96. The evolution of cytometry technologies is enhancing research capabilities.
97. Cytometry is often a component of larger experimental designs.
98. The importance of cytometry in understanding cellular function continues to grow.
99. Ongoing training in cytometry is essential for laboratory personnel.
100. The researchers are collaborating on a project that focuses on innovative cytometry approaches.