100 Examples of sentences containing the common noun "pseudopodial"

Definition

Pseudopodial refers to a characteristic or pertaining to a pseudopod, which is a temporary protrusion of the cytoplasm used by certain cells, particularly amoebae, for movement and feeding. It can also describe cellular structures that exhibit similar functions in various organisms.

Synonyms

• Pseudopod
• Cytoplasmic extension
• Protoplasmic extension

Antonyms

• None (as "pseudopodial" is a specific term without direct opposites in this context)

Examples

1. The amoeba pseudopodial movements allow it to capture food efficiently.
2. Researchers noted that the pseudopodial behavior was crucial for the survival of the organism.
3. The cell's pseudopodial extensions were visible under the microscope.
4. To understand its feeding mechanism, scientists studied the pseudopodial formations in detail.
5. The pseudopodial action helps in locomotion for many protozoans.
6. As the amoeba pseudopodial extended, it engulfed the surrounding bacteria.
7. The study focused on how pseudopodial dynamics influence cellular interactions.
8. In a lab setting, the pseudopodial movement was observed in real-time.
9. Some cells can exhibit pseudopodial behavior when responding to environmental stimuli.
10. The pseudopodial structure is essential for the amoeba's ability to adapt to various habitats.
11. By analyzing the pseudopodial formations, scientists gained insights into cell motility.
12. The pseudopodial extensions play a vital role in the immune response of certain cells.
13. During the experiment, the pseudopodial behavior was recorded and analyzed.
14. The pseudopodial movements were rapid and fluid, showcasing the cell's agility.
15. Evolutionarily, pseudopodial cells have adapted unique structures for survival.
16. The researchers were fascinated by the pseudopodial characteristics of the sample.
17. Observing pseudopodial movement can provide clues about cellular communication.
18. The pseudopodial structures are involved in the phagocytosis process.
19. The team hypothesized that pseudopodial actions could be influenced by external factors.
20. Cells exhibiting pseudopodial features are often more versatile in their functions.
21. The pseudopodial dynamics were compared across different species for the study.
22. A detailed analysis of the pseudopodial mechanisms revealed unexpected results.
23. The organism's pseudopodial extensions were crucial for its predatory lifestyle.
24. Upon closer inspection, the pseudopodial formations appeared to have intricate designs.
25. The pseudopodial behavior was documented in various environmental conditions.
26. The pseudopodial interactions between cells were critical for tissue formation.
27. The lab focused on the biochemical pathways involved in pseudopodial development.
28. Pseudopodial locomotion is a fascinating subject of study in cellular biology.
29. The pseudopodial network allowed the cells to communicate more effectively.
30. The researchers aimed to uncover the genetic basis of pseudopodial behavior.
31. The pseudopodial characteristics were distinct among the tested species.
32. Through their pseudopodial maneuvers, the cells were able to navigate complex environments.
33. The team observed how pseudopodial formation changed over time.
34. The pseudopodial structures were crucial for the organism’s feeding strategy.
35. The experiment highlighted the importance of pseudopodial motion in cell biology.
36. The pseudopodial behavior was particularly pronounced in low-nutrient environments.
37. Each pseudopodial extension served a functional purpose in the organism's life cycle.
38. The study of pseudopodial cells has implications for understanding cancer metastasis.
39. Researchers utilized imaging techniques to capture pseudopodial activities.
40. The pseudopodial features of the sample were analyzed for structural integrity.
41. The adaptability of the organism was largely due to its pseudopodial capabilities.
42. The pseudopodial extensions could change shape rapidly in response to stimuli.
43. Observing the pseudopodial behavior provided insights into evolutionary adaptations.
44. The pseudopodial action was integral to the cell's mobility and nutrient acquisition.
45. The study revealed how pseudopodial movement assists in immune system functions.
46. The pseudopodial formations were influenced by the surrounding microenvironment.
47. The pseudopodial dynamics were essential for successful cell division.
48. Each pseudopodial extension was unique in its function and structure.
49. The findings on pseudopodial behavior could inform future medical research.
50. The pseudopodial structures helped the cells to adapt to their environment.
51. The team mapped the pseudopodial connections among different cell types.
52. The pseudopodial action was observed during the cell’s feeding phase.
53. Researchers were intrigued by the pseudopodial adaptations seen in extreme environments.
54. The pseudopodial locomotion was a key feature of the species studied.
55. The role of pseudopodial structures in disease processes is an emerging research area.
56. The pseudopodial movements were documented as part of the cell's life cycle.
57. The pseudopodial behavior varied significantly between individuals of the same species.
58. The pseudopodial efficiency was measured to assess the health of the organism.
59. The pseudopodial formations were crucial for capturing prey in the wild.
60. The study aimed to quantify the effects of environmental changes on pseudopodial behavior.
61. The pseudopodial extensions facilitated the organism's ability to explore its environment.
62. The cellular response involved complex pseudopodial dynamics.
63. The pseudopodial movements were recorded over several hours for analysis.
64. The role of pseudopodial actions in wound healing was explored in this research.
65. The pseudopodial mechanisms are vital for understanding cell motility.
66. The pseudopodial behavior was influenced by various signaling pathways.
67. The researchers studied how pseudopodial dynamics change under stress conditions.
68. The ability to pseudopodial effectively is crucial for survival in many microorganisms.
69. The pseudopodial extensions allowed the cells to interact with their surroundings.
70. Observing pseudopodial motion in real-time provided valuable data.
71. The pseudopodial network facilitated communication between the cells.
72. The researchers focused on the genetic regulation of pseudopodial behavior.
73. The pseudopodial characteristics were essential for the organism's ecological niche.
74. The pseudopodial projections were instrumental in nutrient uptake.
75. The findings on pseudopodial dynamics could lead to new treatments for autoimmune diseases.
76. The pseudopodial extensions were significant for the organism's reproductive strategy.
77. The pseudopodial network was a focal point of the cellular communication study.
78. The pseudopodial behavior was an indication of the organism's health.
79. The role of pseudopodial action in cell migration is a key research area.
80. The pseudopodial extensions were monitored for their growth and development.
81. Investigating pseudopodial interactions can reveal much about cellular behavior.
82. The pseudopodial dynamics were crucial for understanding cell differentiation.
83. Researchers aimed to characterize the pseudopodial structures in various species.
84. The study highlighted the importance of pseudopodial function in microbial ecology.
85. The pseudopodial action was crucial during the organism's feeding cycle.
86. The pseudopodial mechanisms were analyzed to better understand their role in disease.
87. The pseudopodial formations were key to the organism's adaptation to its environment.
88. The pseudopodial behaviors observed could have implications for evolutionary biology.
89. The researchers documented the pseudopodial interactions during their experiments.
90. Understanding pseudopodial dynamics is essential for comprehending cellular life.
91. The pseudopodial extensions were designed for maximum efficiency in nutrient capture.
92. The pseudopodial action was recorded as part of the cell's response to stimuli.
93. The team analyzed how pseudopodial behavior varies among different species.
94. The pseudopodial structures provided insights into the evolutionary adaptations of cells.
95. Observations of pseudopodial movement helped clarify the cell’s feeding strategies.
96. The pseudopodial capabilities of the organism were critical for its ecological role.
97. The pseudopodial dynamics were influenced by the presence of other cells.
98. The study of pseudopodial behavior has implications for understanding cell biology.
99. The pseudopodial interactions were essential for the organism's survival.
100. The researchers were able to track the pseudopodial movements over time.