100 Examples of sentences containing the common noun "epileptogenesis"

Definition

Epileptogenesis refers to the process through which a healthy brain develops epilepsy, characterized by the progression from a normal state to one that is susceptible to recurrent seizures. It encompasses various biological, chemical, and physiological mechanisms that contribute to the onset of epilepsy.

Synonyms

• Seizure development
• Epileptic development
• Seizure genesis

Antonyms

• Seizure resolution
• Epilepsy remission
• Seizure prevention

Examples

1. Researchers continue to study how epileptogenesis occurs in the human brain.
2. Understanding epileptogenesis is crucial for developing effective treatments for epilepsy.
3. The team focused on the cellular changes that contribute to epileptogenesis.
4. Genetic factors play a significant role in the epileptogenesis process.
5. There is still much to learn about the triggers of epileptogenesis.
6. The study aims to identify biomarkers associated with epileptogenesis.
7. Early intervention may help prevent epileptogenesis in at-risk populations.
8. The research highlights the importance of understanding epileptogenesis for future therapies.
9. A better grasp of epileptogenesis could lead to groundbreaking treatments.
10. The mechanisms underlying epileptogenesis are still largely unknown.
11. Environmental factors may influence the rate of epileptogenesis.
12. The new drug shows promise in inhibiting epileptogenesis.
13. Scientists are exploring the link between inflammation and epileptogenesis.
14. Advances in imaging technology help visualize epileptogenesis.
15. The model used in the experiment simulates epileptogenesis accurately.
16. Stress has been shown to exacerbate epileptogenesis in some patients.
17. Researchers are investigating how metabolic disorders affect epileptogenesis.
18. The latest findings challenge previous theories of epileptogenesis.
19. Understanding epileptogenesis can aid in the development of preventative strategies.
20. Certain neurotransmitters are believed to play a role in epileptogenesis.
21. The team published their findings on epileptogenesis in a leading journal.
22. Disruptions in neural circuits may lead to epileptogenesis.
23. The researchers collected data to analyze the patterns of epileptogenesis.
24. The role of glial cells in epileptogenesis is an area of active research.
25. The seminar focused on the latest developments in epileptogenesis.
26. The genetic predisposition to epileptogenesis varies among individuals.
27. There is ongoing debate about the stages of epileptogenesis.
28. The patient’s history revealed factors contributing to epileptogenesis.
29. The findings could potentially alter the understanding of epileptogenesis.
30. Experimental treatments aim to halt the process of epileptogenesis.
31. Hereditary factors often complicate the study of epileptogenesis.
32. The link between trauma and epileptogenesis needs further exploration.
33. Changes in ion channels have been implicated in epileptogenesis.
34. The symposium featured discussions on the implications of epileptogenesis.
35. New insights into epileptogenesis emerged from recent clinical trials.
36. The research emphasizes the dynamic nature of epileptogenesis.
37. Understanding the timeline of epileptogenesis is crucial for treatment.
38. The effects of drug abuse on epileptogenesis are concerning.
39. The data collected will help clarify the mechanisms of epileptogenesis.
40. Hormonal changes can influence the process of epileptogenesis.
41. The study concluded that age is a significant factor in epileptogenesis.
42. Epileptogenesis may vary significantly between different types of epilepsy.
43. The researchers aim to develop a model to predict epileptogenesis.
44. The interaction between genetics and environment influences epileptogenesis.
45. The researchers are dedicated to unraveling the complexities of epileptogenesis.
46. The role of sleep in epileptogenesis is a growing area of interest.
47. The findings suggest a potential link between diet and epileptogenesis.
48. The research on epileptogenesis could benefit from multi-disciplinary approaches.
49. The implications of epileptogenesis extend beyond seizure management.
50. The accuracy of the model in predicting epileptogenesis was validated.
51. Understanding epileptogenesis can lead to better patient outcomes.
52. The role of neuroinflammation in epileptogenesis is being investigated.
53. The study provided new insights into the cellular basis of epileptogenesis.
54. The researchers are optimistic about the future of epileptogenesis research.
55. Insights into epileptogenesis can inform public health initiatives.
56. The complexity of epileptogenesis requires a collaborative research effort.
57. The review highlighted the need for more studies on epileptogenesis.
58. The clinical implications of epileptogenesis are far-reaching.
59. The team's findings suggest a novel approach to studying epileptogenesis.
60. The longitudinal study tracked changes related to epileptogenesis.
61. The effects of certain medications on epileptogenesis are under scrutiny.
62. The researchers hope to identify critical periods in epileptogenesis.
63. The model helps simulate different scenarios of epileptogenesis.
64. The findings will contribute to the understanding of epileptogenesis.
65. There is increasing interest in the relationship between metabolism and epileptogenesis.
66. The study explored how stress hormones affect epileptogenesis.
67. Advances in technology are revolutionizing the study of epileptogenesis.
68. The relationship between genetics and epileptogenesis is complex.
69. The researchers hope to map the pathways involved in epileptogenesis.
70. A deeper understanding of epileptogenesis could enhance therapeutic options.
71. The study's results shed light on the intricacies of epileptogenesis.
72. The connection between physical trauma and epileptogenesis is significant.
73. The research team is examining the role of synaptic plasticity in epileptogenesis.
74. The findings suggest potential interventions to mitigate epileptogenesis.
75. The research will focus on early indicators of epileptogenesis.
76. The influence of lifestyle choices on epileptogenesis is being studied.
77. The researchers aim to publish their results on epileptogenesis soon.
78. The study indicates a need for further exploration of epileptogenesis.
79. The effects of chronic stress on epileptogenesis are concerning.
80. The researchers are working to develop a framework for understanding epileptogenesis.
81. The team is collaborating with neurologists to study epileptogenesis.
82. The findings of the study have implications for understanding epileptogenesis.
83. There is a growing body of literature on the topic of epileptogenesis.
84. The research focuses on the early stages of epileptogenesis.
85. The impact of diet on epileptogenesis is an emerging field of study.
86. The researchers are hopeful that their work will clarify epileptogenesis.
87. The findings emphasize the importance of early intervention in epileptogenesis.
88. The cellular mechanisms involved in epileptogenesis are complex.
89. The study aims to uncover the factors that promote epileptogenesis.
90. The research indicates that lifestyle changes may influence epileptogenesis.
91. The ongoing research seeks to develop therapies targeting epileptogenesis.
92. The seminar addressed recent advancements in understanding epileptogenesis.
93. The team is focused on identifying the triggers of epileptogenesis.
94. The implications of the study extend to potential treatments for epileptogenesis.
95. The researchers are examining the neurobiological basis of epileptogenesis.
96. The role of the immune system in epileptogenesis is a topic of interest.
97. The study highlights the importance of research on epileptogenesis.
98. The findings could pave the way for new approaches to understanding epileptogenesis.
99. The research team is dedicated to unraveling the complexities of epileptogenesis.
100. There is a critical need for innovative research on epileptogenesis.