100 Examples of sentences containing the common noun "nondisjunction"

Definition

Nondisjunction refers to the failure of homologous chromosomes or sister chromatids to separate properly during cell division, specifically during meiosis or mitosis. This can result in gametes with an abnormal number of chromosomes, which may lead to genetic disorders in offspring.

Synonyms

• Chromosomal aberration
• Chromosomal non-disjunction
• Genetic anomaly

Antonyms

• Disjunction
• Chromosomal separation

Examples

1. Scientists have studied the effects of nondisjunction on genetic disorders for years.
2. The occurrence of nondisjunction can lead to conditions like Down syndrome.
3. In some cases, nondisjunction happens randomly during cell division.
4. Researchers are investigating how nondisjunction contributes to infertility.
5. The likelihood of nondisjunction increases with maternal age.
6. Genetic counseling can help families understand the implications of nondisjunction.
7. Many cancers are associated with nondisjunction of chromosomes.
8. The concept of nondisjunction was first described in the early 20th century.
9. Nondisjunction in meiosis can result in trisomy or monosomy in offspring.
10. The study of nondisjunction is crucial for understanding chromosomal disorders.
11. Nondisjunction can occur in both plant and animal cells.
12. Early detection of nondisjunction can aid in prenatal diagnosis.
13. Nondisjunction events can lead to mosaicism in individuals.
14. Geneticists aim to understand the mechanisms behind nondisjunction.
15. The phenomenon of nondisjunction can be observed in various species.
16. Nondisjunction can result in gametes with an abnormal number of chromosomes.
17. The impact of maternal age on nondisjunction rates is well documented.
18. Nondisjunction can be a significant factor in the development of hereditary diseases.
19. The risk of nondisjunction increases during the formation of eggs in females.
20. Understanding nondisjunction is essential for advancements in genetic therapies.
21. Some researchers are focusing on nondisjunction as a potential cause of autism.
22. Nondisjunction events can occur during the first or second meiotic division.
23. The effects of nondisjunction can be devastating for the affected individuals.
24. Nondisjunction can lead to genetic imbalances that affect development.
25. The diagnosis of nondisjunction often involves genetic testing.
26. Geneticists have identified several genes that may influence nondisjunction.
27. Nondisjunction is a key topic in the study of cytogenetics.
28. Many studies focus on the environmental factors that may induce nondisjunction.
29. Nondisjunction can occur in both somatic and germ cells.
30. The phenomenon of nondisjunction has serious implications for evolution.
31. Nondisjunction can lead to aneuploidy, which affects cellular function.
32. Educational programs often include information about nondisjunction.
33. The relationship between aging and nondisjunction is still being explored.
34. The chances of nondisjunction can vary between different types of organisms.
35. Nondisjunction can be a result of errors in the spindle assembly checkpoint.
36. The study of nondisjunction has implications for cancer research.
37. Nondisjunction events can be hereditary or sporadic.
38. Many genetic counselors discuss nondisjunction when advising parents.
39. The consequences of nondisjunction can be life-altering for families.
40. Prenatal screenings can detect conditions caused by nondisjunction.
41. Nondisjunction is often a topic of debate in genetics discussions.
42. The mechanisms behind nondisjunction are still not fully understood.
43. Researchers are exploring therapeutic options to correct nondisjunction.
44. Nondisjunction can result in a variety of congenital abnormalities.
45. The effects of nondisjunction can manifest in different ways depending on the chromosomes involved.
46. Nondisjunction can complicate the diagnosis of certain genetic conditions.
47. The study of nondisjunction is critical for understanding human evolution.
48. Various factors, including environmental toxins, may contribute to nondisjunction.
49. Nondisjunction is a significant area of research in reproductive biology.
50. New technologies are making it easier to study nondisjunction in detail.
51. Nondisjunction can affect any pair of chromosomes during cell division.
52. Some genetic disorders are specifically linked to nondisjunction of particular chromosomes.
53. Understanding the implications of nondisjunction is crucial for genetic research.
54. Geneticists are developing models to predict nondisjunction occurrences.
55. The effects of nondisjunction can sometimes be mitigated by early intervention.
56. Nondisjunction may contribute to the development of certain types of tumors.
57. The study of nondisjunction has illuminated many aspects of cell biology.
58. Nondisjunction can be a factor in the success rates of fertility treatments.
59. The relationship between nondisjunction and maternal health is being investigated.
60. Nondisjunction can lead to a range of developmental disorders.
61. Many people are unaware of the role that nondisjunction plays in genetics.
62. The occurrence of nondisjunction can vary among different populations.
63. Nondisjunction is often a focus in studies of human genetics.
64. The implications of nondisjunction extend beyond individual health to public health.
65. Nondisjunction can have profound effects on genetic diversity.
66. Some genetic tests can identify nondisjunction before birth.
67. Researchers are exploring how to prevent nondisjunction in future generations.
68. Nondisjunction can complicate the understanding of certain genetic traits.
69. The effects of nondisjunction can vary widely depending on timing.
70. Geneticists are working to identify factors that exacerbate nondisjunction.
71. The study of nondisjunction is integral to understanding chromosomal stability.
72. Nondisjunction can lead to complex genetic mosaics in some individuals.
73. The concept of nondisjunction helps explain the origins of some cancers.
74. Researchers are keen to learn how environmental factors influence nondisjunction.
75. Genetic counseling often includes discussions about the risks of nondisjunction.
76. The ramifications of nondisjunction are significant in reproductive health.
77. Nondisjunction can affect the viability of certain embryos.
78. The biological mechanisms behind nondisjunction are an active area of research.
79. Nondisjunction has been observed in various organisms, from yeast to humans.
80. The study of nondisjunction provides insights into chromosome behavior.
81. Nondisjunction can result in various genetic syndromes.
82. Understanding nondisjunction is crucial for advancements in genetic engineering.
83. Many researchers focus on preventing the occurrence of nondisjunction.
84. Nondisjunction can be detected through various genetic screening methods.
85. The effects of nondisjunction are often studied in relation to population genetics.
86. Nondisjunction may lead to unexpected results in scientific experiments.
87. The role of nondisjunction in evolution is a topic of scholarly debate.
88. Nondisjunction can disrupt normal cellular processes.
89. The likelihood of nondisjunction varies between different types of cell division.
90. Nondisjunction events can sometimes be a target for gene therapy.
91. Many genetic conditions are rooted in the phenomenon of nondisjunction.
92. Understanding the timing of nondisjunction is essential for genetic research.
93. Nondisjunction can also affect the outcome of certain diseases.
94. The effects of nondisjunction can be observed in the laboratory setting.
95. Nondisjunction is often a key factor in discussions about genetic health.
96. The study of nondisjunction can inform practices in reproductive medicine.
97. Nondisjunction can lead to unexpected genetic outcomes in breeding programs.
98. The relationship between nondisjunction and age is a crucial area of study.
99. Understanding nondisjunction can help improve genetic counseling practices.
100. The implications of nondisjunction are far-reaching in the field of genetics.