Book contents
- Male and Sperm Factors that Maximize IVF Success
- Male and Sperm Factors that Maximize IVF Success
- Copyright page
- Contents
- Contributors
- Chapter 1 Sperm Selection for ART Success
- Chapter 2 New Horizons in Male Subfertility and Infertility
- Chapter 3 Chromosome Abnormalities and the Infertile Male
- Chapter 4 The Effect of Endocrine Disruptors and Environmental and Lifestyle Factors on the Sperm Epigenome
- Chapter 5 Lifestyle Factors and Sperm Quality
- Chapter 6 The Effect of Age on Male Fertility and the Health of Offspring
- Chapter 7 The Assessment and Role of Anti-sperm Antibodies
- Chapter 8 FSH Treatment in Male Infertility
- Chapter 9 Antioxidants to Improve Sperm Quality
- Chapter 10 The History of Utilization of IVF for Male Factor Subfertility
- Chapter 11 The Case Against Intracytoplasmic Sperm Injection for All
- Chapter 12 Perinatal Outcomes from IVF and ICSI
- Chapter 13 Artificial Insemination with Partner’s Sperm for Male Subfertility
- Chapter 14 Obstructive Azoospermia: Is There a Place for Microsurgical Testicular Sperm Extraction?
- Chapter 15 Should Varicocele Be Operated on Before IVF?
- Chapter 16 Donor Insemination: Past, Present and Future Perspectives
- Chapter 17 DNA Damage in Spermatozoa
- Chapter 18 Prevention of Male Infertility: From Childhood to Adulthood
- Index
- References
Chapter 17 - DNA Damage in Spermatozoa
Published online by Cambridge University Press: 24 May 2020
Book contents
- Male and Sperm Factors that Maximize IVF Success
- Male and Sperm Factors that Maximize IVF Success
- Copyright page
- Contents
- Contributors
- Chapter 1 Sperm Selection for ART Success
- Chapter 2 New Horizons in Male Subfertility and Infertility
- Chapter 3 Chromosome Abnormalities and the Infertile Male
- Chapter 4 The Effect of Endocrine Disruptors and Environmental and Lifestyle Factors on the Sperm Epigenome
- Chapter 5 Lifestyle Factors and Sperm Quality
- Chapter 6 The Effect of Age on Male Fertility and the Health of Offspring
- Chapter 7 The Assessment and Role of Anti-sperm Antibodies
- Chapter 8 FSH Treatment in Male Infertility
- Chapter 9 Antioxidants to Improve Sperm Quality
- Chapter 10 The History of Utilization of IVF for Male Factor Subfertility
- Chapter 11 The Case Against Intracytoplasmic Sperm Injection for All
- Chapter 12 Perinatal Outcomes from IVF and ICSI
- Chapter 13 Artificial Insemination with Partner’s Sperm for Male Subfertility
- Chapter 14 Obstructive Azoospermia: Is There a Place for Microsurgical Testicular Sperm Extraction?
- Chapter 15 Should Varicocele Be Operated on Before IVF?
- Chapter 16 Donor Insemination: Past, Present and Future Perspectives
- Chapter 17 DNA Damage in Spermatozoa
- Chapter 18 Prevention of Male Infertility: From Childhood to Adulthood
- Index
- References
Summary
All sperm accrue varying amounts of DNA damage during maturation and storage, a process that appears to be mediated through oxidative stress. The clinical significance of genetic damage in the male germ line depends upon severity and how that damage is distributed among the sperm population. In human reproduction, the embryo is capable of significant DNA repair, which occurs prior to the first cleavage event. However, when the magnitude of genomic damage reaches pathologic levels, reproductive outcomes begin to be affected. Evidence now exists linking excessive sperm DNA fragmentation with time to pregnancy for natural conception, pregnancy outcomes of intrauterine insemination and in vitro fertilization, and miscarriage rates when intracytoplasmic sperm injection is employed. This review will discuss the pathophysiology of sperm DNA damage, the studies linking it to impaired reproductive outcomes, and how clinicians may render treatment to optimize the chance of paternity for their patients.
- Type
- Chapter
- Information
- Male and Sperm Factors that Maximize IVF Success , pp. 199 - 210Publisher: Cambridge University PressPrint publication year: 2020
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