The impact of sperm DNA damage in assisted conception and beyond: recent advances in diagnosis and treatment

Sheena E.M. Lewis; R. John Aitken; Sarah J. Conner; Geoffry De Iuliis; Donald P. Evenson; Ralph Henkel; Aleksander Giwercman; Parviz Gharagozloo

doi:10.1016/j.rbmo.2013.06.014

Review| Volume 27, ISSUE 4, P325-337, October 2013

Download started.

Ok

The impact of sperm DNA damage in assisted conception and beyond: recent advances in diagnosis and treatment

Sheena E.M. Lewis
Sheena E.M. Lewis
Correspondence
Corresponding author.
Contact
Affiliations
Centre for Public Health, Institute of Clinical Sciences, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, Northern Ireland, UK
Search for articles by this author
R. John Aitken
R. John Aitken
Affiliations
Discipline of Biological Sciences, School of Environmental and Life Sciences, University of Newcastle, Callaghan, NSW 2308, Australia
Search for articles by this author
Sarah J. Conner
Sarah J. Conner
Affiliations
Reproductive Biology and Genetics Group, School of Clinical and Experimental Medicine College of Medical and Dental Sciences, Institute for Biomedical Research, University of Birmingham, Room SG6A, Ground Floor IBR West, Edgbaston, Birmingham B15 2TH, UK
Search for articles by this author
Geoffry De Iuliis
Geoffry De Iuliis
Affiliations
Reproductive Science Group, University of Newcastle, School of Environmental and Life Sciences, University Drive, Callaghan, NSW 2308, Australia
Search for articles by this author
Donald P. Evenson
Donald P. Evenson
Affiliations
SCSA Diagnostics, Inc. PO Box 107 219, Kasan Ave. Volga, SD 57071, USA
Search for articles by this author
Ralph Henkel
Ralph Henkel
Affiliations
University of the Western Cape, Department of Medical Bioscience, Bellville ZA-7535, South Africa
Search for articles by this author
Aleksander Giwercman
Aleksander Giwercman
Affiliations
Molecular Genetic Reproductive Medicine, Department of Clinical Sciences, Faculty of Medicine, Lund University, Lund, SE 205 02 Malmö, Sweden
Malmo Reproductive Medicine Centre, Skane University Hospital, Malmo, Sweden
Division of Occupational and Environmental Medicine, Lund University, Lund, Sweden
Search for articles by this author
Parviz Gharagozloo
Parviz Gharagozloo
Affiliations
CellOxess LLC, Pennington, NJ 08534, USA
Search for articles by this author

Published:July 15, 2013DOI:https://doi.org/10.1016/j.rbmo.2013.06.014

Abstract

Sperm DNA damage is a useful biomarker for male infertility diagnosis and prediction of assisted reproduction outcomes. It is associated with reduced fertilization rates, embryo quality and pregnancy rates, and higher rates of spontaneous miscarriage and childhood diseases. This review provides a synopsis of the most recent studies from each of the authors, all of whom have major track records in the field of sperm DNA damage in the clinical setting. It explores current laboratory tests and the accumulating body of knowledge concerning the relationship between sperm DNA damage and clinical outcomes. The paper proceeds to discuss the strengths, weaknesses and clinical applicability of current sperm DNA tests. Next, the biological significance of DNA damage in the male germ line is considered. Finally, as sperm DNA damage is often the result of oxidative stress in the male reproductive tract, the potential contribution of antioxidant therapy in the clinical management of this condition is discussed. DNA damage in human spermatozoa is an important attribute of semen quality. It should be part of the clinical work up and properly controlled trials addressing the effectiveness of antioxidant therapy should be undertaken as a matter of urgency.

Sperm DNA damage is a useful biomarker for male infertility diagnosis and prediction of assisted reproduction outcomes. It is associated with reduced fertilization rates, embryo quality and pregnancy rates, and higher rates of spontaneous miscarriage and childhood diseases. With all of these fertility check points, it shows more promise than conventional semen parameters from a diagnostic perspective. Despite this, few infertility clinics use it routinely. This review provides a synopsis of the most recent studies from each of the authors, all of whom have major track records in the field of sperm DNA damage in the clinical setting. It explores current laboratory tests and the accumulating body of knowledge concerning the relationship between sperm DNA damage and clinical outcomes. The paper proceeds to discuss the strengths and weaknesses and clinical applicability of current sperm DNA fragmentation tests. Next, the biological significance of DNA damage in the male germ line is considered. Finally, as sperm DNA damage is often the result of increased oxidative stress in the male reproductive tract, the potential contribution of antioxidant therapy in the clinical management of this condition is discussed. As those working in this field of clinical research, we conclude that DNA damage in human spermatozoa is an important attribute of semen quality which should be carefully assessed in the clinical work up of infertile couples and that properly controlled trials addressing the effectiveness of antioxidant therapy should be undertaken as a matter of urgency.

Keywords

Introduction

Male factor infertility is implicated in more than 40% of couples presenting for assisted reproduction treatment. Conventional semen analysis continues to be the only routine test to diagnose this condition even though it is known that such descriptive assessments cannot discriminate between the spermatozoa of fertile and infertile men (

Guzick et al., 2001

Guzick D.S.
Overstreet J.W.
Factor-Litvak P.
Brazil C.K.
Nakajima S.T.
Coutifaris C.
Carson S.A.
Cisneros P.
Steinkampf M.P.
Hill J.A.
et al.

National Co-operative Reproductive Medicine Network. Sperm morphology, motility, and concentration in fertile and infertile men.

). The shifting values for normality (all ‘normal’ values now lower) in the fifth edition of the WHO manual (

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

) compared with the previous WHO editions may result in even less men being classified as infertile (

Murray et al., 2012

Murray K.S.
James A.
McGeady J.B.
Reed M.L.
Kuang W.W.
Nangia A.K.

The effect of the new 2010 World Health Organization criteria for semen analyses on male infertility.

).

A growing number of studies report sperm DNA damage to be useful as a diagnostic tool for male infertility. This criterion of sperm quality is useful as a predictor of treatment success as suggested by its associations at numerous points in the reproductive process including impaired fertilization, disrupted preimplantation embryo development, miscarriage and birth defects in the offspring (

Bungum et al., 2012

Bungum M.
Bungum L.
Lynch K.F.
Wedlund L.
Humaidan P.
Giwercman A.

Spermatozoa DNA damage measured by sperm chromatin structure assay (SCSA) and birth characteristics in children conceived by IVF and ICSI.

,

Lewis and Aitken, 2005

Lewis S.E.
Aitken R.J.

DNA damage to spermatozoa has impacts on fertilization and pregnancy.

,

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

,

Zini, 2011

Zini A.

Are sperm chromatin and DNA defects relevant in the clinic?.

,

Zini et al., 2008

Zini A.
Boman J.M.
Belzile E.
Ciampi A.

Sperm DNA damage is associated with an increased risk of pregnancy loss after IVF and ICSI: systematic review and meta-analysis.

). Childhood cancers have been also been associated with oxidative damage to sperm DNA as a consequence of paternal smoking (

Fraga et al., 1996

Fraga C.G.
Motchnik P.A.
Wyrobek A.J.
Rempel D.M.
Ames B.N.

Smoking and low antioxidant levels increase oxidative damage to DNA.

,

Ji et al., 1997

Ji B.T.
Shu X.O.
Linet M.S.
Zheng W.
Wacholder S.
Gao Y.T.
Ying D.M.
Jin F.

Paternal cigarette smoking and the risk of childhood cancer among offspring of nonsmoking mothers.

).

DNA damage in spermatozoa is primarily from oxidative stress (

Aitken et al., 2010

Aitken R.J.
De Iuliis G.N.
Finnie J.M.
Hedges A.
McLachlan R.I.

Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.

). In any semen sample, the vast majority of spermatozoa are abnormal (

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

). The spermatozoa that reflect such stress most profoundly are those morphologically abnormal cells that were destined for apoptosis but the process was incomplete or those cells that have experienced defective chromatin remodelling during spermiogenesis. Such defective spermatozoa are also thought to retain excess residual cytoplasm, allowing them to generate excessive reactive oxygen species (ROS), which, given their incomplete chromatin packaging, induces DNA damage (

Aitken et al., 2010

Aitken R.J.
De Iuliis G.N.
Finnie J.M.
Hedges A.
McLachlan R.I.

Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.

).

DNA damage has long been the recognized universal indicator of cell lethality in toxicology laboratories in the pharmaceutical industry. Spermatozoa are no different. Sperm DNA damage is a robust indicator of cellular ill health. Now, with the aid of advances in assisted reproduction, fertilization can be achieved in vitro with spermatozoa that would have been rejected in vivo. However, by using spermatozoa with compromised DNA for assisted conception, the long-term health and wellbeing of children conceived by assisted reproduction treatment are being put at risk. As a matter of ‘best practice’, the DNA quality of male gametes should be tested before they are used clinically.

Unfortunately, as spermatozoa have few repair mechanisms, DNA damage is commonly encountered in human spermatozoa, even within the fertile donor population (

Simon et al., 2010

Simon L.
Lutton D.
McManus J.
Sheena E.
Lewis M.

Clinical significance of sperm DNA damage in reproductive outcome.

). However, what is important clinically is the level of damage that adversely impacts on treatment outcomes. For any test to be useful diagnostically or prognostically, it must have a threshold value which provides adequate discriminatory power in the clinical situation. Routine semen analysis does not meet these standards (

Guzick et al., 2001

Guzick D.S.
Overstreet J.W.
Factor-Litvak P.
Brazil C.K.
Nakajima S.T.
Coutifaris C.
Carson S.A.
Cisneros P.
Steinkampf M.P.
Hill J.A.
et al.

National Co-operative Reproductive Medicine Network. Sperm morphology, motility, and concentration in fertile and infertile men.

,

Lefièvre et al., 2007

Lefièvre L.
Bedu-Addo K.
Conner S.J.
Machado-Oliveira G.S.
Chen Y.
Kirkman-Brown J.C.
Afnan M.A.
Publicover S.J.
Ford W.C.
Barratt C.L.

Counting sperm does not add up any more: time for a new equation?.

; reviewed by

Lewis, 2007

Lewis S.

Is sperm evaluation useful in predicting human fertility?.

,

Barratt et al., 2011

Barratt C.L.
Mansell S.
Beaton C.
Tardif S.
Oxenham S.K.

Diagnostic tools in male infertility – the question of sperm dysfunction.

), so improved assays are needed.

Benefits and limitations of current semen tests

Sperm numbers and quality, along with normal seminal plasma constituents, are crucial for fertility in vivo, so a semen analysis evaluating these parameters has long been the cornerstone of male infertility diagnosis. WHO provides guidance for semen analysis via a detailed laboratory manual and associated reference values (

Cooper et al., 2010

Cooper T.G.
Noonan E.
von Eckardstein S.
Auger J.
Baker H.W.
Behre H.M.
Haugen T.B.
Kruger T.
Wang C.
Mbizvo M.T.
Vogelsong K.M.

World Health Organization reference values for human semen characteristics.

,

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

). The current minimum standard is assessment of seminal plasma by volume, appearance and liquefaction of the ejaculate, and, for spermatozoa, measurement of concentration, motility and morphology (

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

). The recently revised WHO reference values are based on samples analysed according to WHO guidelines from 1953 men in nine countries on three continents with time to pregnancy 12 months or less. This represents a significantly better reference population than previous editions of the guidelines, although it has been argued that there is still room for improvement (

Cooper et al., 2010

Cooper T.G.
Noonan E.
von Eckardstein S.
Auger J.
Baker H.W.
Behre H.M.
Haugen T.B.
Kruger T.
Wang C.
Mbizvo M.T.
Vogelsong K.M.

World Health Organization reference values for human semen characteristics.

,

Esteves et al., 2012

Esteves S.C.
Zini A.
Aziz N.
Alvarez J.G.
Sabanegh Jr., E.S.
Agarwal A.

Critical appraisal of World Health Organization’s new reference values for human semen characteristics and effect on diagnosis and treatment of subfertile men.

,

World Health Organization, 1999

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

). Analysis of semen samples is complicated by intersample variability caused by both technical and biological factors (reviewed in

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

) and WHO recommends the analysis of two or three samples. Consistency can be improved by implementation of quality assurance and staff training (

Björndahl et al., 2002

Björndahl L.
Barratt C.L.
Fraser L.R.
Kvist U.
Mortimer D.

ESHRE basic semen analysis courses 1995–1999: immediate beneficial effects of standardized training.

) but a significant issue is that many laboratories do not work to WHO guidelines (

Keel et al., 2002

Keel B.A.
Stembridge T.W.
Pineda G.
Serafy Sr., N.T.

Lack of standardization in performance of the semen analysis among laboratories in the United States.

,

Penn et al., 2011

Penn H.A.
Windsperger A.
Smith Z.
Parekattil S.J.
Kuang W.W.
Kolettis P.N.
Nangia A.K.

National semen analysis reference range reporting: adherence to the 1999 World Health Organization guidelines 10 years later.

,

Riddell et al., 2005

Riddell D.
Pacey A.
Whittington K.

Lack of compliance by UK andrology laboratories with World Health Organization recommendations for sperm morphology assessment.

). It is recommended that semen analysis should be complemented by other clinical assessments (physical examination, history, endocrine and genetic investigations) as appropriate (

Esteves et al., 2012

Esteves S.C.
Zini A.
Aziz N.
Alvarez J.G.
Sabanegh Jr., E.S.
Agarwal A.

Critical appraisal of World Health Organization’s new reference values for human semen characteristics and effect on diagnosis and treatment of subfertile men.

). However, in practice this is often overlooked (

Jequier, 2008

Jequier A.

Male Infertility: A Guide for the Clinician.

Google Scholar

).

In both natural and assisted conception (with the exception of intracytoplasmic sperm injection (ICSI)), motility is a vital function for transit to the oocyte and penetration of the oocyte vestments. The strict Tygerberg criteria for assessing sperm morphology recommended by

World Health Organization, 2010

World Health Organization

WHO Laboratory Manual for the Examination and Processing of Human Semen.

Google Scholar

are based on the morphology of spermatozoa capable of penetrating cervical mucus and binding to the zona pellucida and therefore have a basis in biology. There is no known link between normal head morphology and the genetic quality of a spermatozoon (

Menkveld et al., 1990

Menkveld R.
Stander F.S.
Kotze T.J.
Kruger T.F.
van Zyl J.A.

The evaluation of morphological characteristics of human spermatozoa according to stricter criteria.

,

Menkveld et al., 1991

Menkveld R.
Franken D.R.
Kruger T.F.
Oehninger S.
Hodgen G.D.

Sperm selection capacity of the human zona pellucida.

,

Ryu et al., 2001

Ryu H.M.
Lin W.W.
Lamb D.J.
Chuang W.
Lipshultz L.I.
Bischoff F.Z.

Increased chromosome X, Y, and 18 nondisjunction in sperm from infertile patients that were identified as normal by strict morphology: implication for intracytoplasmic sperm injection.

;

Simon et al., 2010

Simon L.
Lutton D.
McManus J.
Sheena E.
Lewis M.

Clinical significance of sperm DNA damage in reproductive outcome.

). This suggests that sperm DNA testing will add further information not available through a conventional semen analysis. Both motility and morphology measurements are highly sensitive to operator subjectivity/variability and further complicated by the highly heterogeneous nature of human sperm populations (

Jørgensen et al., 1997

Jørgensen N.
Auger J.
Giwercman A.
Irvine D.S.
Jensen T.K.
Jouannet P.
Keiding N.
Le Bon C.
MacDonald E.
Pekuri A.M.
et al.

Semen analysis performed by different laboratory teams: an intervariation study.

).

Although both sperm motility and morphology scores have repeatedly been found to positively correlate with fertilization rate (

Kruger et al., 1987

Kruger T.F.
Acosta A.A.
Simmons K.F.
Swanson R.J.
Matta J.F.
Veeck L.L.
Morshedi M.
Brugo S.

New method of evaluating sperm morphology with predictive value for human in vitro fertilization.

,

Eggert-Kruse et al., 1996

Eggert-Kruse W.
Schwarz H.
Rohr G.
Demirakca T.
Tilgen W.
Runnebaum B.

Sperm morphology assessment using strict criteria and male fertility under in-vivo conditions of conception.

,

Bonde et al., 1998

Bonde J.P.
Ernst E.
Jensen T.K.
Hjollund N.H.
Kolstad H.
Henriksen T.B.
Scheike T.
Giwercman A.
Olsen J.
Skakkebaek N.E.

Relation between semen quality and fertility: a population-based study of 430 first-pregnancy planners.

,

Coetzee et al., 1998

Coetzee K.
Kruge T.F.
Lombard C.J.

Predictive value of normal sperm morphology: a structured literature review.

,

Larsen et al., 2000

Larsen L.
Scheike T.
Jensen T.K.
Bonde J.P.
Ernst E.
Hjollund N.H.
Zhou Y.
Skakkebaek N.E.
Giwercman A.

Computer-assisted semen analysis parameters as predictors for fertility of men from the general population. The Danish First Pregnancy Planner Study Team.

,

Van Waart et al., 2001

Van Waart J.
Kruger T.F.
Lombard C.J.
Ombelet W.

Predictive value of normal sperm morphology in intrauterine insemination (IUI): a structured literature review.

,

Ombelet et al., 2003

Ombelet W.
Deblaere K.
Bosmans E.
Cox A.
Jacobs P.
Janssen M.
Nijs M.

Semen quality and intrauterine insemination.

,

Haugen et al., 2006

Haugen T.B.
Egeland T.
Magnus O.

Semen parameters in Norwegian fertile men.

,

Nallella et al., 2006

Nallella K.P.
Sharma R.K.
Aziz N.
Agarwal A.

Significance of sperm characteristics in the evaluation of male infertility.

,

Merviel et al., 2010

Merviel P.
Heraud M.H.
Grenier N.
Lourdel E.
Sanguinet P.
Copin H.

Predictive factors for pregnancy after intrauterine insemination (IUI): an analysis of 1038 cycles and a review of the literature.

,

Simon and Lewis, 2011

Simon L.
Lewis S.E.

Sperm DNA damage or progressive motility: which one is the better predictor of fertilization in vitro?.

), a detailed analysis of a large cohort of fertile and subfertile men by

Guzick et al., 2001

Guzick D.S.
Overstreet J.W.
Factor-Litvak P.
Brazil C.K.
Nakajima S.T.
Coutifaris C.
Carson S.A.
Cisneros P.
Steinkampf M.P.
Hill J.A.
et al.

National Co-operative Reproductive Medicine Network. Sperm morphology, motility, and concentration in fertile and infertile men.

showed an extensive overlap in the semen profiles of the two groups. They concluded that sperm morphology, motility and concentration reference values could be no more than a guide to reproductive potential, aligning with reports that the (1999) WHO reference values were not clinically predictive (

Nallella et al., 2006

Nallella K.P.
Sharma R.K.
Aziz N.
Agarwal A.

Significance of sperm characteristics in the evaluation of male infertility.

,

Van der Steeg et al., 2011

Van der Steeg J.W.
Steures P.
Eijkemans M.J.
Habbema J.D.
Hompes P.G.
Kremer J.A.
van der Leeuw-Harmsen L.
Bossuyt P.M.
Repping S.
Silber S.J.
Mol B.W.
van der Veen F.

Collaborative Effort for Clinical Evaluation in Reproductive Medicine Study Group. Role of semen analysis in subfertile couples.

), although it is clearly too soon to judge whether the new WHO values provide a correlation with outcome. Very few (0.0041%) spermatozoa (

Williams et al., 1993

Williams M.
Hill C.J.
Scudamore I.
Dunphy B.
Cooke I.D.
Barratt C.L.

Sperm numbers and distribution within the human female fallopian tube around ovulation.

) reach the site of fertilization in vivo, This is supported by animal data where considerably fewer than 1% of spermatozoa reach the ampulla of the oviduct at the time of fertilization. Thus to expect an analysis of the gross parameters of the whole ejaculate to give strong discriminatory information is not realistic. There are many obstacles that a spermatozoon must overcome on its long journey to fertilize an oocyte and what is required are tests of sperm function to replace, or supplement, the surrogate measures currently being used (

Lefièvre et al., 2007

Lefièvre L.
Bedu-Addo K.
Conner S.J.
Machado-Oliveira G.S.
Chen Y.
Kirkman-Brown J.C.
Afnan M.A.
Publicover S.J.
Ford W.C.
Barratt C.L.

Counting sperm does not add up any more: time for a new equation?.

). It is estimated that a significant proportion of men with unexplained infertility have a cause attributed after sperm genomic testing (

Bungum et al., 2007

Bungum M.
Humaidan P.
Axmon A.
Spano M.
Bungum L.
Erenpreiss J.
Giwercman A.

Sperm DNA integrity assessment in prediction of assisted reproduction technology outcome.

). In its current form, semen analysis should be considered only as a means of identifying men whose chance of achieving a natural pregnancy is reduced.

Current sperm DNA damage tests

In recent years, the Comet, SCSA, Halo and TUNEL assays have been studied extensively to analyse sperm chromatin integrity. Criticisms have been made that the results from these tests are not equivalent. This is to be expected because, although each test evaluates sperm DNA quality, each may be elucidating a different aspect of DNA damage.

Further, the parameter, DNA fragmentation index (DFI), seems to have become the generic term for all ‘DNA’ tests but is only applicable to the SCSA test.

The Comet assay

The Comet assay is a single-cell gel electrophoretic assay that quantifies broken strands of DNA in individual spermatozoon. Within an agarose gel, the sperm membranes are lysed and the DNA decondensed in a high-concentration salt solution. Disulphide bridges are broken down and then the spermatozoon is placed in an electrophoretic field where strands of charged broken DNA stream towards the cathode. As the mass of DNA fragments stream out from the ‘head’ of unbroken DNA they resemble a ‘comet tail’, hence the name of the assay. One major advantage of this assay is that only 5000 spermatozoa from a clinical sample are needed so it is suitable for assessment of small portions of semen left over after clinical use and also for oligozoospermic samples or testicular samples where only a few spermatozoa are available.

The Comet assay is sensitive (

Irvine et al., 2000

Irvine S.D.
Twigg J.P.
Gordon E.L.
Fulton N.
Milne P.A.
Aitken J.R.

DNA integrity in human spermatozoa: relationships with semen quality.

,

Trisini et al., 2004

Trisini A.T.
Singh N.P.
Duty S.M.
Hauser R.

Relationship between human semen parameters and deoxyribonucleic acid damage assessed by the neutral comet assay.

,

Aitken and De Iuliis, 2007

Aitken R.J.
De Iuliis G.N.

Origins and consequences of DNA damage in male germ cells.

) and is able to detect degrees of DNA damage in an individual spermatozoon rather than a percentage of damaged spermatozoa in a whole sample. The Comet assay also measures single- and double-strand breaks, as well as altered bases. This is useful as it is not yet known which types of DNA damage are most deleterious to male fertility. A further advantage is that, unlike some other tests which detect primarily breaks in protamine-associated chromatin, the Comet assay has a broader use in detecting breaks in both protamine- and histone-bound chromatin equally. The clinical thresholds for diagnosis of male infertility and prediction of success with IVF (

Simon et al., 2010

Simon L.
Lutton D.
McManus J.
Sheena E.
Lewis M.

Clinical significance of sperm DNA damage in reproductive outcome.

,

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

,

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

) have now been established by studies of over 500 couples. Unlike the SCSA that gives a DFI value based on the number of spermatozoa in an ejaculate with detectable damage (subdivided into categories of non-detectable-, moderate- and high-damage groups), the Comet can quantify damage from 0 to 100% for each individual spermatozoon. The Comet is so sensitive that DNA damage is observed in every spermatozoon; even from fertile donors. The threshold values from the Comet assay are measures of the mean damage from groups of individual spermatozoon, above which spontaneous conception or success with IVF is less likely (

Simon et al., 2010

Simon L.
Lutton D.
McManus J.
Sheena E.
Lewis M.

Clinical significance of sperm DNA damage in reproductive outcome.

,

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

).

Analysis of repeatability was performed using an analysis of repeatability with the residual variance from the analysis of within-laboratory variance for single DNA damage measurements. It is 3.7% but decreases to 2.6% and 2.2% for duplicates and triplicates, respectively (ISO 5725:1994(E) guidelines for determination of repeatability of a standard measurement method; as described in

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

). In light of these results, analysis of just 50 of the 5000 spermatozoa assayed is sufficient to provide a measurement of DNA damage in the total sperm population with a coefficient of variation lower than 4%.

In a recent study using the Comet assay, the effects of male infertility alone on assisted reproduction were evaluated by excluding all couples presenting with female factors or without detectable fertility problems from either partner (idiopathic infertility;

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

). This study design allowed clinical thresholds for male infertility (25%), success with IVF (25–50%) or the need for ICSI (>50%) to be identified.

Most recently, live birth data has been reported for the first time using the Comet assay. Couples whose pregnancy resulted in a live birth had significantly lower sperm DNA fragmentation than those couples who did not achieve a live birth following IVF treatment (

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

). With the benefits of the Comet assay’s sensitivity, almost half previously unexplained couples now have a diagnosis in the form of sperm DNA damage (

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

). In this latest study, high levels of sperm DNA damage were also associated with the markedly lower live birth rates following IVF in both men and couples with idiopathic infertility.

The usefulness of progressive sperm motility compared with DNA damage as predictive tools for IVF rates has also reported using the Comet assay (

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

). Progressive motility is the only semen parameter that correlates with sperm DNA damage. This may be explained as a real-time functional test of sperm vitality. However, while fertilization rates are directly dependent upon both sperm progressive motility and DNA fragmentation, the latter is a stronger test, with an odds ratio of 24.18 (95% CI 5.21–154.51) to determine fertilization outcome compared with 4.81 (95% CI 1.89–12.65) for progressive motility.

The sperm chromatin structure assay

The pioneering work describing flow cytometry measurements of sperm nuclear DNA fragmentation was published by Evenson et al. in 1980. A significant advantage of this assay, the sperm chromatin structure assay (SCSA), is the simultaneous measure of two important fertility-dependent factors (

Evenson et al., 1980

Evenson D.P.
Darzynkiewicz Z.
Melamed M.R.

Relation of mammalian sperm chromatin heterogeneity to fertility.

): DFI and the presence of immature sperm nuclei with abnormal proteins and/or altered protamine/histone ratios (high DNA stainability, HDS; reviewed by

Evenson et al., 1999

Evenson D.P.
Jost L.K.
Marshall D.
Zinaman M.J.
Clegg E.
Purvis K.
de Angelis P.
Claussen O.P.

Utility of the sperm chromatin structure assay as a diagnostic and prognostic tool in the human fertility clinic.

,

Evenson et al., 2007

Evenson D.P.
Kasperson K.
Wixon R.L.

Analysis of sperm DNA fragmentation using flow cytometry and other techniques.

). The SCSA is technically much less demanding than any other DNA fragmentation test and can be conducted on fresh or frozen–thawed semen within minutes rather than hours. It has only two straightforward biochemical steps: (i) treat the raw semen dilution with pH 1.2 buffer for 30 s; and (ii) stain the spermatozoa with acridine orange, a dye that reveals broken DNA as red fluorescence and unbroken DNA strands as green fluorescence (

Darzynkiewicz et al., 1975

Darzynkiewicz Z.
Traganos F.
Sharpless T.
Melamed M.R.

Thermal denaturation of DNA in situ as studied by acridine orange staining and automated cytofluorometry.

). Both the 30-s low-pH-induced opening of the DNA strands at sites of DNA breaks and the biochemical interaction between acridine orange and DNA/chromatin are precisely repeatable. This is proven by comparing cytogram scatter plots with 1024 channels for both X (red) and Y (green) fluorescence values in repeat measures of individual semen samples (

Evenson et al., 1991

Evenson D.P.
Jost L.K.
Baer R.K.
Turner T.W.
Schrader S.M.

Individuality of DNA denaturation patterns in human sperm as measured by the sperm chromatin structure assay.

). The 5000 dots, each representing single spermatozoon, were in virtually identical X, Y coordinates (±five channels). This scale ranges from 0–1000 and includes normal spermatozoa with no detectable DNA fragmentation to those with 100% DNA fragmentation. Thus, the mean DFI is the mean amount of DNA fragmentation for 5000 spermatozoa. The frequency histogram of DFI allows a precision determination of the DFI. Such observations on over a hundred thousand SCSA measurements negate statements such as ‘the acid treatment tends to denature the DNA’, as if the SCSA protocol were poorly specific. The controversy regarding lack of unity in the utilization and interpretation of the SCSA data is due to incorrect implementation of the protocol. Furthermore, publications suggesting that the SCSA is of little value for clinical diagnosis and prognosis have been the result of low numbers of patients in some studies, lack of laboratory experience with the SCSA and especially the lack of screening out couples where the female partner had infertility issues.

The software SCSAsoft computes the raw red versus green fluorescence data as red/red + green fluorescence (

Evenson et al., 2002

Evenson D.P.
Larson K.
Jost L.K.

The sperm chromatin structure assay (SCSA™): clinical use for detecting sperm DNA fragmentation related to male infertility and comparisons with other techniques. Andrology Lab Corner.

). This produces a vertical dot pattern for non-denatured DNA and a horizontal dot pattern for spermatozoa with fragmented DNA. The SCSAsoft frequency histogram of DFI allows a precision determination of DFI. The standard deviation of DFI is a highly sensitive measure of animal infertility (

Ballachey et al., 1988

Ballachey B.E.
Saacke R.G.
Evenson D.P.

The sperm chromatin structure assay: relationship with alternate tests of sperm quality and heterospermic performance of bulls.

,

Didion et al., 2009

Didion B.
Kasperson K.
Wixon R.
Evenson D.P.

Boar fertility and sperm chromatin structure status: a retrospective report.

) and genotoxicant-induced DNA damage (

Sailer et al., 1997

Sailer B.
Sarkar L.J.
Bjordahl J.A.
Jost L.K.
Evenson D.P.

Effects of heat stress on mouse testicular cells and sperm chromatin structure.

,

Rubes et al., 2005

Rubes J.
Selevan S.G.
Evenson D.P.
Zudova D.
Vozdova M.
Zudova Z.
Robbins W.A.
Perreault S.D.

Episodic air pollution is associated with increased DNA fragmentation in human sperm without other changes in semen quality.

).

SCSA data are not correlated with the extent of free nuclear –SH groups (

Evenson et al., 2000

Evenson D.P.
Jost L.K.
Varner D.D.

Stallion sperm nuclear protamine-SH status and susceptibility to DNA denaturation are not strongly correlated.

), freezing and thawing (

Evenson et al., 1999

Evenson D.P.
Jost L.K.
Marshall D.
Zinaman M.J.
Clegg E.
Purvis K.
de Angelis P.
Claussen O.P.

Utility of the sperm chromatin structure assay as a diagnostic and prognostic tool in the human fertility clinic.

) or sonication and gradient purification of sperm nuclei (

Evenson et al., 1991

Evenson D.P.
Jost L.K.
Baer R.K.
Turner T.W.
Schrader S.M.

Individuality of DNA denaturation patterns in human sperm as measured by the sperm chromatin structure assay.

). In a study with 182 men, the percentage HDS was significantly correlated with the efficiency of chromatin remodelling, as measured by chromomycin A3 staining (r = 0.610, P < 0.0001). Interestingly, when men were given an antioxidant, their percentage DFI was reduced but HDS was increased (

Ménézo et al., 2007

Ménézo Y.J.
Hazout A.
Panteix G.
Robert F.
Rollet J.
Cohen-Bacrie P.
Chapuis F.
Clément P.
Benkhalifa M.

Antioxidants to reduce sperm DNA fragmentation: an unexpected adverse effect.

). Pregnancies were not observed with HDS above 35%. Following repeated studies (

Evenson et al., 1999

Evenson D.P.
Jost L.K.
Marshall D.
Zinaman M.J.
Clegg E.
Purvis K.
de Angelis P.
Claussen O.P.

Utility of the sperm chromatin structure assay as a diagnostic and prognostic tool in the human fertility clinic.

,

Spano et al., 2000

Spano M.
Bonde J.
Hjollund H.I.
Kolstad H.A.
Cordelli E.
Leter G.

Sperm chromatin damage impairs human fertility.

,

Evenson and Wixon, 2006a

Evenson D.P.
Wixon R.

Clinical aspects of sperm DNA fragmentation detection and male infertility.

,

Evenson and Wixon, 2006b

Evenson D.
Wixon R.

Meta-analysis of sperm DNA fragmentation using the sperm chromatin structure assay.

,

Bungum et al., 2007

Bungum M.
Humaidan P.
Axmon A.
Spano M.
Bungum L.
Erenpreiss J.
Giwercman A.

Sperm DNA integrity assessment in prediction of assisted reproduction technology outcome.

), an internationally accepted statistical threshold for natural and intrauterine insemination (IUI) conception of ∼25% DFI has been adopted.

The sperm chromatin dispersion

The sperm chromatin dispersion (SCD) or Halo test is marketed in a simple and inexpensive kit (Halotech DNA), available to fertility laboratories in kit form. The technique involves a simple differential chromatin decondensation step after which spermatozoa with DNA fragmentation are visually smaller than those with intact DNA, which appear to have a ‘halo’ around the sperm head. It takes about an hour to prepare slides prior to counting individual cells manually with bright-field microscopy, available in all fertility laboratories. Unlike all the other tests, in its most commonly used form, it measures the absence of damage rather than the damaged DNA in spermatozoa. The halo is unique with no relationship observed between it and the SCSA (

Balasuriya et al., 2011

Balasuriya A.
Speyer A.B.
Serhal P.
Doshi A.
Harper J.C.

Sperm chromatin dispersion test in the assessment of DNA fragmentation and aneuploidy in human spermatozoa.

). To date, correlations have been observed between DNA and other sperm parameters (

Gosálvez et al., 2008

Gosálvez J.
Gosálbez A.
Arroyo F.
Fernández J.L.
López-Fernández C.

Assessing sperm DNA fragmentation in the field: an adaptation of sperm chromatin dispersion technology.

,

Nasr-Esfahani et al., 2008

Nasr-Esfahani M.H.
Razavi S.
Vahdati A.A.
Fathi F.
Tavalaee M.

Evaluation of sperm selection procedure based on hyaluronic acid binding ability on ICSI outcome.

) although few correlations between sperm DNA damage and treatment outcomes have been established using this method. Some recent studies have shown no significant associations using ejaculated spermatozoa (n = 100,

Muriel et al., 2006

Muriel L.
Garrido N.
Fernández J.L.
Remohí J.
Pellicer A.
de los Santos M.J.
Meseguer M.

Value of the sperm DNA fragmentation level, measured by the sperm chromatin dispersion (SCD) test, in the IVF and ICSI outcome.

); n = 622,

Velez de la Calle et al., 2008

Velez de la Calle J.F.V.
Muller A.
Walschaerts M.
Clavere J.L.
Jimenez C.
Wittemer C.
Thonneau P.

Sperm deoxyribonucleic acid fragmentation as assessed by the sperm chormatin dispersion test in assisted reproductive technology programs: results of a large prospective multicenter study.

); n = 60,

Yilmaz et al., 2010

Yilmaz S.
Zergeroglu A.D.
Yilmaz E.
Sofuoglu K.
Delikara N.
Katlu P.

Effects of sperm DNA fragmentation on semen parameters and ICSI outcome determined by an improved SCD test, Halosperm.

Google Scholar

)) or testicular spermatozoa (

Meseguer et al., 2009

Meseguer M.
Santiso R.
Garrido N.
Gil-Salom M.
RemohÃ J.
Fernandez J.L.

Sperm DNA fragmentation levels in testicular sperm samples from azoospermic males as assessed by the sperm chromatin dispersion (SCD) test.

). However, in an interesting study by

Meseguer et al., 2008

Meseguer M.
Martínez-Conejero J.A.
O’Connor J.E.
Pellicer A.
Remohí J.
Garrido N.

The significance of sperm DNA oxidation in embryo development and reproductive outcome in an oocyte donation program: a new model to study a male infertility prognostic factor.

, sperm DNA damage as measured by the Halo assay had a negative impact on pregnancy if the oocytes were from infertile women (n = 98) but not if donor oocytes (n = 112) were used. Using the Halo test, the dynamics of DNA fragmentation have been measured with time and fragmentation has been shown to increase with time after thawing (

Gosálvez et al., 2008

Gosálvez J.
Gosálbez A.
Arroyo F.
Fernández J.L.
López-Fernández C.

Assessing sperm DNA fragmentation in the field: an adaptation of sperm chromatin dispersion technology.

). This is an important clinical finding, suggesting that immediate use of thawed spermatozoa for clinical purposes would be advisable.

The TUNEL assay

Among the different types of assays available to determine real, ‘actual’ DNA damage, the TdT (terminal deoxynucleotidyl transferase)-mediated dUDP nick-end labelling (TUNEL) assay is one of the oldest. It was developed by

Ausubel et al., 1992

Ausubel M.F.
Brent R.
Kingston R.E.
Moore D.D.
Seidman J.G.
Smith J.A.
Strahl K.

Short Protocols in Molecular Biology.

Google Scholar

and was first applied to spermatozoa by

Gorczyca et al., 1993

Gorczyca W.
Traganos F.
Jesionowska H.
Darzynkiewicz Z.

Presence of DNA strand breaks and increased sensitivity of DNA in situ to denaturation in abnormal human sperm cells: analogy to apoptosis of somatic cells.

. The principle of this widely used assay is based on the ligation of dUTP to the 3′-OH phosphate ends including blunt-ended and 5′-recessed DNA fragments at single- and double-strand DNA breaks (

Gold et al., 1994

Gold R.
Schmied M.
Giegerich G.
Breitschopf H.
Hartung H.P.
Toyka K.V.
Lassmann H.

Differentiation between cellular apoptosis and necrosis by combined use of in situ tailing and nick translation techniques.

,

Nakamura et al., 1995

Nakamura T.
Sakai T.
Hotchi M.

Histochemical demonstration of DNA double strand breaks by in situ 3′-tailing reaction in apoptotic endometrium.

), thus measures definite endpoints, which is referred to as ‘actual’ DNA damage. In contrast, the SCSA detects DNA damage induced by acidic conditions.(

Alvarez, 2005

Alvarez J.G.

The predictive value of sperm chromatin structure assay.

,

Henkel, 2007

Henkel R.

DNA-based sperm assessment.

Google Scholar

). The TUNEL and SCSA assays correlate well (

Evenson et al., 2007

Evenson D.P.
Kasperson K.
Wixon R.L.

Analysis of sperm DNA fragmentation using flow cytometry and other techniques.

), although they determine different aspects of sperm function (

Henkel et al., 2010

Henkel R.
Hoogendijk C.F.
Bouic P.J.
Kruger T.F.

TUNEL assay and SCSA determine different aspects of sperm DNA damage.

,

Mitchell et al., 2011

Mitchell L.A.
De Iuliis G.N.
Aitken R.J.

The TUNEL assay consistently underestimates DNA damage in human spermatozoa and is influenced by DNA compaction and cell vitality: development of an improved methodology.

).

Since the TUNEL assay is specific for phosphodiester-strand breaks, it is often used to determine apoptosis. However, this specificity has neither been demonstrated for spermatozoa (

Manicardi et al., 1998

Manicardi G.C.
Tombacco A.
Bizzaro D.
Bianchi U.
Bianchi P.G.
Sakkas D.

DNA strand breaks in ejaculated human spermatozoa: comparison of susceptibility to the nick translation and terminal transferase assays.

) nor can this endpoint be used because it can also be reached by other mechanisms such as necrosis. Thus, by using the TUNEL assay, one should rather refer to this DNA damage as ‘DNA fragmentation’ than ‘apoptosis’ (

Henkel et al., 2004

Henkel R.
Hajimohammad M.
Stalf T.
Hoogendijk C.
Mehnert C.
Menkveld R.
Gips H.
Schill W.-B.
Kruger T.F.

Influence of deoxyribonucleic acid damage on fertilization and pregnancy.

,

Muratori et al., 2010

Muratori M.
Tamburrino L.
Marchiani S.
Guido C.
Forti G.
Baldi E.

Critical aspects of detection of sperm DNA fragmentation by TUNEL/flow cytometry.

).

Principally, the TUNEL assay can be performed using flow cytometry or microscopically with either fluorescent or colorimetric labels. The latter, fluorometric or colorimetric, should preferably be performed in cases with very low sperm count, for example in cases of oligozoospermia or if spermatozoa are retrieved from the epididymis or testis. Although not very sensitive due to technical specifics in the original protocol (

Mitchell et al., 2011

Mitchell L.A.
De Iuliis G.N.
Aitken R.J.

The TUNEL assay consistently underestimates DNA damage in human spermatozoa and is influenced by DNA compaction and cell vitality: development of an improved methodology.

), the assay has been regarded as being precise and reproducible (

Muratori et al., 2009

Muratori M.
Tamburrino L.
Tocci V.
Costantino A.
Marchiani S.
Giachini C.
Laface I.
Krausz C.
Meriggiola M.C.
Forti G.
Baldi E.

Small variations in crucial steps of TUNEL assay coupled to flow cytometry greatly affect measures of sperm DNA fragmentation.

). A number of different factors such as preparation, fixation and permeabilization of samples negatively affect its clinical application (

Muratori et al., 2010

Muratori M.
Tamburrino L.
Marchiani S.
Guido C.
Forti G.
Baldi E.

Critical aspects of detection of sperm DNA fragmentation by TUNEL/flow cytometry.

). The latter factor is due to the highly compact nature of sperm chromatin by and its reinforced structure in protamines due to inter- and intramolecular bonds (

Balhorn et al., 1992

Balhorn R.
Corzett M.
Mazrimas J.A.

Formation of intraprotamine disulfates in vitro.

,

Brewer et al., 2003

Brewer L.
Corzett M.
Lau E.Y.
Balhorn R.

Dynamics of protamine 1 binding to single DNA molecules.

,

Vilfan et al., 2004

Vilfan I.D.
Conwell C.C.
Hud N.V.

Formation of native-like mammalian sperm cell chromatin with folded bull protamine.

), which prevent TdT from directly accessing the DNA strand breaks. All these factors contribute to the fact that the TUNEL assay has not yet been standardized to the same extent as the SCSA.

Only recently, solutions to these standardization problems have been found. For example, M540 bodies, which represent an interference in flow cytometry and contain apoptotic markers (

Marchiani et al., 2007

Marchiani S.
Tamburrino L.
Maoggi A.
Vannelli G.B.
Forti G.
Baldi E.
Muratori M.

Characterization of M540 bodies in human semen: evidence that they are apoptotic bodies.

), were excluded and a standardized fixation protocol (

Muratori et al., 2009

Muratori M.
Tamburrino L.
Tocci V.
Costantino A.
Marchiani S.
Giachini C.
Laface I.
Krausz C.
Meriggiola M.C.
Forti G.
Baldi E.

Small variations in crucial steps of TUNEL assay coupled to flow cytometry greatly affect measures of sperm DNA fragmentation.

) was introduced. Additionally, pretreating the samples with the disulphide-bridge-reducing agent dithiothreitol resulted in relaxation of the compact chromatin structure for TdT to access the DNA (

Codrington et al., 2007

Codrington A.M.
Hales B.F.
Robaire B.

Exposure of male rats to cyclophosphamide alters the chromatin structure and basic proteome in spermatozoa.

). Using this technique,

Mitchell et al., 2011

Mitchell L.A.
De Iuliis G.N.
Aitken R.J.

The TUNEL assay consistently underestimates DNA damage in human spermatozoa and is influenced by DNA compaction and cell vitality: development of an improved methodology.

significantly enhanced the sensitivity of the TUNEL assay. Apart from its general clinical value, which has been shown repeatedly (

Aitken et al., 2010

Aitken R.J.
De Iuliis G.N.
Finnie J.M.
Hedges A.
McLachlan R.I.

Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.

,

Henkel et al., 2004

Henkel R.
Hajimohammad M.
Stalf T.
Hoogendijk C.
Mehnert C.
Menkveld R.
Gips H.
Schill W.-B.
Kruger T.F.

Influence of deoxyribonucleic acid damage on fertilization and pregnancy.

,

Sharma et al., 2010

Sharma R.K.
Sabanegh E.
Mahfouz R.
Gupta S.
Thiyagarajan A.
Agarwal A.

TUNEL as a test for sperm DNA damage in the evaluation of male infertility.

), the technical standardization and proper clinical evaluation of the TUNEL assay are essential.

Sharma et al., 2010

Sharma R.K.
Sabanegh E.
Mahfouz R.
Gupta S.
Thiyagarajan A.
Agarwal A.

TUNEL as a test for sperm DNA damage in the evaluation of male infertility.

and

Aitken et al., 2010

Aitken R.J.
De Iuliis G.N.
Finnie J.M.
Hedges A.
McLachlan R.I.

Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.

evaluated the flow cytometric TUNEL assay for clinical use and established reference ranges for DNA damage in patients and fertile donors. Nevertheless, despite the advantages of the TUNEL assay and the efforts in its standardization, more work remains to be done in order to eventually establish a robust, clinical test system to determine male infertility.

The value of sperm DNA adduct analysis

Biological and environmental factors which are known to elevate DNA adduct formation in spermatozoa have been shown to produce marked effects on embryonic development and the health of the offspring (

Adler, 2000

Adler I.D.

Spermatogenesis and mutagenicity of environmental hazards: extrapolation of genetic risk from mouse to man.

,

Anderson, 2001

Anderson D.

Genetic and reproductive toxicity of butadiene and isoprene.

). Further studies have clearly indicated that DNA adduct formation in human spermatozoa has direct, negative impacts on fertility and is a good predictor of treatment outcome (

Tyla et al., 2000

Tyla R.W.
Friedman M.A.
Losco P.E.
Fisher L.C.
Johnson K.A.
Strother D.E.
Wolf C.H.

Rat two-generation reproduction and dominant lethal study of acrylamide in drinking water.

). The current understanding of the molecular nature of the DNA damage is limited to mainly a handful of aryl/alkyl adducts (

Witt and Bishop, 1996

Witt K.L.
Bishop J.B.

Mutagenicity of anticancer drugs in mammalian germ cells.

) and oxidative DNA modifications (

De Iuliis et al., 2009

De Iuliis G.N.
Thomson L.K.
Mitchell L.A.
Finnie J.M.
Koppers A.J.
Hedges A.
Nixon B.
Aitken R.J.

DNA damage in human spermatozoa is highly correlated with the efficiency of chromatin remodelling and the formation of 8-hydroxy-2′-deoxyguanosine, a marker of oxidative stress.

). Nevertheless, this knowledge is aiding efforts to understand the underlying aetiology of sperm DNA damage.

DNA fragmentation can arise through two independent mechanisms: direct enzymic cleavage and oxidative breakage of the backbone. In addition to these canonical mechanisms, DNA cleavage will also occur as a result of DNA adduct formation. Upon the creation of a base adduct, the glycosyl bond linking the base to the sugar moiety is weakened, leading to a basic site formation (

Lee et al., 2009

Lee K.M.
Ward M.H.
Han S.
Ahn H.S.
Kang H.J.
Choi H.S.
Shin H.Y.
Koo H.H.
Seo J.J.
Choi J.E.
Ahn Y.
Kang D.

Paternal smoking, genetic polymorphisms in CYP1A1 and childhood leukemia risk.

). These now-vulnerable sections of DNA are favoured to produce strand breaks, either spontaneously via ribose ring opening reactions (

Liu et al., 2006

Liu Y.
Guo H.C.
Wang L.J.
Dai Y.L.
Zhang X.M.
Li Z.H.
He B.

Dynamic phosphorus budget for lake-watershed ecosystems.

,

Zini et al., 2008

Zini A.
Boman J.M.
Belzile E.
Ciampi A.

Sperm DNA damage is associated with an increased risk of pregnancy loss after IVF and ICSI: systematic review and meta-analysis.

) or by targeted enzymic cleavage by nucleases (topoisomerase II;

Cavalieri and Rogan, 2010

Cavalieri E.L.
Rogan E.G.

Depurinating estrogen–DNA adducts in the etiology and prevention of breast and other human cancers.

). DNA fragmentation assays measure strand breaks as an end point. While this provides data on the level of breakage, these tests can provide little-to-no insights into the origins of the damage. Thus, chemical characterization of the DNA adducts present in human spermatozoa will provide clues to the aetiology of this DNA damage that will supplement the data generated by DNA fragmentation assays.

The use of mass spectrometry to detect and characterize DNA adducts is well established in cancer research (

Badouard et al., 2008

Badouard C.
Menezo Y.
Panteix G.
Ravanat J.L.
Douki T.
Cadet J.
Favier A.

Determination of new types of DNA lesions in human sperm.

,

Stone et al., 2011

Stone M.P.
Huang H.
Brown K.L.
Shanmugam G.

Chemistry and structural biology of DNA damage and biological consequences.

) and is beginning to permeate into gamete biology (

Witt and Bishop, 1996

Witt K.L.
Bishop J.B.

Mutagenicity of anticancer drugs in mammalian germ cells.

,

Verhofstad et al., 2011

Verhofstad N.
van Oostrom C.T.
Zwart E.
Mass L.M.
van Benthem J.
van Schooten F.J.
van Steeg H.
Godschalk R.W.

Evaluation of benzo(a)pyrene-induced gene mutations in male germ cells.

). The measurement of sperm DNA modifications such as 8-hydroxy-2-deoxyguanosine (

Lee et al., 2009

Lee K.M.
Ward M.H.
Han S.
Ahn H.S.
Kang H.J.
Choi H.S.
Shin H.Y.
Koo H.H.
Seo J.J.
Choi J.E.
Ahn Y.
Kang D.

Paternal smoking, genetic polymorphisms in CYP1A1 and childhood leukemia risk.

,

Gharagozloo and Aitken, 2011

Gharagozloo P.
Aitken R.J.

The role of sperm oxidative stress in male infertility and the significance of oral antioxidant therapy.

,

Thomson et al., 2011

Thomson L.K.
Zieschang J.A.
Clark A.M.

Oxidative deoxyribonucleic acid damage in sperm has a negative impact on clinical pregnancy rate in intrauterine insemination but not intracytoplasmic sperm injection cycles.

,

Cambi et al., 2013

Cambi M.
Tamburrino L.
Marchiani S.
Olivito B.
Azzari C.
Forti G.
Baldi E.
Muratori M.

Development of a specific method to evaluate 8-hydroxy,2-deoxyguanosine in sperm nuclei: relationship with semen quality in a cohort of 94 subjects.

) and xenobiotic adduct formation (

Zenzes, 2000

Zenzes M.T.

Smoking and reproduction: gene damage to human gametes and embryos.

) including benzo[a]pyrene (

Park et al., 2008

Park J.H.
Gelhaus S.
Vedantam S.
Oliva A.L.
Batra A.
Blair I.A.
Troxel A.B.
Field J.
Penning T.M.

The pattern of p53 mutations caused by PAH o-quinones is driven by 8-oxo-dGuo formation while the spectrum of mutations is determined by biological selection for dominance.

), has been gaining much momentum of late, especially employing antibody-based analyses. In fact, these two lesions have been recently implicated as playing a major role in male infertility and the health of the offspring (

Anderson, 2001

Anderson D.

Genetic and reproductive toxicity of butadiene and isoprene.

,

Bidmon et al., 2007

Bidmon C.
Frischmann M.
Pischetsrieder M.

Analysis of DNA-bound advanced glycation end-products by LC and mass spectrometry.

,

Lee et al., 2009

Lee K.M.
Ward M.H.
Han S.
Ahn H.S.
Kang H.J.
Choi H.S.
Shin H.Y.
Koo H.H.
Seo J.J.
Choi J.E.
Ahn Y.
Kang D.

Paternal smoking, genetic polymorphisms in CYP1A1 and childhood leukemia risk.

). While the identification of specific xenobiotic-adducts may point toward a specific cause, the identification of oxidative stress markers can be common to several aetiologies given that oxidative stress is a major mediator of DNA damage in the male germ line (

De Iuliis et al., 2009

De Iuliis G.N.
Thomson L.K.
Mitchell L.A.
Finnie J.M.
Koppers A.J.
Hedges A.
Nixon B.
Aitken R.J.

DNA damage in human spermatozoa is highly correlated with the efficiency of chromatin remodelling and the formation of 8-hydroxy-2′-deoxyguanosine, a marker of oxidative stress.

). Furthermore, the presence of these markers together with the detection of others, such as advanced glycation end products, may confirm specific pathologies such as diabetes (

Agbaje et al., 2008

Agbaje I.M.
McVicar C.M.
Schock B.C.
McClure N.
Atkinson A.B.
Rogers D.
Lewis S.E.M.

Increased levels of the Oxidative DNA adduct 7,8-dihydro-8-oxo-2′-deoxoguanosine in the germ-line of men with type-1 diabetes.

). Based on the oxidative stress data, a pertinent body of work is being generated supporting the potential therapeutic effects of antioxidant supplements (

Gharagozloo and Aitken, 2011

Gharagozloo P.
Aitken R.J.

The role of sperm oxidative stress in male infertility and the significance of oral antioxidant therapy.

,

Henkel, 2012

Henkel R.

Sperm preparation: state-of-the-art – physiological aspects and application of advanced sperm preparation methods.

).

It is clear that this fundamental comprehension of the origins of DNA damage in the male germ line is not only critical from a basic sperm cell biology perspective but is invaluable as a diagnostic for male infertility, as it can give information on the potential underlying causes in each case. Therefore, having now established a fundamental platform of information on sperm DNA strand breaks, the next step in gaining a detailed understanding of DNA damage to characterize the DNA adducts that created these breaks in the male gamete.

Proxy tests for sperm DNA damage

The major limitation of testing for sperm DNA damage is that each assay renders the tested spermatozoa unsuitable for clinical purpose. In an effort to overcome this problem, a number of non-invasive tests have been developed and their correlation with DNA damage assessed. These novel tests include birefringence, intracytoplasmic morphologically selected sperm injection (IMSI) and hyaluronic acid-selection of spermatozoa for ICSI. If these tests can help embryologists choose spermatozoa with low DNA damage for use in assisted reproduction, a major step forward in sperm selection will be achieved, but presently tenuous relationships are based on a few studies with very small numbers of cases.

The implications of sperm DNA damage in the diagnosis of male infertility, treatment choice and the health of future generations

Fecundity in the general population

There is a consensus based on numerous publications that men in infertile couples have a higher level of sperm DNA fragmentation compared with those in the general population and proven fertile males. Such findings are interesting from a biological point of view since they point to a new, and potentially curable, cause of male infertility. Two independent population-based studies, one from the USA (

Evenson et al., 1999

Evenson D.P.
Jost L.K.
Marshall D.
Zinaman M.J.
Clegg E.
Purvis K.
de Angelis P.
Claussen O.P.

Utility of the sperm chromatin structure assay as a diagnostic and prognostic tool in the human fertility clinic.

) and one from Denmark (

Yilmaz et al., 2010

Yilmaz S.
Zergeroglu A.D.
Yilmaz E.
Sofuoglu K.
Delikara N.
Katlu P.

Effects of sperm DNA fragmentation on semen parameters and ICSI outcome determined by an improved SCD test, Halosperm.

Google Scholar

), have shown that sperm DNA damage (as measured by DFI using SCSA) is a useful marker in the prediction of fertility in males from couples of unknown fertility. Thus, both studies have shown that the chance of spontaneous conception starts to decline at sperm DNA damage values above 20% and approaches zero for readings over 30–40%. This means that, although low sperm DNA damage (<20%) does not guarantee normal male fertility, high levels of damage are indicative of severely impaired male fertility. Furthermore, the SCSA data indicate that, for men who classified as ‘normal’ because their conventional sperm parameters are in the normal range, the risk of infertility starts to increase at DFI above 20% (odds ratio, OR, 5.1, 95% CI 1.2–23). However, this threshold drops to ∼10% if the sperm concentration is below 20 × 10⁶/ml and/or there is an impairment of sperm motility or morphology (OR 16, 95% CI 4.2–60;

Giwercman et al., 2010

Giwercman A.
Lindstedt L.
Larsson M.
Bungum M.
Spano M.
Levine R.J.
Rylander L.

Sperm chromatin structure assay as an independent predictor of fertility in vivo: a case–control study.

). In another study (

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

), using the Comet assay, there was also a strong correlation between sperm DNA fragmentation and fertility status of men, with 95% of fertile donors having DNA fragmentation below 25% and 98% of infertile men having DNA fragmentation above 25%. The prognostic value of sperm DNA fragmentation in relation to infertility showed an OR for infertility of 120 (95% CI 13–2700) in men with DNA damage above 25% (

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

). Thirdly, a comparison between male infertility patients and sperm donors using a flow cytometric TUNEL assay gave 19.25% as the cut-off value, with no donors but 65% patients having DNA damage above this level (

Sharma et al., 2010

Sharma R.K.
Sabanegh E.
Mahfouz R.
Gupta S.
Thiyagarajan A.
Agarwal A.

TUNEL as a test for sperm DNA damage in the evaluation of male infertility.

). Thus, there is robust evidence from all the DNA fragmentation tests that the chance of spontaneous pregnancy is reduced when DNA damage is excessive.

Treatment choice

Success rates for IUI are similar to those for spontaneous pregnancies, indicating a reduction in the chance of pregnancy with sperm DNA damage above 20% according to the SCSA (

Bungum et al., 2007

Bungum M.
Humaidan P.
Axmon A.
Spano M.
Bungum L.
Erenpreiss J.
Giwercman A.

Sperm DNA integrity assessment in prediction of assisted reproduction technology outcome.

). If a test for oxidized bases is employed (8-hydroxy-2′-deoxyguanosine) the results are even more sensitive, with a lower threshold value of 11.5% (

Thomson et al., 2011

Thomson L.K.
Zieschang J.A.
Clark A.M.

Oxidative deoxyribonucleic acid damage in sperm has a negative impact on clinical pregnancy rate in intrauterine insemination but not intracytoplasmic sperm injection cycles.

).

In terms of IVF, a recent meta-analysis of nine IVF and 11 ICSI studies by

Zini and Sigman, 2009

Zini A.
Sigman M.

Are tests of sperm DNA damage clinically useful? pros and cons.

showed a modestly increased pregnancy chance after IVF (OR 1.7, 95% CI 1.3–2.2) in cases when the proportion of DNA-damaged spermatozoa was below the threshold values for SCSA or TUNEL. As a result of these data, sperm DNA testing is now employed routinely throughout south Sweden. In further support, studies using the Comet assay (

Simon et al., 2010

Simon L.
Lutton D.
McManus J.
Sheena E.
Lewis M.

Clinical significance of sperm DNA damage in reproductive outcome.

,

Simon et al., 2013

Simon L.
Proutski I.
Stevenson M.
Jennings D.
McManus J.
Lutton D.
Lewis S.E.M.

Sperm DNA damage has negative association with live birth rates after IVF.

; both published after

Zini and Sigman, 2009

Zini A.
Sigman M.

Are tests of sperm DNA damage clinically useful? pros and cons.

meta-analysis) showed an OR of 76 (95% CI 8.7–1700) for clinical pregnancy if the mean DNA fragmentation per spermatozoon was below 52% (

Simon et al., 2011

Simon L.
Lutton D.
McManus J.
Lewis S.E.

Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.

). The latest study using the Comet assay showed that couples with low levels of sperm DNA fragmentation (<25%) had a live birth rate of 33% following IVF treatment. In contrast, couples with high levels of sperm DNA fragmentation (>50%) had a much lower live birth rate of 13% following IVF treatment. of couples with idiopathic infertility, 39% have high sperm DNA damage. Sperm DNA damage was also associated with lower live birth rates following IVF in couples with idiopathic infertility than couples with detectable causes.

Sperm DNA damage has not been found to be predictive for ICSI treatment (

Zini, 2011

Zini A.

Are sperm chromatin and DNA defects relevant in the clinic?.

) except for one exception (

Bungum et al., 2007

Bungum M.
Humaidan P.
Axmon A.
Spano M.
Bungum L.
Erenpreiss J.
Giwercman A.

Sperm DNA integrity assessment in prediction of assisted reproduction technology outcome.

). However, in this study, couples were not randomized for IVF or ICSI so the impact of other factors contributing to the choice of treatment cannot be excluded. A number of reasons have been put forward to explain the finding that poor sperm DNA does not appear to impact adversely on ICSI outcomes. Firstly, unlike IVF, up to 30% of women (with subfertile partners) having ICSI have no detectable problems. They may be fertile and their oocytes may have more capacity to repair DNA damage even if the injected spermatozoon is of poor quality. This is supported by the findings of

Meseguer et al., 2011

Meseguer M.
Stantiso R.
Garrido N.
Garcia-Herrero S.
Remohi J.
Fernandez J.L.

Effect of sperm DNA fragmentation on pregnancy outcome depends on oocyte quality.

where high-quality oocytes from donors offset the negative impact of sperm DNA damage on pregnancy.

Secondly, a recent major study from

Dumoulin et al., 2010

Dumoulin J.C.
Land J.A.
Van Montfoort A.P.
Nelissen E.C.
Coonen E.
Derhaag J.G.
Schreurs I.L.
Dunselman G.A.
Kester A.D.
Geraedts J.P.
Evers J.L.

Effect of in vitro culture of human embryos on birthweight of newborns.

shows that even the birthweight of IVF babies can be markedly influenced by minor differences in culture conditions. In contrast to IVF, ICSI spermatozoa are injected into the optimal environment of the ooplasm within a few hours of ejaculation. This may protect them from laboratory-induced damage.

Thirdly, it is well documented that spermatozoa from up to 40% of infertile men have high levels of ROS (

Aitken et al., 2012

Aitken R.J.
Jones K.T.
Robertson S.A.

Reactive oxygen species and sperm function – in sickness and in health.

,

Henkel, 2011

Henkel R.

Leukocytes and oxidative stress: dilemma for sperm function and male fertility.

) and their antioxidant content is also significantly lower than fertile men (

Lewis et al., 1995

Lewis S.E.M.
Boyle P.M.
McKinney K.
Young I.S.
Thompson W.

Total antioxidant capacity of seminal plasma is different in fertile and infertile men.

). During the IVF process, oocytes can be exposed to an overnight oxidative assault from 0.5 million spermatozoa releasing ROS. This may well impair the oocyte’s functional ability, including its capacity to repair sperm DNA fragmentation post fertilization.

Finally, as mentioned above, evidence is emerging that embryos with high sperm DNA damage are associated with early pregnancy loss (reviewed by

Zini et al., 2008

Zini A.
Boman J.M.
Belzile E.
Ciampi A.

Sperm DNA damage is associated with an increased risk of pregnancy loss after IVF and ICSI: systematic review and meta-analysis.

; using 11 studies composed of 808 IVF and 741 ICSI cycles) so ICSI success rates are sometimes affected adversely by sperm DNA damage but at a later stage. In fact, high levels of sperm DNA damage are associated with increased risk of pregnancy loss (OR 2.5, 95% CI 1.5–4.0), regardless of the in-vitro technique applied (reviewed by

Robinson et al., 2012

Robinson L.
Gallos I.D.
Conner S.J.
Rajkhowa M.
Miller D.
Lewis S.E.M.
Kirkman-Brown J.
Coomarasamy A.

The effect of sperm DNA fragmentation on miscarriage rates: a systematic review and meta-analysis.

).

Early pregnancy loss, whether following spontaneous or assisted conception is another form of infertility, and one for which we need to develop an appropriate patient pathway.

Implications for future generations’ health

Importantly, compounds that induce oxidative stress in the male germ line such as iron dextran have also been shown to generate positive results in dominant lethal assays (

Doreswamy and Muralidhara, 2005

Doreswamy K.
Muralidhara R.

Genotoxic consequences associated with oxidative damage in testis of mice subjected to iron intoxication.

). The importance of oxidative stress in the aetiology of the dominant lethal effect is also emphasized by the fact that polyphenolic antioxidants can reverse the dominant lethal impact of benzo[a]pyrene (

Shukla and Taneja, 2001

Shukla Y.
Taneja P.

Antimutagenic effect of black tea extract using ‘rodent dominant lethal mutation assay’.

). Similarly, enhancing the concentration of reduced glutathione in the male reproductive tract following treatment with N-acetylcysteine was found to reduce the dominant lethal effects observed with ethyl methanesulphonate, while glutathione depletion with phorone had the opposite effect (

Gandy et al., 1992

Gandy J.
Bates H.K.
Conder L.A.
Harbison R.D.

Effects of reproductive tract glutathione enhancement and depletion on ethyl methanesulfonate-induced dominant lethal mutations in Sprague–Dawley rats.

). The literature on male-mediated toxicity in animals, and the dominant lethal assay in particular, is extensive and demonstrates beyond doubt that the induction of DNA damage in the male germ line can induce miscarriage or, if the pregnancy carries to term, morbidity in the offspring, including an enhanced susceptibility to tumour formation.

To set this fundamental point beyond doubt,

Fernández-Gonzalez et al., 2008

Fernández-Gonzalez R.
Moreira P.N.
Pérez-Crespo M.
Sánchez-Martín M.
Ramirez M.A.
Pericuesta E.
Bilbao A.
Bermejo-Alvarez P.
de Dios Hourcade J.
de Fonseca F.R.
Gutiérrez-Adán A.

Long-term effects of mouse intracytoplasmic sperm injection with DNA-fragmented sperm on health and behavior of adult offspring.

performed ICSI with mouse spermatozoa that had their DNA damaged by a freeze–thaw cycle in the absence of cryoprotectant. Fertilization with such damaged spermatozoa allowed embryonic development to proceed to term but at a reduced rate compared with control animals. Furthermore, the offspring that were generated in this study following ICSI showed reduced longevity, increased behavioural abnormalities and a significant rise in the incidence of pathologies, including the age-dependent appearance of solid tumours (

Fernández-Gonzalez et al., 2008

Fernández-Gonzalez R.
Moreira P.N.
Pérez-Crespo M.
Sánchez-Martín M.
Ramirez M.A.
Pericuesta E.
Bilbao A.
Bermejo-Alvarez P.
de Dios Hourcade J.
de Fonseca F.R.
Gutiérrez-Adán A.

Long-term effects of mouse intracytoplasmic sperm injection with DNA-fragmented sperm on health and behavior of adult offspring.

).

These animal studies provide experimental support for the correlative associations that have been observed clinically between DNA damage in human spermatozoa and morbidity in children. One paradigm that perfectly illustrates the power of these associations is paternal ageing. Thus, numerous studies demonstrate that paternal age is associated with a high incidence of DNA damage in human spermatozoa (

Schmid et al., 2007

Schmid T.E.
Eskenazi B.
Baumgartner A.
Marchetti F.
Young S.
Weldon R.
Anderson D.
Wyrobek A.J.

The effects of male age on sperm DNA damage in healthy non-smokers.

,

Singh et al., 2003

Singh N.P.
Muller C.H.
Berger R.E.

Effects of age on DNA double-strand breaks and apoptosis in human sperm.

,

Varshini et al., 2012

Varshini J.
Srinag B.S.
Kalthur G.
Krishnamurthy H.
Kumar P.
Rao S.B.
Adiga S.K.

Poor sperm quality and advancing age are associated with increased sperm DNA damage in infertile men.

) as well as an increase in the mutational load subsequently carried by the offspring (

Kong et al., 2012

Kong A.
Frigge M.L.
Masson G.
Besenbacher S.
Sulem P.
Magnusson G.
Gudjonsson S.A.
Sigurdsson A.
Jonasdottir A.
Jonasdottir A.
Wong W.S.
Sigurdsson G.
Walters G.B.
Steinberg S.
Helgason H.
Thorleifsson G.
Gudbjartsson D.F.
Helgason A.
Magnusson O.T.
Thorsteinsdottir U.
Stefansson K.

Rate of de novo mutations and the importance of father’s age to disease risk.

). Whether there is a mechanistic link between DNA damage in the germ line on the one hand and increased mutation rates in the embryo on the other is a critical issue that remains unresolved. It is possible that advanced paternal age is associated with an increased mutation rate in the spermatogonial stem cell population as a consequence of replication errors that are completely independent of any DNA damage seen in the spermatozoa. Alternatively, the DNA damage recorded in the spermatozoa of older men may be directly responsible for the age-dependent increase in mutational load seen in the embryo, as a result of aberrant DNA repair in the oocyte prior to the initiation of S-phase of the first mitotic division (

Aitken et al., 2004

Aitken R.J.
Koopman P.
Lewis S.E.

Seeds of concern.

). Whatever the nature the genetic damage present in the spermatozoon as a consequence of paternal age its appearance is correlated with an increase in neurological conditions in the offspring such as epilepsy, spontaneous schizophrenia, autism and bipolar disease (

Sipos et al., 2004

Sipos A.
Rasmussen F.
Harrison G.
Tynelius P.
Lewis G.
Leon D.A.
Gunnell D.

Paternal age and schizophrenia: a population based cohort study.

,

Reichenberg et al., 2006

Reichenberg A.
Gross R.
Weiser M.
Bresnahan M.
Silverman J.
Harlap S.
Rabinowitz J.
Shulman C.
Malaspina D.
Lubin G.
Knobler H.Y.
Davidson M.
Susser E.

Advancing paternal age and autism.

,

Aitken and De Iuliis, 2007

Aitken R.J.
De Iuliis G.N.

Origins and consequences of DNA damage in male germ cells.

,

Frans et al., 2008

Frans E.M.
Sandin S.
Reichenberg A.
Lichtenstein P.
Långström N.
Hultman C.M.

Advancing paternal age and bipolar disorder.

). DNA lesions in the spermatozoa of ageing fathers are also associated with an increased risk of cancer in the offspring (

Hemminki et al., 1999

Hemminki K.
Kyyrönen P.
Vaittinen P.

Parental age as a risk factor of childhood leukemia and brain cancer in offspring.

,

Johnson et al., 2011

Johnson K.J.
Carozza S.E.
Chow E.J.
Fox E.E.
Horel S.
McLaughlin C.C.
Mueller B.A.
Puumala S.E.
Reynolds P.
Von Behren J.
Spector L.G.

Birth characteristics and childhood carcinomas.

), birth defects (

Green et al., 2010

Green R.F.
Devine O.
Crider K.S.
Olney R.S.
Archer N.
Olshan A.F.
Shapira S.K.

National Birth Defects Prevention Study
Association of paternal age and risk for major congenital anomalies from the National Birth Defects Prevention Study, 1997 to 2004.

) and the appearance of dominant genetic mutations including achondroplasia and Apert’s syndrome (

Crow, 2000

Crow J.F.

The origins, patterns and implications of human spontaneous mutation.

).

A second paradigm that shows the same relationship between DNA damage in the spermatozoa and a significantly increased risk of morbidity in the offspring is smoking. Paternal smoking creates oxidative stress in the ejaculate and significantly enhanced levels of oxidative DNA damage in the spermatozoa (

Fraga et al., 1996

Fraga C.G.
Motchnik P.A.
Wyrobek A.J.
Rempel D.M.
Ames B.N.

Smoking and low antioxidant levels increase oxidative damage to DNA.

). A number of independent studies have indicated that this genetic damage to the spermatozoa is, in turn, associated with significantly increased levels of cancer in the offspring (

Ji et al., 1997

Ji B.T.
Shu X.O.
Linet M.S.
Zheng W.
Wacholder S.
Gao Y.T.
Ying D.M.
Jin F.

Paternal cigarette smoking and the risk of childhood cancer among offspring of nonsmoking mothers.

,

Lee et al., 2009

Lee K.M.
Ward M.H.
Han S.
Ahn H.S.
Kang H.J.
Choi H.S.
Shin H.Y.
Koo H.H.
Seo J.J.
Choi J.E.
Ahn Y.
Kang D.

Paternal smoking, genetic polymorphisms in CYP1A1 and childhood leukemia risk.

).

A third situation in which DNA damage in the spermatozoa is associated with defects in the offspring is assisted reproduction treatment. The detrimental effect of assisted conception on the health and wellbeing of the progeny has been conclusively demonstrated in a recent meta-analysis (

Wen et al., 2012

Wen J.
Jiang J.
Ding C.
Dai J.
Liu Y.
Xia Y.
Liu J.
Hu Z.

Birth defects in children conceived by in vitro fertilization and intracytoplasmic sperm injection: a meta-analysis.

). In this review of the existing literature, no difference was found between the risks associated with IVF and ICSI; however, a recent analysis of pregnancies in South Australia revealed a significantly enhanced chance of birth defects in ICSI compared with IVF children (

Davies et al., 2012

Davies M.J.
Moore V.M.
Willson K.J.
Van Essen P.
Priest K.
Scott H.
Haan E.A.
Chan A.

Reproductive technologies and the risk of birth defects.

). Interestingly, this difference was not observed with cryostored embryos, suggesting that the stresses associated with embryo freezing might selectively eliminate any defective embryos generated as a result of the ICSI procedure. In light of these results, routine cryostorage of ICSI embryos might be considered in cases where DNA damage in the father’s spermatozoa is high and a potential risk to the normality of embryonic development is therefore evident.

Finally, because the three factors known to be associated with DNA damage in human spermatozoa (ageing, smoking and infertility) are also associated with the formation of oxidative DNA adducts in the germ line, these data suggest that oxidative stress is a critical trigger for paternally mediated impacts on development. The implications of this rationale are 2-fold. Firstly, if this is the case, then any factor capable of causing oxidative stress in the male reproductive tract is capable of influencing the health and wellbeing of the next generation. The list of such factors is very extensive and, in addition to age and smoking, includes alcohol consumption, exposure to radio-frequency electromagnetic radiation, chemotherapy, diabetes, heat, testicular torsion, oestrogenic steroids, anti-retroviral drugs, anti-epileptics, phthalate esters, heavy metals, acrylamide, arsenic, pesticides, herbicides, paracetamol, hypobaric hypoxia, cryostorage and indeed idiopathic infertility, among others (

Mathur and D’Cruz, 2011

Mathur P.P.
D’Cruz S.C.

The effect of environmental contaminants on testicular function.

). Given the extensive nature of this list, it is not surprising that oxidative DNA damage in human spermatozoa is such a widespread phenomenon (

Aitken et al., 2010

Aitken R.J.
De Iuliis G.N.
Finnie J.M.
Hedges A.
McLachlan R.I.

Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.

,

Aitken et al., 2012

Aitken R.J.
Jones K.T.
Robertson S.A.

Reactive oxygen species and sperm function – in sickness and in health.

). The implications of such damage in terms of the incidence of disease in the offspring is therefore potentially immense. Secondly, if oxidative stress is involved in the aetiology of DNA damage then antioxidants should be part of the cure (

Greco et al., 2005

Greco E.
Iacobelli M.
Rienzi L.
Ubaldi F.
Ferrero S.
Tesarik J.

Reduction of the incidence of sperm DNA fragmentation by oral antioxidant treatment.

).

The potential of antioxidant therapy

Excess ROS chemically modify cellular components such as proteins, lipids, RNA and DNA molecules, thus impairing normal cell function. This is true for all cell types. Sperm cells are particularly vulnerable to oxidative attack for three reasons: (i) their plasma membrane is largely composed of polyunsaturated fatty acids such as docosahexaenoic acid, which, with six double bonds per molecule, creates an ‘electron sink’ rendering it highly susceptible to oxidation and other chemical modifications (

Jones et al., 1978

Jones R.
Mann T.
Sherins R.J.

Adverse effects of peroxidized lipid on human spermatozoa.

,

Jones et al., 1979

Jones R.
Mann T.
Sherins R.J.

Peroxidative breakdown of phospholipids in human spermatozoa: spermicidal effects of fatty acid peroxides and protective action of seminal plasma.

); (ii) spermatozoa have inherent deficiencies in intracellular antioxidant enzyme protection; and (iii) unlike most cell types, spermatozoa have a limited capacity for DNA damage detection and repair. Chronic oxidative stress in the male reproductive tract is therefore potentially detrimental to sperm health compromising motility, membrane fusion events with the oocyte and, most critically, the integrity of the DNA they transport. Nonetheless, depending on factors such as the nature, extent and location of the DNA damage, spermatozoa with such lesions can still fertilize oocytes and generate pregnancies. Such pregnancies will carry an elevated risk of miscarriage and may lead to embryonic DNA mutations with deleterious consequences for the health of the offspring. It is therefore prudent to include tests that measure sperm DNA damage as part of the patients’ routine semen analysis. Patients diagnosed with moderate-to-severe oxidative DNA damage will be guided towards a more informed decision regarding the most appropriate treatment. For example, patients may be advised to skip IUI treatments altogether in favour of IVF or ICSI since IUI success rates are very poor for patients with sperm DNA damage. Moreover, the physician may recommend the use of testicular spermatozoa or high-magnification ICSI as alternative procedures. In all cases, patients with oxidative DNA damage should be encouraged to consider a simple course of antioxidants as a first-line therapy prior to undertaking any form of assisted reproduction treatment. The use of antioxidants in ameliorating sperm oxidative stress has been the subject of some 20 clinical trials over the last decade, summarized in a recent review paper (

Gharagozloo and Aitken, 2011

Gharagozloo P.
Aitken R.J.

The role of sperm oxidative stress in male infertility and the significance of oral antioxidant therapy.

). Although, most of these trials have serious shortcomings, the results unanimously and consistently show a reduction of sperm oxidative stress with a diverse array of antioxidants. In some cases, the reported improvement is accompanied by correlations with one or more secondary clinical outcomes such as pregnancy. These studies do not delineate which antioxidant or combination of antioxidants offers the best protection against oxidative stress and there is no clear consensus regarding the doses of the antioxidants that should be administered. Future research and clinical studies should address these issues as a matter of urgency. For now, based on current studies and theoretical considerations, we offer the following opinion. Since oxidative stress is not a localized phenomenon in cells or in tissues and is caused by vastly different oxidants, it is reasonable to assume that a combination of antioxidants targeting the male reproductive tract with the appropriate oral bioavailability will tender a better protection than any single antioxidant. It should also be noted that the complexities involved in the identification of such a formulation is never a trivial one as there are no ‘hard and fast’ rules in developing such a formula. While awaiting the development of efficacious formulations backed up by quality human clinical data, physicians should consider the use of one or more antioxidant(s) reported in recent review papers (

Zini et al., 2009

Zini A.
San Gabriel M.
Baazeem A.

Antioxidants and sperm DNA damage: a clinical perspective.

,

Lanzafame et al., 2009

Lanzafame F.M.
La Vignera S.
Vicari E.
Calogero A.E.

Oxidative stress and medical antioxidant treatment in male infertility.

,

Ross et al., 2010

Ross C.
Morriss A.
Khairy M.
Khalaf Y.
Braude P.
Coomarasamy A.
El-Toukhy T.

A systematic review of the effect of oral antioxidants on male infertility.

,

Gharagozloo and Aitken, 2011

Gharagozloo P.
Aitken R.J.

The role of sperm oxidative stress in male infertility and the significance of oral antioxidant therapy.

,

Showell et al., 2011

Showell M.G.
Brown J.
Yazdani A.
Stankiewicz M.T.
Hart R.J.

Antioxidants for male subfertility.

). Fortunately, there is little or no concern over the safety of these natural antioxidants with the following caveats. High doses and long durations of administration as well as the use of synthetic or chemically modified versions of antioxidants should be avoided. For example, the long-term use of synthetic esterified racemic vitamin E at 400 IU/d in the large cancer prevention SELECT clinical trials shows a significant rise in prostate cancer among healthy men (

Klein et al., 2011

Klein E.A.
Thompson Jr., I.M.
Tangen C.M.
Crowley J.J.
Lucia M.S.
Goodman P.J.
Minasian L.M.
Ford L.G.
Parnes H.L.
Gaziano J.M.
Karp D.D.
Lieber M.M.
Walther P.J.
Klotz L.
Parsons J.K.
Chin J.L.
Darke A.K.
Lippman S.M.
Goodman G.E.
Meyskens Jr., F.L.
Baker L.H.

Vitamin E and the risk of prostate cancer: the Selenium and Vitamin E Cancer Prevention Trial (SELECT).

). Additionally, antioxidants with no known benefit to reproductive health should not be considered. Physicians or IVF specialists should also avoid the use of arbitrary antioxidant formulations where little evidence concerning their safety and efficacy is reported. Some formulations may combine a large number of antioxidants with aggressive doses, raising the possibility of ‘reductive stress’ (

O’Flaherty et al., 2005

O’Flaherty C.
de Lamirande E.
Gagnon C.

Reactive oxygen species and protein kinases modulate the level of phospho-MEK-like proteins during human sperm capacitation.

) by potentially depleting the physiological concentration s of ROS known to be critical for normal sperm function. It is also important to note that, according to recently published data, 40% of men seeking fertility treatment are fertile and devoid of sperm oxidative DNA damage (

Cohen-Bacrie et al., 2009

Cohen-Bacrie P.
Belloc S.
Ménézo Y.J.
Clement P.
Hamidi J.
Benkhalifa M.

Correlation between DNA damage and sperm parameters: a prospective study of 1633 patients.

). These men do not require antioxidant treatment, which may in fact lower their fertility potential. For example, administering selenium to fertile men is known to reduce the number of motile spermatozoa possibly through modifying thyroid hormone metabolism (

Hawkes and Turek, 2001

Hawkes W.C.
Turek P.J.

Effects of dietary selenium on sperm motility in healthy men.

). Similarly, in high doses, vitamin C is reported to reduce the interchain disulphide bridges in protamines opening the cysteine net and subsequently promoting DNA decondensation in spermatozoa (

Donnelly et al., 1999

Donnelly E.T.
McClure N.
Lewis S.E.

The effect of ascorbate and alpha-tocopherol supplementation in vitro on DNA integrity and hydrogen peroxide-induced DNA damage in human spermatozoa.

,

Ménézo et al., 2007

Ménézo Y.J.
Hazout A.
Panteix G.
Robert F.
Rollet J.
Cohen-Bacrie P.
Chapuis F.
Clément P.
Benkhalifa M.

Antioxidants to reduce sperm DNA fragmentation: an unexpected adverse effect.

,

Giustarini et al., 2008

Giustarini D.
Dalle-Donne I.
Colombo R.
Milzani A.
Rossi R.

Is ascorbate able to reduce disulfide bridges? A cautionary note.

).

Thus, based on such overwhelming considerations and as a matter of ‘best practice’, the current status quo governing male fertility treatment should change to include tests of sperm DNA quality as part of the routine semen analysis. To enhance fertility potential, lower the risk of miscarriage and reduce sporadic embryonic DNA mutations, patients tested positive for sperm DNA damage should be treated with one or more antioxidants for the duration of spermatogenesis. This approach will lead to improvement of patients’ sperm DNA quality prior to undertaking any form of fertility treatment by assisted reproduction treatment.

Conclusion

The large body of literature informs those working in human fertility of the importance of assessing DNA damage in human spermatozoa, in terms of effectiveness of treatment and the health of offspring conceived using this technology. It is an important element of semen quality: useful in the diagnostic workup of the male and also as an additional indicator of assisted reproduction treatment success. Well-designed and powered clinical trials should be undertaken to address the effectiveness of antioxidant therapy as a matter of urgency.

Acknowledgements

The SCSA protocol and interpretation of data were developed over 25 years with peer-reviewed non-commercial US RO1 federal grants. All Comet data in this article was performed through peer-reviewed non-commercial funding, prior to the formation of Lewis Fertility Testing.

References

- Adler I.D.
Spermatogenesis and mutagenicity of environmental hazards: extrapolation of genetic risk from mouse to man.
Andrologia. 2000; 32: 233-237
View in Article
- Agbaje I.M.
- McVicar C.M.
- Schock B.C.
- McClure N.
- Atkinson A.B.
- Rogers D.
- Lewis S.E.M.
Increased levels of the Oxidative DNA adduct 7,8-dihydro-8-oxo-2′-deoxoguanosine in the germ-line of men with type-1 diabetes.
Reprod. Biomed. Online. 2008; 16: 401-409
View in Article
- Aitken R.J.
- De Iuliis G.N.
Origins and consequences of DNA damage in male germ cells.
Reprod. Biomed. Online. 2007; 14: 727-733
View in Article
- Aitken R.J.
- Koopman P.
- Lewis S.E.
Seeds of concern.
Nature. 2004; 432: 48-52
View in Article
- Aitken R.J.
- De Iuliis G.N.
- Finnie J.M.
- Hedges A.
- McLachlan R.I.
Analysis of the relationships between oxidative stress, DNA damage and sperm vitality in a patient population: development of diagnostic criteria.
Hum. Reprod. 2010; 25: 2415-2426
View in Article
- Aitken R.J.
- Jones K.T.
- Robertson S.A.
Reactive oxygen species and sperm function – in sickness and in health.
J. Androl. 2012; 33: 1096-1106
View in Article
- Alvarez J.G.
The predictive value of sperm chromatin structure assay.
Hum. Reprod. 2005; 20: 2365-2367
View in Article
- Anderson D.
Genetic and reproductive toxicity of butadiene and isoprene.
Chem. Biol. Interact. 2001; 135–136: 65-80
View in Article
- Ausubel M.F.
- Brent R.
- Kingston R.E.
- Moore D.D.
- Seidman J.G.
- Smith J.A.
- Strahl K.
Short Protocols in Molecular Biology.
second ed. Greene Publishing Association and John Wiley and Sons, New York, NY1992
View in Article
- Google Scholar
- Badouard C.
- Menezo Y.
- Panteix G.
- Ravanat J.L.
- Douki T.
- Cadet J.
- Favier A.
Determination of new types of DNA lesions in human sperm.
Zygote. 2008; 16: 9-13
View in Article
- Balasuriya A.
- Speyer A.B.
- Serhal P.
- Doshi A.
- Harper J.C.
Sperm chromatin dispersion test in the assessment of DNA fragmentation and aneuploidy in human spermatozoa.
Reprod. Biomed. Online. 2011; 22: 428-436
View in Article
- Balhorn R.
- Corzett M.
- Mazrimas J.A.
Formation of intraprotamine disulfates in vitro.
Arch. Biochem. Biophys. 1992; 296: 384-393
View in Article
- Ballachey B.E.
- Saacke R.G.
- Evenson D.P.
The sperm chromatin structure assay: relationship with alternate tests of sperm quality and heterospermic performance of bulls.
J. Androl. 1988; 9: 109-115
View in Article
- Barratt C.L.
- Mansell S.
- Beaton C.
- Tardif S.
- Oxenham S.K.
Diagnostic tools in male infertility – the question of sperm dysfunction.
Asian J. Androl. 2011; 13 (Epub 2010 November 22): 53-58
View in Article
- Bidmon C.
- Frischmann M.
- Pischetsrieder M.
Analysis of DNA-bound advanced glycation end-products by LC and mass spectrometry.
J. Chromatogr. B: Analyt. Technol. Biomed. Life Sci. 2007; 855: 51-58
View in Article
- Björndahl L.
- Barratt C.L.
- Fraser L.R.
- Kvist U.
- Mortimer D.
ESHRE basic semen analysis courses 1995–1999: immediate beneficial effects of standardized training.
Hum. Reprod. 2002; 17: 1299-1305
View in Article
- Bonde J.P.
- Ernst E.
- Jensen T.K.
- Hjollund N.H.
- Kolstad H.
- Henriksen T.B.
- Scheike T.
- Giwercman A.
- Olsen J.
- Skakkebaek N.E.
Relation between semen quality and fertility: a population-based study of 430 first-pregnancy planners.
Lancet. 1998; 352: 1172-1177
View in Article
- Brewer L.
- Corzett M.
- Lau E.Y.
- Balhorn R.
Dynamics of protamine 1 binding to single DNA molecules.
J. Biol. Chem. 2003; 278: 42403-42408
View in Article
- Bungum M.
- Humaidan P.
- Axmon A.
- Spano M.
- Bungum L.
- Erenpreiss J.
- Giwercman A.
Sperm DNA integrity assessment in prediction of assisted reproduction technology outcome.
Hum. Reprod. 2007; 22: 174-179
View in Article
- Bungum M.
- Bungum L.
- Lynch K.F.
- Wedlund L.
- Humaidan P.
- Giwercman A.
Spermatozoa DNA damage measured by sperm chromatin structure assay (SCSA) and birth characteristics in children conceived by IVF and ICSI.
Int. J. Androl. 2012; 35: 485-490
View in Article
- Cambi M.
- Tamburrino L.
- Marchiani S.
- Olivito B.
- Azzari C.
- Forti G.
- Baldi E.
- Muratori M.
Development of a specific method to evaluate 8-hydroxy,2-deoxyguanosine in sperm nuclei: relationship with semen quality in a cohort of 94 subjects.
Reproduction. 2013; 45: 227-235
View in Article
- Cavalieri E.L.
- Rogan E.G.
Depurinating estrogen–DNA adducts in the etiology and prevention of breast and other human cancers.
Future Oncol. 2010; 6: 75-91
View in Article
- Codrington A.M.
- Hales B.F.
- Robaire B.
Exposure of male rats to cyclophosphamide alters the chromatin structure and basic proteome in spermatozoa.
Hum. Reprod. 2007; 22: 1431-1442
View in Article
- Coetzee K.
- Kruge T.F.
- Lombard C.J.
Predictive value of normal sperm morphology: a structured literature review.
Hum. Reprod. Update. 1998; 4: 73-82
View in Article
- Cohen-Bacrie P.
- Belloc S.
- Ménézo Y.J.
- Clement P.
- Hamidi J.
- Benkhalifa M.
Correlation between DNA damage and sperm parameters: a prospective study of 1633 patients.
Fertil. Steril. 2009; 91: 1801-1805
View in Article
- Cooper T.G.
- Noonan E.
- von Eckardstein S.
- Auger J.
- Baker H.W.
- Behre H.M.
- Haugen T.B.
- Kruger T.
- Wang C.
- Mbizvo M.T.
- Vogelsong K.M.
World Health Organization reference values for human semen characteristics.
Hum. Reprod. Update. 2010; 16: 231-245
View in Article
- Crow J.F.
The origins, patterns and implications of human spontaneous mutation.
Nat. Rev. Genet. 2000; 1: 40-47
View in Article
- Darzynkiewicz Z.
- Traganos F.
- Sharpless T.
- Melamed M.R.
Thermal denaturation of DNA in situ as studied by acridine orange staining and automated cytofluorometry.
Exp. Cell Res. 1975; 90: 411
View in Article
- Davies M.J.
- Moore V.M.
- Willson K.J.
- Van Essen P.
- Priest K.
- Scott H.
- Haan E.A.
- Chan A.
Reproductive technologies and the risk of birth defects.
N. Engl. J. Med. 2012; 366: 1803-1813
View in Article
- De Iuliis G.N.
- Thomson L.K.
- Mitchell L.A.
- Finnie J.M.
- Koppers A.J.
- Hedges A.
- Nixon B.
- Aitken R.J.
DNA damage in human spermatozoa is highly correlated with the efficiency of chromatin remodelling and the formation of 8-hydroxy-2′-deoxyguanosine, a marker of oxidative stress.
Biol. Reprod. 2009; 81: 517-524
View in Article
- Didion B.
- Kasperson K.
- Wixon R.
- Evenson D.P.
Boar fertility and sperm chromatin structure status: a retrospective report.
J. Androl. 2009; 30: 655-660
View in Article
- Donnelly E.T.
- McClure N.
- Lewis S.E.
The effect of ascorbate and alpha-tocopherol supplementation in vitro on DNA integrity and hydrogen peroxide-induced DNA damage in human spermatozoa.
Mutagenesis. 1999; 14: 505-512
View in Article
- Doreswamy K.
- Muralidhara R.
Genotoxic consequences associated with oxidative damage in testis of mice subjected to iron intoxication.
Toxicology. 2005; 206: 169-178
View in Article
- Dumoulin J.C.
- Land J.A.
- Van Montfoort A.P.
- Nelissen E.C.
- Coonen E.
- Derhaag J.G.
- Schreurs I.L.
- Dunselman G.A.
- Kester A.D.
- Geraedts J.P.
- Evers J.L.
Effect of in vitro culture of human embryos on birthweight of newborns.
Hum. Reprod. 2010; 25: 605-612
View in Article
- Eggert-Kruse W.
- Schwarz H.
- Rohr G.
- Demirakca T.
- Tilgen W.
- Runnebaum B.
Sperm morphology assessment using strict criteria and male fertility under in-vivo conditions of conception.
Hum. Reprod. 1996; 11: 139-146
View in Article
- Esteves S.C.
- Zini A.
- Aziz N.
- Alvarez J.G.
- Sabanegh Jr., E.S.
- Agarwal A.
Critical appraisal of World Health Organization’s new reference values for human semen characteristics and effect on diagnosis and treatment of subfertile men.
Urology. 2012; 79: 16-22
View in Article
- Evenson D.P.
- Wixon R.
Clinical aspects of sperm DNA fragmentation detection and male infertility.
Theriogenology. 2006; 65: 979-991
View in Article
- Evenson D.
- Wixon R.
Meta-analysis of sperm DNA fragmentation using the sperm chromatin structure assay.
Reprod. Biomed. Online. 2006; 12: 466-472
View in Article
- Evenson D.P.
- Darzynkiewicz Z.
- Melamed M.R.
Relation of mammalian sperm chromatin heterogeneity to fertility.
Science. 1980; 240: 131-133
View in Article
- Crossref
- Google Scholar
- Evenson D.P.
- Jost L.K.
- Baer R.K.
- Turner T.W.
- Schrader S.M.
Individuality of DNA denaturation patterns in human sperm as measured by the sperm chromatin structure assay.
Reprod. Toxicol. 1991; 5: 115-125
View in Article
- Evenson D.P.
- Jost L.K.
- Marshall D.
- Zinaman M.J.
- Clegg E.
- Purvis K.
- de Angelis P.
- Claussen O.P.
Utility of the sperm chromatin structure assay as a diagnostic and prognostic tool in the human fertility clinic.
Hum. Reprod. 1999; 14: 1039-1049
View in Article
- Evenson D.P.
- Jost L.K.
- Varner D.D.
Stallion sperm nuclear protamine-SH status and susceptibility to DNA denaturation are not strongly correlated.
J. Reprod. Fertil. Suppl. 2000; 56: 401-406
View in Article
- PubMed
- Google Scholar
- Evenson D.P.
- Larson K.
- Jost L.K.
The sperm chromatin structure assay (SCSA™): clinical use for detecting sperm DNA fragmentation related to male infertility and comparisons with other techniques. Andrology Lab Corner.
J. Androl. 2002; 23: 25-43
View in Article
- PubMed
- Google Scholar
- Evenson D.P.
- Kasperson K.
- Wixon R.L.
Analysis of sperm DNA fragmentation using flow cytometry and other techniques.
Soc. Reprod. Fertil. Suppl. 2007; 65: 93-113
View in Article
- PubMed
- Google Scholar
- Fernández-Gonzalez R.
- Moreira P.N.
- Pérez-Crespo M.
- Sánchez-Martín M.
- Ramirez M.A.
- Pericuesta E.
- Bilbao A.
- Bermejo-Alvarez P.
- de Dios Hourcade J.
- de Fonseca F.R.
- Gutiérrez-Adán A.
Long-term effects of mouse intracytoplasmic sperm injection with DNA-fragmented sperm on health and behavior of adult offspring.
Biol. Reprod. 2008; 78: 761-772
View in Article
- Fraga C.G.
- Motchnik P.A.
- Wyrobek A.J.
- Rempel D.M.
- Ames B.N.
Smoking and low antioxidant levels increase oxidative damage to DNA.
Mutat. Res. 1996; 351: 199-203
View in Article
- Frans E.M.
- Sandin S.
- Reichenberg A.
- Lichtenstein P.
- Långström N.
- Hultman C.M.
Advancing paternal age and bipolar disorder.
Arch. Gen. Psychiatry. 2008; 65: 1034-1040
View in Article
- Gandy J.
- Bates H.K.
- Conder L.A.
- Harbison R.D.
Effects of reproductive tract glutathione enhancement and depletion on ethyl methanesulfonate-induced dominant lethal mutations in Sprague–Dawley rats.
Teratog. Carcinog. Mutagen. 1992; 12: 61-70
View in Article
- Gharagozloo P.
- Aitken R.J.
The role of sperm oxidative stress in male infertility and the significance of oral antioxidant therapy.
Hum. Reprod. 2011; 26: 1628-1640
View in Article
- Giustarini D.
- Dalle-Donne I.
- Colombo R.
- Milzani A.
- Rossi R.
Is ascorbate able to reduce disulfide bridges? A cautionary note.
Nitric Oxide. 2008; 19: 252-258
View in Article
- Giwercman A.
- Lindstedt L.
- Larsson M.
- Bungum M.
- Spano M.
- Levine R.J.
- Rylander L.
Sperm chromatin structure assay as an independent predictor of fertility in vivo: a case–control study.
Int. J. Androl. 2010; 33: 221-227
View in Article
- Gold R.
- Schmied M.
- Giegerich G.
- Breitschopf H.
- Hartung H.P.
- Toyka K.V.
- Lassmann H.
Differentiation between cellular apoptosis and necrosis by combined use of in situ tailing and nick translation techniques.
Lab. Invest. 1994; 71: 219-225
View in Article
- PubMed
- Google Scholar
- Gorczyca W.
- Traganos F.
- Jesionowska H.
- Darzynkiewicz Z.
Presence of DNA strand breaks and increased sensitivity of DNA in situ to denaturation in abnormal human sperm cells: analogy to apoptosis of somatic cells.
Exp. Cell Res. 1993; 207: 202-205
View in Article
- Gosálvez J.
- Gosálbez A.
- Arroyo F.
- Fernández J.L.
- López-Fernández C.
Assessing sperm DNA fragmentation in the field: an adaptation of sperm chromatin dispersion technology.
Biotech. Histochem. 2008; 83: 247-252
View in Article
- Greco E.
- Iacobelli M.
- Rienzi L.
- Ubaldi F.
- Ferrero S.
- Tesarik J.
Reduction of the incidence of sperm DNA fragmentation by oral antioxidant treatment.
J. Androl. 2005; 3: 349-353
View in Article
- Green R.F.
- Devine O.
- Crider K.S.
- Olney R.S.
- Archer N.
- Olshan A.F.
- Shapira S.K.
- National Birth Defects Prevention Study
Association of paternal age and risk for major congenital anomalies from the National Birth Defects Prevention Study, 1997 to 2004.
Ann. Epidemiol. 2010; 20: 241-249
View in Article
- Guzick D.S.
- Overstreet J.W.
- Factor-Litvak P.
- Brazil C.K.
- Nakajima S.T.
- Coutifaris C.
- Carson S.A.
- Cisneros P.
- Steinkampf M.P.
- Hill J.A.
- et al.
National Co-operative Reproductive Medicine Network. Sperm morphology, motility, and concentration in fertile and infertile men.
N. Engl. J. Med. 2001; 345: 1388-1393
View in Article
- Haugen T.B.
- Egeland T.
- Magnus O.
Semen parameters in Norwegian fertile men.
J. Androl. 2006; 27: 66-71
View in Article
- Hawkes W.C.
- Turek P.J.
Effects of dietary selenium on sperm motility in healthy men.
J. Androl. 2001; 22: 764-772
View in Article
- PubMed
- Google Scholar
- Hemminki K.
- Kyyrönen P.
- Vaittinen P.
Parental age as a risk factor of childhood leukemia and brain cancer in offspring.
Epidemiology. 1999; 10: 271-275
View in Article
- Henkel R.
DNA-based sperm assessment.
in: Kruger T.F. van der Spuy Z. Kempers R. Advances in Fertility Studies and Reproductive Medicine. Juta and Co. Ltd., Lansdowne, South Africa2007: 284-292
View in Article
- Google Scholar
- Henkel R.
Leukocytes and oxidative stress: dilemma for sperm function and male fertility.
Asian J. Androl. 2011; 13: 43-52
View in Article
- Henkel R.
Sperm preparation: state-of-the-art – physiological aspects and application of advanced sperm preparation methods.
Asian J. Androl. 2012; 14: 260-269
View in Article
- Henkel R.
- Hajimohammad M.
- Stalf T.
- Hoogendijk C.
- Mehnert C.
- Menkveld R.
- Gips H.
- Schill W.-B.
- Kruger T.F.
Influence of deoxyribonucleic acid damage on fertilization and pregnancy.
Fertil. Steril. 2004; 81: 965-972
View in Article
- Henkel R.
- Hoogendijk C.F.
- Bouic P.J.
- Kruger T.F.
TUNEL assay and SCSA determine different aspects of sperm DNA damage.
Andrologia. 2010; 42: 305-313
View in Article
- Irvine S.D.
- Twigg J.P.
- Gordon E.L.
- Fulton N.
- Milne P.A.
- Aitken J.R.
DNA integrity in human spermatozoa: relationships with semen quality.
J. Androl. 2000; 21: 33-44
View in Article
- PubMed
- Google Scholar
- Jequier A.
Male Infertility: A Guide for the Clinician.
Cambridge University Press, 2008
View in Article
- Google Scholar
- Ji B.T.
- Shu X.O.
- Linet M.S.
- Zheng W.
- Wacholder S.
- Gao Y.T.
- Ying D.M.
- Jin F.
Paternal cigarette smoking and the risk of childhood cancer among offspring of nonsmoking mothers.
J. Natl. Cancer Inst. 1997; 89: 238-244
View in Article
- Johnson K.J.
- Carozza S.E.
- Chow E.J.
- Fox E.E.
- Horel S.
- McLaughlin C.C.
- Mueller B.A.
- Puumala S.E.
- Reynolds P.
- Von Behren J.
- Spector L.G.
Birth characteristics and childhood carcinomas.
Br. J. Cancer. 2011; 105: 1396-1401
View in Article
- Jones R.
- Mann T.
- Sherins R.J.
Adverse effects of peroxidized lipid on human spermatozoa.
Proc. R. Soc. Lond. B: Biol. Sci. 1978; 201: 413-417
View in Article
- Jones R.
- Mann T.
- Sherins R.J.
Peroxidative breakdown of phospholipids in human spermatozoa: spermicidal effects of fatty acid peroxides and protective action of seminal plasma.
Fertil. Steril. 1979; 31: 531-537
View in Article
- Jørgensen N.
- Auger J.
- Giwercman A.
- Irvine D.S.
- Jensen T.K.
- Jouannet P.
- Keiding N.
- Le Bon C.
- MacDonald E.
- Pekuri A.M.
- et al.
Semen analysis performed by different laboratory teams: an intervariation study.
Int. J. Androl. 1997; 20: 201-208
View in Article
- Keel B.A.
- Stembridge T.W.
- Pineda G.
- Serafy Sr., N.T.
Lack of standardization in performance of the semen analysis among laboratories in the United States.
Fertil. Steril. 2002; 78: 603-608
View in Article
- Klein E.A.
- Thompson Jr., I.M.
- Tangen C.M.
- Crowley J.J.
- Lucia M.S.
- Goodman P.J.
- Minasian L.M.
- Ford L.G.
- Parnes H.L.
- Gaziano J.M.
- Karp D.D.
- Lieber M.M.
- Walther P.J.
- Klotz L.
- Parsons J.K.
- Chin J.L.
- Darke A.K.
- Lippman S.M.
- Goodman G.E.
- Meyskens Jr., F.L.
- Baker L.H.
Vitamin E and the risk of prostate cancer: the Selenium and Vitamin E Cancer Prevention Trial (SELECT).
JAMA. 2011; 306: 1549-1556
View in Article
- Kong A.
- Frigge M.L.
- Masson G.
- Besenbacher S.
- Sulem P.
- Magnusson G.
- Gudjonsson S.A.
- Sigurdsson A.
- Jonasdottir A.
- Jonasdottir A.
- Wong W.S.
- Sigurdsson G.
- Walters G.B.
- Steinberg S.
- Helgason H.
- Thorleifsson G.
- Gudbjartsson D.F.
- Helgason A.
- Magnusson O.T.
- Thorsteinsdottir U.
- Stefansson K.
Rate of de novo mutations and the importance of father’s age to disease risk.
Nature. 2012; 488: 471-475
View in Article
- Kruger T.F.
- Acosta A.A.
- Simmons K.F.
- Swanson R.J.
- Matta J.F.
- Veeck L.L.
- Morshedi M.
- Brugo S.
New method of evaluating sperm morphology with predictive value for human in vitro fertilization.
Urology. 1987; 30: 248-251
View in Article
- Lanzafame F.M.
- La Vignera S.
- Vicari E.
- Calogero A.E.
Oxidative stress and medical antioxidant treatment in male infertility.
Reprod. Biomed. Online. 2009; 19: 638-659
View in Article
- Larsen L.
- Scheike T.
- Jensen T.K.
- Bonde J.P.
- Ernst E.
- Hjollund N.H.
- Zhou Y.
- Skakkebaek N.E.
- Giwercman A.
Computer-assisted semen analysis parameters as predictors for fertility of men from the general population. The Danish First Pregnancy Planner Study Team.
Hum. Reprod. 2000; 15: 1562-1567
View in Article
- Lee K.M.
- Ward M.H.
- Han S.
- Ahn H.S.
- Kang H.J.
- Choi H.S.
- Shin H.Y.
- Koo H.H.
- Seo J.J.
- Choi J.E.
- Ahn Y.
- Kang D.
Paternal smoking, genetic polymorphisms in CYP1A1 and childhood leukemia risk.
Leuk. Res. 2009; 33: 250-258
View in Article
- Lefièvre L.
- Bedu-Addo K.
- Conner S.J.
- Machado-Oliveira G.S.
- Chen Y.
- Kirkman-Brown J.C.
- Afnan M.A.
- Publicover S.J.
- Ford W.C.
- Barratt C.L.
Counting sperm does not add up any more: time for a new equation?.
Reproduction. 2007; 133: 675-684
View in Article
- Lewis S.
Is sperm evaluation useful in predicting human fertility?.
Reproduction. 2007; 134 (Reproduction 2007, 133(4), 675–684): 1-11
View in Article
- Lewis S.E.
- Aitken R.J.
DNA damage to spermatozoa has impacts on fertilization and pregnancy.
Cell Tissue Res. 2005; 322 (Epub 2005 November 3, Review): 33-41
View in Article
- Lewis S.E.M.
- Boyle P.M.
- McKinney K.
- Young I.S.
- Thompson W.
Total antioxidant capacity of seminal plasma is different in fertile and infertile men.
Fertil. Steril. 1995; 64: 868-870
View in Article
- Liu Y.
- Guo H.C.
- Wang L.J.
- Dai Y.L.
- Zhang X.M.
- Li Z.H.
- He B.
Dynamic phosphorus budget for lake-watershed ecosystems.
J. Environ. Sci. (China). 2006; 18: 596-603
View in Article
- PubMed
- Google Scholar
- Manicardi G.C.
- Tombacco A.
- Bizzaro D.
- Bianchi U.
- Bianchi P.G.
- Sakkas D.
DNA strand breaks in ejaculated human spermatozoa: comparison of susceptibility to the nick translation and terminal transferase assays.
Histochem. J. 1998; 30: 33-39
View in Article
- Marchiani S.
- Tamburrino L.
- Maoggi A.
- Vannelli G.B.
- Forti G.
- Baldi E.
- Muratori M.
Characterization of M540 bodies in human semen: evidence that they are apoptotic bodies.
Mol. Hum. Reprod. 2007; 13: 621-631
View in Article
- Mathur P.P.
- D’Cruz S.C.
The effect of environmental contaminants on testicular function.
Asian J. Androl. 2011; 13: 585-591
View in Article
- Ménézo Y.J.
- Hazout A.
- Panteix G.
- Robert F.
- Rollet J.
- Cohen-Bacrie P.
- Chapuis F.
- Clément P.
- Benkhalifa M.
Antioxidants to reduce sperm DNA fragmentation: an unexpected adverse effect.
Reprod. Biomed. Online. 2007; 14: 418-421
View in Article
- Menkveld R.
- Stander F.S.
- Kotze T.J.
- Kruger T.F.
- van Zyl J.A.
The evaluation of morphological characteristics of human spermatozoa according to stricter criteria.
Hum. Reprod. 1990; 5: 586-592
View in Article
- PubMed
- Google Scholar
- Menkveld R.
- Franken D.R.
- Kruger T.F.
- Oehninger S.
- Hodgen G.D.
Sperm selection capacity of the human zona pellucida.
Mol. Reprod. Dev. 1991; 30: 346-352
View in Article
- Merviel P.
- Heraud M.H.
- Grenier N.
- Lourdel E.
- Sanguinet P.
- Copin H.
Predictive factors for pregnancy after intrauterine insemination (IUI): an analysis of 1038 cycles and a review of the literature.
Fertil. Steril. 2010; 93: 79-88
View in Article
- Meseguer M.
- Martínez-Conejero J.A.
- O’Connor J.E.
- Pellicer A.
- Remohí J.
- Garrido N.
The significance of sperm DNA oxidation in embryo development and reproductive outcome in an oocyte donation program: a new model to study a male infertility prognostic factor.
Fertil. Steril. 2008; 89: 1191-1199
View in Article
- Meseguer M.
- Santiso R.
- Garrido N.
- Gil-Salom M.
- RemohÃ J.
- Fernandez J.L.
Sperm DNA fragmentation levels in testicular sperm samples from azoospermic males as assessed by the sperm chromatin dispersion (SCD) test.
Fertil. Steril. 2009; 92 (Epub 2008 November 11): 1638-1645
View in Article
- Meseguer M.
- Stantiso R.
- Garrido N.
- Garcia-Herrero S.
- Remohi J.
- Fernandez J.L.
Effect of sperm DNA fragmentation on pregnancy outcome depends on oocyte quality.
Fertil. Steril. 2011; 95: 124-128
View in Article
- Mitchell L.A.
- De Iuliis G.N.
- Aitken R.J.
The TUNEL assay consistently underestimates DNA damage in human spermatozoa and is influenced by DNA compaction and cell vitality: development of an improved methodology.
Int. J. Androl. 2011; 34: 2-13
View in Article
- Muratori M.
- Tamburrino L.
- Tocci V.
- Costantino A.
- Marchiani S.
- Giachini C.
- Laface I.
- Krausz C.
- Meriggiola M.C.
- Forti G.
- Baldi E.
Small variations in crucial steps of TUNEL assay coupled to flow cytometry greatly affect measures of sperm DNA fragmentation.
J. Androl. 2009; 31: 336-345
View in Article
- Muratori M.
- Tamburrino L.
- Marchiani S.
- Guido C.
- Forti G.
- Baldi E.
Critical aspects of detection of sperm DNA fragmentation by TUNEL/flow cytometry.
Syst. Biol. Reprod. Med. 2010; 56: 277-285
View in Article
- Murray K.S.
- James A.
- McGeady J.B.
- Reed M.L.
- Kuang W.W.
- Nangia A.K.
The effect of the new 2010 World Health Organization criteria for semen analyses on male infertility.
Fertil. Steril. 2012; 98: 1428-1431
View in Article
- Muriel L.
- Garrido N.
- Fernández J.L.
- Remohí J.
- Pellicer A.
- de los Santos M.J.
- Meseguer M.
Value of the sperm DNA fragmentation level, measured by the sperm chromatin dispersion (SCD) test, in the IVF and ICSI outcome.
Fertil. Steril. 2006; 85: 371-383
View in Article
- Nakamura T.
- Sakai T.
- Hotchi M.
Histochemical demonstration of DNA double strand breaks by in situ 3′-tailing reaction in apoptotic endometrium.
Biotech. Histochem. 1995; 70: 33-39
View in Article
- Nallella K.P.
- Sharma R.K.
- Aziz N.
- Agarwal A.
Significance of sperm characteristics in the evaluation of male infertility.
Fertil. Steril. 2006; 85: 629-634
View in Article
- Nasr-Esfahani M.H.
- Razavi S.
- Vahdati A.A.
- Fathi F.
- Tavalaee M.
Evaluation of sperm selection procedure based on hyaluronic acid binding ability on ICSI outcome.
J. Assist. Reprod. Genet. 2008; 25: 197-203
View in Article
- O’Flaherty C.
- de Lamirande E.
- Gagnon C.
Reactive oxygen species and protein kinases modulate the level of phospho-MEK-like proteins during human sperm capacitation.
Biol. Reprod. 2005; 73: 94-105
View in Article
- Ombelet W.
- Deblaere K.
- Bosmans E.
- Cox A.
- Jacobs P.
- Janssen M.
- Nijs M.
Semen quality and intrauterine insemination.
Reprod. Biomed. Online. 2003; 7: 485-492
View in Article
- Park J.H.
- Gelhaus S.
- Vedantam S.
- Oliva A.L.
- Batra A.
- Blair I.A.
- Troxel A.B.
- Field J.
- Penning T.M.
The pattern of p53 mutations caused by PAH o-quinones is driven by 8-oxo-dGuo formation while the spectrum of mutations is determined by biological selection for dominance.
Chem. Res. Toxicol. 2008; 21: 1039-1049
View in Article
- Penn H.A.
- Windsperger A.
- Smith Z.
- Parekattil S.J.
- Kuang W.W.
- Kolettis P.N.
- Nangia A.K.
National semen analysis reference range reporting: adherence to the 1999 World Health Organization guidelines 10 years later.
Fertil. Steril. 2011; 95: 2320-2323
View in Article
- Reichenberg A.
- Gross R.
- Weiser M.
- Bresnahan M.
- Silverman J.
- Harlap S.
- Rabinowitz J.
- Shulman C.
- Malaspina D.
- Lubin G.
- Knobler H.Y.
- Davidson M.
- Susser E.
Advancing paternal age and autism.
Arch. Gen. Psychiatry. 2006; 63: 1026-1032
View in Article
- Riddell D.
- Pacey A.
- Whittington K.
Lack of compliance by UK andrology laboratories with World Health Organization recommendations for sperm morphology assessment.
Hum. Reprod. 2005; 20: 3441-3445
View in Article
- Robinson L.
- Gallos I.D.
- Conner S.J.
- Rajkhowa M.
- Miller D.
- Lewis S.E.M.
- Kirkman-Brown J.
- Coomarasamy A.
The effect of sperm DNA fragmentation on miscarriage rates: a systematic review and meta-analysis.
Hum. Reprod. 2012; https://doi.org/10.1093/humrep/des261
View in Article
- Ross C.
- Morriss A.
- Khairy M.
- Khalaf Y.
- Braude P.
- Coomarasamy A.
- El-Toukhy T.
A systematic review of the effect of oral antioxidants on male infertility.
Reprod. Biomed. Online. 2010; 20: 711-723
View in Article
- Rubes J.
- Selevan S.G.
- Evenson D.P.
- Zudova D.
- Vozdova M.
- Zudova Z.
- Robbins W.A.
- Perreault S.D.
Episodic air pollution is associated with increased DNA fragmentation in human sperm without other changes in semen quality.
Hum. Reprod. 2005; 20: 2776-2783
View in Article
- Ryu H.M.
- Lin W.W.
- Lamb D.J.
- Chuang W.
- Lipshultz L.I.
- Bischoff F.Z.
Increased chromosome X, Y, and 18 nondisjunction in sperm from infertile patients that were identified as normal by strict morphology: implication for intracytoplasmic sperm injection.
Fertil. Steril. 2001; 76: 879-883
View in Article
- Sailer B.
- Sarkar L.J.
- Bjordahl J.A.
- Jost L.K.
- Evenson D.P.
Effects of heat stress on mouse testicular cells and sperm chromatin structure.
J. Androl. 1997; 18: 294-301
View in Article
- PubMed
- Google Scholar
- Schmid T.E.
- Eskenazi B.
- Baumgartner A.
- Marchetti F.
- Young S.
- Weldon R.
- Anderson D.
- Wyrobek A.J.
The effects of male age on sperm DNA damage in healthy non-smokers.
Hum. Reprod. 2007; 22: 180-187
View in Article
- Sharma R.K.
- Sabanegh E.
- Mahfouz R.
- Gupta S.
- Thiyagarajan A.
- Agarwal A.
TUNEL as a test for sperm DNA damage in the evaluation of male infertility.
Urology. 2010; 76: 1380-1386
View in Article
- Showell M.G.
- Brown J.
- Yazdani A.
- Stankiewicz M.T.
- Hart R.J.
Antioxidants for male subfertility.
Cochrane Database Syst. Rev. 2011; 1: CD007411
View in Article
- PubMed
- Google Scholar
- Shukla Y.
- Taneja P.
Antimutagenic effect of black tea extract using ‘rodent dominant lethal mutation assay’.
Toxicology. 2001; 168: 269-274
View in Article
- Simon L.
- Lewis S.E.
Sperm DNA damage or progressive motility: which one is the better predictor of fertilization in vitro?.
Syst. Biol. Reprod. Med. 2011; 57: 133-138
View in Article
- Simon L.
- Lutton D.
- McManus J.
- Sheena E.
- Lewis M.
Clinical significance of sperm DNA damage in reproductive outcome.
Hum. Reprod. 2010; 25: 1594-1608
View in Article
- Simon L.
- Lutton D.
- McManus J.
- Lewis S.E.
Sperm DNA damage measured by the alkaline Comet assay as an independent predictor of male infertility and in vitro fertilization success.
Fertil. Steril. 2011; 95: 652-657
View in Article
- Simon L.
- Proutski I.
- Stevenson M.
- Jennings D.
- McManus J.
- Lutton D.
- Lewis S.E.M.
Sperm DNA damage has negative association with live birth rates after IVF.
Reprod. Biomed. Online. 2013; 26: 68-78
View in Article
- Singh N.P.
- Muller C.H.
- Berger R.E.
Effects of age on DNA double-strand breaks and apoptosis in human sperm.
Fertil. Steril. 2003; 80: 1420-1430
View in Article
- Sipos A.
- Rasmussen F.
- Harrison G.
- Tynelius P.
- Lewis G.
- Leon D.A.
- Gunnell D.
Paternal age and schizophrenia: a population based cohort study.
BMJ. 2004; 329: 1070
View in Article
- Spano M.
- Bonde J.
- Hjollund H.I.
- Kolstad H.A.
- Cordelli E.
- Leter G.
Sperm chromatin damage impairs human fertility.
Fertil. Steril. 2000; 73: 43-50
View in Article
- Stone M.P.
- Huang H.
- Brown K.L.
- Shanmugam G.
Chemistry and structural biology of DNA damage and biological consequences.
Chem. Biodivers. 2011; 8: 1571-1615
View in Article
- Thomson L.K.
- Zieschang J.A.
- Clark A.M.
Oxidative deoxyribonucleic acid damage in sperm has a negative impact on clinical pregnancy rate in intrauterine insemination but not intracytoplasmic sperm injection cycles.
Fertil. Steril. 2011; 96: 843-847
View in Article
- Trisini A.T.
- Singh N.P.
- Duty S.M.
- Hauser R.
Relationship between human semen parameters and deoxyribonucleic acid damage assessed by the neutral comet assay.
Fertil. Steril. 2004; 82: 1623-1632
View in Article
- Tyla R.W.
- Friedman M.A.
- Losco P.E.
- Fisher L.C.
- Johnson K.A.
- Strother D.E.
- Wolf C.H.
Rat two-generation reproduction and dominant lethal study of acrylamide in drinking water.
Reprod. Toxicol. 2000; 14: 385-401
View in Article
- Van der Steeg J.W.
- Steures P.
- Eijkemans M.J.
- Habbema J.D.
- Hompes P.G.
- Kremer J.A.
- van der Leeuw-Harmsen L.
- Bossuyt P.M.
- Repping S.
- Silber S.J.
- Mol B.W.
- van der Veen F.
Collaborative Effort for Clinical Evaluation in Reproductive Medicine Study Group. Role of semen analysis in subfertile couples.
Fertil. Steril. 2011; 95: 1013-1019
View in Article
- Van Waart J.
- Kruger T.F.
- Lombard C.J.
- Ombelet W.
Predictive value of normal sperm morphology in intrauterine insemination (IUI): a structured literature review.
Hum. Reprod. Update. 2001; 7: 495-500
View in Article
- Varshini J.
- Srinag B.S.
- Kalthur G.
- Krishnamurthy H.
- Kumar P.
- Rao S.B.
- Adiga S.K.
Poor sperm quality and advancing age are associated with increased sperm DNA damage in infertile men.
Andrologia. 2012; 44: 642-649
View in Article
- Velez de la Calle J.F.V.
- Muller A.
- Walschaerts M.
- Clavere J.L.
- Jimenez C.
- Wittemer C.
- Thonneau P.
Sperm deoxyribonucleic acid fragmentation as assessed by the sperm chormatin dispersion test in assisted reproductive technology programs: results of a large prospective multicenter study.
Fertil. Steril. 2008; 90: 1792-1799
View in Article
- Verhofstad N.
- van Oostrom C.T.
- Zwart E.
- Mass L.M.
- van Benthem J.
- van Schooten F.J.
- van Steeg H.
- Godschalk R.W.
Evaluation of benzo(a)pyrene-induced gene mutations in male germ cells.
Toxicol. Sci. 2011; 119: 218-223
View in Article
- Vilfan I.D.
- Conwell C.C.
- Hud N.V.
Formation of native-like mammalian sperm cell chromatin with folded bull protamine.
J. Biol. Chem. 2004; 279: 20088-20095
View in Article
- Wen J.
- Jiang J.
- Ding C.
- Dai J.
- Liu Y.
- Xia Y.
- Liu J.
- Hu Z.
Birth defects in children conceived by in vitro fertilization and intracytoplasmic sperm injection: a meta-analysis.
Fertil. Steril. 2012; 97: 1331-1337
View in Article
- Williams M.
- Hill C.J.
- Scudamore I.
- Dunphy B.
- Cooke I.D.
- Barratt C.L.
Sperm numbers and distribution within the human female fallopian tube around ovulation.
Hum. Reprod. 1993; 8: 2019-2026
View in Article
- PubMed
- Google Scholar
- Witt K.L.
- Bishop J.B.
Mutagenicity of anticancer drugs in mammalian germ cells.
Mutat. Res. 1996; 355: 209-234
View in Article
- World Health Organization
WHO Laboratory Manual for the Examination and Processing of Human Semen.
fourth ed. World Health Organization, Geneva1999
View in Article
- Google Scholar
- World Health Organization
WHO Laboratory Manual for the Examination and Processing of Human Semen.
fifth ed. World Health Organization, Geneva2010
View in Article
- Google Scholar
- Yilmaz S.
- Zergeroglu A.D.
- Yilmaz E.
- Sofuoglu K.
- Delikara N.
- Katlu P.
Effects of sperm DNA fragmentation on semen parameters and ICSI outcome determined by an improved SCD test, Halosperm.
Int. J. Fertil. Steril. 2010; 4: 73-78
View in Article
- Google Scholar
- Zenzes M.T.
Smoking and reproduction: gene damage to human gametes and embryos.
Hum. Reprod. Update. 2000; 6: 122-131
View in Article
- Zini A.
Are sperm chromatin and DNA defects relevant in the clinic?.
Syst. Biol. Reprod. Med. 2011; 57: 78-85
View in Article

Property	Value
Status
Version
Ad File
Disable Ads Flag
Environment
Moat Init
Moat Ready
Contextual Ready
Contextual URL
Contextual Initial Segments
Contextual Used Segments
AdUnit
SubAdUnit
Custom Targeting
Ad Events
Invalid Ad Sizes

Latest

For Authors

Society

Journal Information

Access

Contact

Follow Us

The impact of sperm DNA damage in assisted conception and beyond: recent advances in diagnosis and treatment

Abstract

Keywords

Introduction

Benefits and limitations of current semen tests

Current sperm DNA damage tests

The Comet assay

The sperm chromatin structure assay

The sperm chromatin dispersion

The TUNEL assay

The value of sperm DNA adduct analysis

Proxy tests for sperm DNA damage

The implications of sperm DNA damage in the diagnosis of male infertility, treatment choice and the health of future generations

Fecundity in the general population

Treatment choice

Implications for future generations’ health

The potential of antioxidant therapy

Conclusion

Acknowledgements

References