Metabolomics analysis of human spermatozoa reveals impaired metabolic pathways in asthenozoospermia.

BACKGROUND: Infertility is a major health issue, affecting 15% of reproductive-age couples with male factors contributing to 50% of cases. Asthenozoospermia (AS), or low sperm motility, is a common cause of male infertility with complex aetiology, involving genetic and metabolic alterations, inflammation and oxidative stress. However, the molecular mechanisms behind low motility are unclear. In this study, we used a metabolomics approach to identify metabolic biomarkers and pathways involved in sperm motility. METHODS: We compared the metabolome and lipidome of spermatozoa of men with normozoospermia (n = 44) and AS (n = 22) using untargeted LC-MS and the metabolome of seminal fluid using 1H-NMR. Additionally, we evaluated the seminal fluid redox status to assess the oxidative stress in the ejaculate. RESULTS: We identified 112 metabolites and 209 lipids in spermatozoa and 27 metabolites in the seminal fluid of normozoospermic and asthenozoospermic men. PCA analysis of the spermatozoa's metabolomics and lipidomics data showed a clear separation between groups. Spermatozoa of asthenozoospermic men presented lower levels of several amino acids, and increased levels of energetic substrates and lysophospholipids. However, the metabolome and redox status of the seminal fluid was not altered inAS. CONCLUSIONS: Our results indicate impaired metabolic pathways associated with redox homeostasis and amino acid, energy and lipid metabolism in AS. Taken together, these findings suggest that the metabolome and lipidome of human spermatozoa are key factors influencing their motility and that oxidative stress exposure during spermatogenesis or sperm maturation may be in the aetiology of decreased motility in AS.

In Vitro Effects of Charged and Zwitterionic Liposomes on Human Spermatozoa and Supplementation with Liposomes and Chlorogenic Acid during Sperm Freezing.

Semen handling and cryopreservation induce oxidative stress that should be minimized. In this study, human semen was supplemented during cryopreservation with formulations of handmade liposomes and chlorogenic acid (CGA), an antioxidant compound. Zwitterionic (ZL), anionic (AL), and cationic (CL) liposomes were synthesized and characterized. Three aliquots of swim-up-selected sperm were incubated with ZL, AL, and CL (1:10,000), respectively. The percentages of sperm with progressive motility, high mitochondrial membrane potential (MMP; JC-1), double-stranded DNA (dsDNA acridine orange), and acrosome integrity (Pisum sativum agglutinin) were assessed. Then, human semen was frozen using both 1:10,000 ZL and CGA as follows: freezing medium/empty ZL (EL), freezing medium/empty ZL/CGA in the medium (CGA + EL), freezing medium/CGA loaded ZL (CGA), freezing medium (CTR). The same sperm endpoints were evaluated. ZL were the most tolerated and used for semen cryopreservation protocols. All the supplemented samples showed better endpoints versus CTR (p < 0.001). In particular, spermatozoa from the CGA and CGA + EL A samples showed increased motility, dsDNA, and acrosome integrity versus CTR and EL (p < 0.001; motility EL vs. CGA + EL p < 0.05). ZL and CGA can improve post-thaw sperm quality, acting on both cold shock effect management and oxidative stress. These findings open new perspectives on human and animal reproduction.

Flagellar beating forces of human spermatozoa with different motility behaviors.

BACKGROUND: One of the causes of male infertility is associated with altered spermatozoa motility. These sperm features are frequently analyzed by image-based approaches, which, despite allowing the acquisition of crucial parameters to assess sperm motility, they are unable to provide details regarding the flagellar beating forces, which have been neglected until now. RESULTS: In this work we exploit Fluidic Force Microscopy to investigate and quantify the forces associated with the flagellar beating frequencies of human spermatozoa. The analysis is performed on two groups divided according to the progressive motility of semen samples, as identified by standard clinical protocols. In the first group, 100% of the spermatozoa swim linearly (100% progressive motility), while, in the other, spermatozoa show both linear and circular motility (identified as 80 - 20% progressive motility). Significant differences in flagellar beating forces between spermatozoa from semen sample with different progressive motility are observed. Particularly, linear motile spermatozoa exhibit forces higher than those with a circular movement. CONCLUSIONS: This research can increase our understanding of sperm motility and the role of mechanics in fertilization, which could help us unveil some of the causes of idiopathic male infertility.

Technology for Biobanking of Epididymal Spermatozoa from Patient with Obstructive Azoospermia: Case Report about Baby Born after Conventional Freezing Only with a Nonpermeable Cryoprotectant 360 kDa Polyvinylpyrrolidone.

This publication reports, for the first time, the birth of a healthy child after intracytoplasmic sperm injection (ICSI) of motile spermatozoa after conventional ("slow") freezing of epididymal spermatozoa using 5% polyvinylpyrrolidone (PVP) of high molecular weight (360 kDa). Cryopreservation solution with 10% PVP was added to 30 µL of spermatozoa suspension in a 1:1 ratio, with a final PVP concentration of 5%. Then, polycarbonate capillaries for oocyte denudation with a diameter of 170 µm were filled with 60 µL of the resulting sperm suspension. After that, the capillaries were placed for 10 minutes at a height of 15 cm above liquid nitrogen and immersed into liquid nitrogen. To warm the spermatozoa, the capillaries were immersed in a water bath at a temperature of 40°C for 30 seconds. Oocyte fertilization was performed by ICSI. Zygotes were cultured in vitro for 5 days to the blastocyst stage. More than 100 spermatozoa were obtained after percutaneous epidydimal sperm aspiration, of which 80% were motile. After cryopreservation, storage for 3 months in liquid nitrogen, and thawing, 72% of the total sperm cells remained motile. Ten oocyte-cumulus complexes were found after follicle puncture, and eight metaphase II stage oocytes were fertilized using ICSI. After 18 hours, two pronuclei were found in seven (88%) of the oocytes. An analysis of the morphological characteristics of 5-day-old embryos showed that four (57%) of them reached the blastocyst stage. One embryo was transferred, and the remaining embryos were cryopreserved (vitrified). The onset of pregnancy was detected on the 14th day after embryo transfer, and one healthy girl (3300 g) was born at term.

Oxidative Stress and Acrosomal Status of Human Spermatozoa Subjected to Hydrophobic Carbon Soot Treatments.

The fourth industrial revolution extensively reshapes the reality we are living in by blurring the boundaries of physical, digital and biological worlds. A good example is the previously unthinkable incursion of nanoscale waste materials, such as soot, into the technologies for assisted reproduction. Although the rapeseed oil soot may efficiently enhance the progressive motility of human spermatozoa, it is yet unknown whether this material induces undesirable oxidative stress and premature acrosome reaction, endangering the sperm-oocyte fusion and blastocyst formation. In an attempt to clarify this issue, we reveal that the three-hour incubation of human semen mixed with three main types of soot does not cause oxidative stress and spontaneous acrosome reaction of the sperm. These unique findings are attributed to synchronous elimination and stabilization of the oxidants via hydrogen bonding to the acidic groups of the soot (i.e., C=O and/or C-O-C) and electron donation by its basic chemical sites (i.e., C-OH and/or COOH). Moreover, the soot nanoparticles are electrostatically attracted by discrete positively charged areas on the sperm head, increasing its negative charge and in some cases interfering the acrosome reaction. Such novel mechanistic insights emphasize the credibility of rapeseed oil soot to confidently shift from the purely diagnostic and therapeutic phases in reproductive medicine to research dealing with the effect of carbon nanomaterials on the embryo development and implantation.

Phospholipase C Zeta in Human Spermatozoa: A Systematic Review on Current Development and Clinical Application.

During fertilization, the fusion of the spermatozoa with the oocytes causes the release of calcium from the oocyte endoplasmatic reticulum. This, in turn, triggers a series of calcium ion (Ca2+) oscillations, a process known as oocyte activation. The sperm-specific factor responsible for oocyte activation is phospholipase C zeta (PLCζ). Men undergoing intracytoplasmic sperm injection (ICSI) with their spermatozoa lacking PLCζ are incapable of generating Ca2+ oscillation, leading to fertilization failure. The immunofluorescence assay is the most used technique to assess the expression and localization of PLCζ and to diagnose patients with reduced/absent ability to activate the oocytes. In these patients, the use of assisted oocyte activation (AOA) technique can help to yield successful ICSI results and shorten the time of pregnancy. However, the production of a stable PLCζ recombinant protein represents a new powerful therapeutic approach to treating individuals with this condition. We aim to conduct a systematic review focusing on the expression, level, and localization of PLCζ, discussing the novel genetic mutation associated with its impairment. In addition, we highlight the benefits of AOA, looking at new and less invasive methods to diagnose and treat cases with PLCζ dysfunction.

Efecto de la borra de café sobre la biológica espermática: aproximación in vitro / Effect of spent coffee grounds on sperm biology: in vitro approach

OBJETIVO: El objetivo de este trabajo fue establecer el efecto de la borra de café sobre la movilidad y los parámetros funcionales de los espermatozoides humanos in vitro. MATERIALES Y MÉTODOS: La borra de café, un subproducto obtenido en establecimientos especializados en la preparación de café soluble a base de grano, se diluyo en tampón fosfato salino y se mezcló en proporciones iguales con las muestras de semen de 16 voluntarios aparentemente sanos. A cada muestra se le determinó el efecto sobre la movilidad espermática en función del tiempo (30, 60, 90 y 120 minutos, n=16) y sobre los parámetros funcionales (n=6) por medio de citometría de flujo: potencial de membrana mitocondrial, producción de especies reactivas de oxígeno y lipoperoxidación de la membrana espermática. RESULTADOS: La incubación de los espermatozoides con la borra de café evidencio un cambio positivo en la movilidad espermática. Adicionalmente, la incubación con la borra de café incremento significativamente el potencial de membrana mitocondrial en los espermatozoides. CONCLUSIÓN: La borra de café, seguramente debido a los compuestos antioxidantes, afecta positivamente la movilidad espermática aumentando el potencial de membrana mitocondrial. Por lo tanto, esto es un paso inicial en la búsqueda de un suplemento de origen natural que aumente la calidad seminal.

OBJECTIVE: The objective of this work is to establish the effect of spent coffee grounds on the motility and functional parameters of human spermatozoa, in vitro. MATERIALS AND METHODS: Spent coffee grounds, a by-product obtained in specialized establishments in the preparation of soluble coffee based on grain, was diluted in saline phosphate buffer and mixed in equal proportions with semen samples from 16 apparently healthy volunteers. Each sample was determined the effect on sperm motility as a function of time (30, 60, 90 and 120 minutes, n=16) and on functional parameters (n=6) by means of flow cytometry: mitochondrial membrane potential, reactive oxygen species production and membrane lipoperoxidation. RESULTS: The incubation of the spermatozoa with the spent coffee grounds showed a positive change in sperm motility. Additionally, incubation with spent coffee grounds significantly increased the mitochondrial membrane potential in human sperm cells. CONCLUSION: Spent coffee grounds, probably due to antioxidant compounds, positively affects sperm motility by increasing mitochondrial membrane potential. Therefore, this is an initial step in the search for a supplement of natural origin that increases seminal quality.

Efecto in vitro del pentóxido de vanadio (V2O5) sobre la calidad espermática / In vitro effect of vanadium pentoxide (V2O5) on sperm quality

El vanadio es un metal pesado considerado como un contaminante ambiental, producto de la manipulación antropogénica, que incide sobre el potencial reproductivo masculino, especialmente sobre la movilidad espermática. Esta investigación tuvo como objetivo determinar el efecto in vitro del pentóxido de vanadio sobre la calidad espermática. Se incubaron suspensiones de espermatozoides humanos por 24 horas bajo concentraciones de 0, 1 y 2 ppm V2O5, se realizó la valoración de la movilidad y vitalidad espermática, la integridad de membrana, la reacción acrosómica y la integridad de la cromatina espermática. El V2O5 alteró de manera significativa la movilidad espermática, específicamente los patrones de movilidad espermática moderado (p < 0.01), lento (p = 0.01) e inmóvil (p < 0.01). Los grupos tratados con V2O5 presentaron un porcentaje de espermatozoides vivos significativamente mayor al grupo control (p < 0.01). La integridad de membrana y reacción acrosómica no resultaron afectadas por la exposición de espermatozoides humanos a V2O5 (p > 0.05). De igual modo, no se observaron alteraciones del material nuclear (p > 0.05). El vanadio es capaz de alterar la movilidad y vitalidad espermática sin inducir cambios sobre la integridad de membrana y la cromatina espermática.

Vanadium is a heavy metal considered an environmental pollutant product of anthropogenic manipulation; it influences the masculine reproductive potential, especially the sperm motility. This research had the objective of determining the effect of vanadium pentoxide on sperm quality in vitro. Spermatozoa were incubated for 24 hours under 0, 1 and 2 ppm V2O5 concentrations, and sperm motility and vitality, membrane integrity, acrosome reaction and sperm chromatin integrity were assessed. V2O5 altered sperm motility in a significant way, specifically moderated (p < 0.01), slow (p = 0.01), and non motile (p < 0.01) sperm motility patterns. The groups treated with V2O5 had a major percentage of live spermatozoa than the control group (p < 0.01). Membrane integrity and acrosome reaction were not affected by human sperm exposition to V2O5 (p > 0.05). Similarly, we did not observe nuclear material alterations. Vanadium is able to alter sperm motility and viability without inducing changes on membrane and chromatin integrity.

Laboratory processing and intracytoplasmic sperm injection using epididymal and testicular spermatozoa: what can be done to improve outcomes?

There are two main reasons why sperm may be absent from semen. Obstructive azoospermia is the result of a blockage in the male reproductive tract; in this case, sperm are produced in the testicle but are trapped in the epididymis. Non-obstructive azoospermia is the result of severely impaired or non-existent sperm production. There are three different sperm-harvesting procedures that obstructive azoospermic males can undergo, namely MESA (microsurgical epididymal sperm aspiration), PESA (percutaneous epididymal sperm aspiration), and TESA (testicular sperm aspiration). These three procedures are performed by fine-gauge needle aspiration of epididymal fluid that is examined by an embryologist. Additionally, one technique, called TESE (testicular sperm extraction), is offered for males with non-obstructive azoospermia. In this procedure, a urologist extracts a piece of tissue from the testis. Then, an embryologist minces the tissue and uses a microscope to locate sperm. Finding sperm in the testicular tissue can be a laborious 2- to 3-hour process depending on the degree of sperm production and the etiology of testicular failure. Sperm are freed from within the seminiferous tubules and then dissected from the surrounding testicular tissue. It is specifically these situations that require advanced reproductive techniques, such as ICSI, to establish a pregnancy. This review describes eight different lab processing techniques that an embryologist can use to harvest sperm. Additionally, sperm cryopreservation, which allows patients to undergo multiple ICSI cycles without the need for additional surgeries, will also be discussed.

Congelación ultra rápida de espermatozoides humanos: efecto sobre la función espermática y producción de especies reactiva de oxígeno / Ultra rapid freezing in human spermatozoa: effect on sperm function and reactive oxygen species production

El incremento del número de pacientes que desean mantener su fertilidad, ya sea por motivos oncológicos o de fertilidad, como son los pacientes con enfermedades infecciosas virales trasmitidas por vía sexual, o que se someten en forma voluntaria a la esterilización quirúrgica, requieren de métodos de congelación que preserven en forma adecuada la función de los espermatozoides. En el área de la criobiología, la utilización de técnicas de congelación ultrarrápida ha permitido preservar en forma exitosa ovocitos, embriones y tejido ovárico. Este método se ha incorporado recientemente para preservar el gameto masculino. El presente estudio evalúa el efecto de la congelación ultrarrápida (vitrificación) sobre la función espermática de 10 donantes normozoospérmicos. Los espermatozoides se seleccionaron por Swim-up y la solución espermática se dividió en dos subfracciones. Una fracción se vitrificó sumergiéndola directamente en nitrógeno líquido mientras que la segunda se utilizó como control. En ambas fracciones se determinaron viabilidad, movilidad, potencial de membrana mitocondrial (YMMit), integridad del ADN, reacción de acrosoma espontánea e inducida, y superóxido intracelular (O2.-). Se observó que la vitrificación preserva una adecuada función celular en un alto número de espermatozoides, siendo además un método simple, rápido y de menor costo, ya que no necesita equipo de congelación. No obstante, existe una significativa activación de la producción de especies reactivas de oxígeno, que conlleva a una prematura capacitación espermática, evento que es necesario de modular, especialmente si se utilizan estas células en técnicas de inseminación intrauterina. Futuros estudios con adición de antioxidantes a los medios de congelación parecen necesarios para optimizar esta técnica.

The number of patients who wish to maintain their fertility is ever increasing. This group of patients includes cancer patients, those with fertility problems or viral infectious diseases acquired through sexual contact and others submitting to voluntary surgical sterilization; all of the above requiring freezing methods to adequately preserve sperm function. In the field of cryobiology the use of ultra-rapid freezing techniques has successfully preserved oocytes, embryos and ovarian tissue. This method has recently been incorporated in preserving male gametes. This study evaluates the effect of ultra-rapid freezing (vitrification) on sperm function of 10 normozoospermic donors. The sperm were selected by swim-up technique and the solution divided into two fractions. One fraction is vitrified by dipping directly into liquid nitrogen and the second fraction is used as control. In both fractions, viability, motility, mitochondrial membrane potential (YMMit) DNA integrity, spontaneous and induced acrosome reaction and intracellular superoxide (O2.-) were determined. It was noted that vitrification preserves cell function in a great number of spermatozoon, and is also simple, rapid and cost effective as this method does not require freezing equipment. There is however, significant activation of the production of reactive oxygen species, which leads to premature sperm capacitation, an event necessary to modulate particularly when using these cells in intrauterine insemination techniques. Future studies with addition of antioxidants to freezing media are necessary to further improve this technique.