ICSI Utilizing Ejaculated Spermatozoa

The original indication for ICSI was to treat mainly male factor infertility such as suboptimal sperm concentration, severely impaired sperm kinetics, and poor sperm morphology (Figure 2.3). During its development, ICSI became a versatile treatment for most types of infertility. Currently, 90% of all ICSI cycles performed at our center utilize ejaculated specimens. ICSI was developed to enable the male gamete to bypass natural barriers surrounding the oocyte, such as cumulus cells, the ZP, as well as the oolemma, and it has been proven to be the most effective method to treat couples presenting with oligo-, astheno-, and/or teratozoospermia [Reference Palermo, Cohen, Alikani, Adler and Rosenwaks33]. In addition, ICSI is the only viable method to treat cryptozoospermia, a condition in which spermatozoa are extremely scarce. In these cases, an extensive sperm search is required to identify all spermatozoa needed to inseminate the oocytes retrieved [Reference Palermo, Neri, Schlegel and Rosenwaks27].

Figure 2.3 Male factor ICSI indications.

ICSI with Surgically Retrieved Spermatozoa

Because ICSI requires only one spermatozoon to fertilize an oocyte regardless of the morphological, kinetical, and maturational status of the male gamete, it represents the sole insemination approach for azoospermic men for whom spermatozoa can only be retrieved by surgical intervention. Epididymal aspiration has become an effective way to retrieve relatively mature spermatozoa for ICSI in men with obstructive azoospermia (OA), whether it is acquired (i.e., vasectomy) or results from genetic defects such as congenital bilateral absence of the vas deferens [Reference Ma, Marti-Gutierrez, Park, Wu, Lee, Suzuki, Koski, Ji, Hayama and Ahmed34, Reference Schlegel, Palermo, Alikani, Adler, Reing, Cohen and Rosenwaks35]. Non-obstructive azoospermia (NOA), whether caused by hypogametogenesis, maturational arrest, or germ cell aplasia, requires surgical retrieval directly from the testicular seminiferous tubule [Reference Schlegel, Palermo, Alikani, Adler, Reing, Cohen and Rosenwaks35, Reference Chan, Palermo, Veeck, Rosenwaks and Schlegel36]). At our center, ICSI has allowed testicular spermatozoa to achieve a 48.4% fertilization rate and a 35.9% clinical pregnancy rate. Even in cases with Klinefelter’s syndrome, ICSI has helped men with a non-mosaic XXY genotype to father offspring with a normal karyotype [Reference Palermo, Schlegel, Sills, Veeck, Zaninovic, Menendez and Rosenwaks37].

High DNA Fragmentation of the Male Gamete

While some male infertility etiologies are straightforward, unexplained infertility because of a subtle male factor remains challenging. To understand the etiology of these peculiar cases, supplementary tests may be needed prior to ICSI treatment [Reference O’Neill, Parrella, Keating, Cheung, Rosenwaks and Palermo38]. Even though the sperm genome is highly compacted, oxidative damage during the transit through the male genital tract can result in DNA breakage (Figure 2.4). Moreover, sperm chromatin fragmentation (SCF) has been shown to be negatively correlated with sperm motility [Reference Palermo, Neri, Schlegel and Rosenwaks27]. High SCF, resulting in recurrent pregnancy loss, can therefore be prevented by ICSI, as only the most motile spermatozoa are selected for insemination. In conjunction with ICSI, surgical retrieval of spermatozoa provided another approach to ameliorate the effect of high SCF [Reference Xie, Keating, Parrella, Cheung, Rosenwaks, Goldstein and Palermo39].

Figure 2.4 TUNEL assay depicting spermatozoa with fragmented DNA (green fluorescent signal).

Assisted Oocyte Activation

Although ICSI has been able to greatly alleviate male factor infertility, rare cases of fertilization failure after ICSI can still occur. While this can result from asynchronous oocyte maturation, it may also be attributed to a lack of a specific oocyte-activating factor in the spermatozoa. Assisted oocyte activation (AOA) can therefore be used to achieve successful fertilization and even clinical pregnancy. AOA can be carried out by exposing the oocytes, post-ICSI, to either a chemical agent or an electrical pulse [Reference Yanagida, Katayose, Yazawa, Kimura, Sato, Yanagimachi and Yanagimachi40]. Moreover, sperm-derived activating extracts or calcium-releasing compounds can be used to further enhance fertilization in these problematic cases. Oocyte activation agents include electroactivation, calcium ionophore, and strontium chloride [Reference Yanagida, Katayose, Yazawa, Kimura, Sato, Yanagimachi and Yanagimachi40–Reference Yanagida, Morozumi, Katayose, Hayashi and Sato42]. During fertilization, a series of distinct Ca²⁺ oscillation spikes occurs in the oocyte. These cytosolic Ca²⁺ spikes release waves from the endoplasmic reticulum, initiated by a sperm-bound labile protein that has been shown to settle onto a sperm-specific phospholipase C zeta (PLCζ) [Reference Wolny, Fissore, Wu, Reis, Colombero, Ergun, Rosenwaks and Palermo44] (Figure 2.5). Treatment with an oocyte-activating agent enhances this process by increasing Ca²⁺ permeability at the cell membrane, allowing an influx of extracellular Ca²⁺ into the ooplasm and thereby inducing Ca²⁺ release from intracellular calcium stores (Figure 2.6).

Figure 2.5 PLCζ, the putative soluble cytosolic factor, required for fertilization examined by immunofluorescence microscopy.

Figure 2.6 Mechanism of assisted oocyte activation.

One pioneering study on AOA reported 17 couples with previously failed fertilization following ICSI. For these patients’ subsequent ICSI cycles, AOA was carried out by injecting the spermatozoon with medium containing a high concentration of CaCl₂, followed by exposing the oocyte to calcium ionophore. As a result, couples with this peculiar defect were able to achieve an overall fertilization rate of over 70% [Reference Heindryckx, Van der Elst, De Sutter and Dhont45]. While this treatment can effectively trigger oocyte activation, allowing concurrent sperm nuclear decondensation and thereby promoting zygote development, it is important to document a clear sperm-dependent oocyte activation deficiency (OAD), as is typical for globozoospermic cases (Figure 2.7). The demonstration of a specific sperm disturbance serves as a proper indication for AOA, identified in couples with a history of fertilization failure with ICSI and confirmed with the mouse oocyte activation test (MOAT) to measure the oocyte activation capacity of the spermatozoon. Couples with a history of failed fertilization caused by OAD were categorized as suspected, somewhat related, or clearly related to the spermatozoon. ICSI fertilization and pregnancy outcomes after AOA were then compared to the same patients’ previous cycles serving as controls. AOA consistently obtained higher fertilization and clinical pregnancy rates than those achieved from cycles of the same couples serving as controls [Reference Bonte, Ferrer-Buitrago, Dhaenens, Popovic, Thys, De Croo, De Gheselle, Steyaert, Boel and Vanden Meerschaut46].

Figure 2.7 Transmission electron micrograph of globozoospermic specimen.

Despite its demonstrated safety and effectiveness, it is imperative to remember that prior to using AOA treatment, the culpable gamete must first be identified. Therefore, AOA should be reserved only for those cases where a clear sperm-linked OAD has been diagnosed, and it should not simply be regarded as a remedy whenever unexplained fertilization failure occurs.

Oocyte Dysmorphism

ICSI is a reliable technique that can also benefit non-male factor infertility. Using oocyte morphology to predict clinical outcome is questionable, but several studies have shown that oocyte quality reflects embryo developmental potential [Reference Gilchrist, Lane and Thompson47]. In conjunction with ICSI, it is possible to evaluate detailed oocyte morphology immediately after decoronization using high-magnification microscopy. This would not be feasible with standard IVF, in which the evaluation is limited to observation of the cumulus–oocyte complex with limited information on the oocyte itself. Indeed, with standard in vitro insemination, the oocyte can be properly evaluated once the cumulus corona cells have been dispersed by the inseminating spermatozoa.

The normal metaphase II (MII) oocyte morphology is defined as an oocyte with a spherical structure surrounded by a homogenous ZP, with a cytoplasm free of inclusions and with a uniform polar body (PB). However, not all MII oocytes display this perfect morphology (Figure 2.8).

Figure 2.8 Different types of intraooplasmic dysmorphism: (A) inclusions, (B) refractile bodies, (C) smooth endoplasmic reticulum, (D) central granulation/dark center, (E) vacuoles, (F) granular ooplasm. Different types of extraooplasmic abnormalities: (G) fragmented PB, (H) large PB, (I) expanse of perivitelline space (PVS), (J) perivitelline debris. Different types of zona pellucida (ZP) deformities: (K) dark ZP, (L) thin ZP, (M) abnormal ZP, (N) bilayered ZP. Other types of oocyte dysmorphism: (O) irregular shape, (P) oval oocyte.

Oocyte dysmorphism can be characterized by an abnormal cytoplasm (dark or granular), cytoplasmic inclusions (vacuoles, refractile bodies, or smooth endoplasmic reticulum), non-spherical shapes, abnormal ZP, abnormal perivitelline space, and/or abnormal PB (fragment, giant, smooth, duplicated). Several studies have attempted to investigate the clinical outcomes of dysmorphic oocytes. Indeed, one such study showed that when these abnormal oocytes were inseminated via standard IVF, no fertilization was achieved, whereas the use of ICSI in these particular cases not only improved their fertilizing ability, but also provided a more satisfactory clinical outcome [Reference Alikani, Palermo, Adler, Bertoil, Blake and Cohen48]. This success proved that sperm decondensation and pronuclear formation/migration are not influenced by cytoplasmic features when ICSI is applied. Another study showed that oocytes with cytoplasmic defects did not influence fertilization and cleavage rates, although implantation and clinical pregnancy rates were compromised [Reference Serhal, Ranieri, Kinis, Marchant, Davies and Khadum49]. Furthermore, a similar study reported that some defects such as refractile bodies or granular cytoplasm could decrease fertilization and embryo developmental competence [Reference Xia50]. These findings were supported by the results of ICSI on oocytes with centered granularity, which achieved a 4.2% implantation rate [Reference Kahraman, Yakin, Donmez, Samli, Bahce, Cengiz, Sertyel, Samli and Imirzalioglu51, Reference Meriano, Alexis, Visram-Zaver, Cruz and Casper52]].

Lastly, a few studies also demonstrated that although fertilization is not compromised, increased pregnancy loss may result from embryo aneuploidy that is possibly caused by dysmorphic oocytes [Reference Alikani, Palermo, Adler, Bertoil, Blake and Cohen48, Reference Yakin, Balaban, Isiklar and Urman53]. For example, an assessment concluded that fertilization and embryo developmental competence could not be attributed to oocyte characteristics [Reference Swain and Pool54].

In conclusion, while many oocyte anomalies have been described that may influence embryo selection, particularly with the advent of time-lapse observation, it is still not clear what impact these morphological traits have on clinical outcome.

Low Oocyte Maturity

To achieve normal fertilization and adequate embryo developmental competence, an oocyte undergoes certain modifications and completes essential processes involving the nucleus and cytoplasm [Reference Eichenlaub-Ritter, Schmiady, Kentenich and Soewarto55]. During follicular antral formation, granulosa cells differentiate into two specialized subpopulations of cumulus complex (CC), in which the innermost layer consists of the corona radiata and the parietal granulosa cells. Communication between the oocyte and the corona cells is required for oocyte maturation. At the time of ovulation, resumption of meiosis along with an LH surge stimulates active secretion of hyaluronic acid, inducing the expansion of the cumulus corona mass, and the formation of the corona radiata, which is essential for proper spermatozoa capacitation and subsequent fertilization.

While germinal vesicles retrieved from smaller follicles are typically characterized by an unexpanded cumulus with multiple layers of granulosa cells, metaphase-I oocytes have a more subtle appearance with a well-dispersed surrounding cumulous cell. Oocyte nuclear maturity can only be assessed properly after removal of cumulus cells, and is confirmed by the extrusion of the first polar body in the perivitelline space, indicating successful completion of meiosis I and arrest at the MII stage of development. In standard IVF, the CC is retained prior to insemination; hence, oocyte morphology and, most importantly, maturity cannot be assessed. In contrast, removal of the CC is essential for ICSI and simultaneously allows for proper evaluation of oocyte maturity. MII oocytes are the optimal and sole maturational stage for ICSI. The number of MII oocytes retrieved at each cycle can be affected by follicle size, certain ovarian stimulation protocols, or the surgeon’s ability to retrieve the smallest antral follicles [Reference Parrella, Irani, Keating, Chow, Rosenwaks and Palermo56]. ICSI offers an advantage in terms of “reading” oocytes following cumulus removal and enhances fertilization chances by direct spermatozoon injection [Reference Palermo, Neri and Rosenwaks28].

Cryopreserved Oocytes

Oocyte cryopreservation provides several advantages in ART, including the ability to preserve fertility for cancer patients or for women who choose to postpone motherhood. The survival rate for cancer patients has dramatically improved in the last two decades, increasing the need for fertility preservation. Cryopreserving “young” oocytes also maintains fertility potential and improves outcomes for older women who have delayed childbearing.

Oocyte morphology prior to cryopreservation impacts the cell integrity during thawing. If the oocyte quality is suboptimal, the post-thaw survivability will be compromised [Reference Xia50]. It is important that the thawed oocytes maintain developmental competence without any major alterations, particularly of the ZP.

The cortical reaction is triggered when a single spermatozoon binds to glycoproteins on the oolemma, leading to hardening of the ZP, thus preventing polyspermy and abnormal fertilization. It has been shown that cryostress may cause an increase in intracellular calcium concentration, inducing a cortical reaction and a premature release of cortical granules, and consequently modifications of the ZP, hindering physiologic sperm–oocyte fusion by IVF. The ability to bypass natural obstacles represented by a modified ZP, and the receptivity of the oolemma during cryopreservation, make ICSI the optimal methodology to inseminate oocytes that have been frozen and thawed [Reference Kazem, Thompson, Srikantharajah, Laing, Hamilton and Templeton57].

In Vitro Maturation (IVM)

In vitro maturation (IVM) is conducted on immature oocytes retrieved from small follicles of about 10 mm diameter, and it is usually considered an optional treatment mainly for patients with polycystic ovaries (PCOs) or a history of severe ovarian hyperstimulation syndrome (OHSS). It can also be extended to many other indications mainly related to defective oocyte maturation following a standard superovulation protocol [Reference Walls, Ryan, Keelan and Hart58]. Nonetheless, ultrastructural changes and altered properties of ZP have been observed in IVM oocytes [Reference Hatirnaz, Ata, Hatirnaz, Dahan, Tannus, Tan and Tan59]. In addition, the cumulus cells surrounding IVM oocytes have shown to carry a high apoptotic potential, requiring premature removal [Reference Shu, Zeng, Ren, Zhuang, Liang, Shen, Yao, Ke and Wang60]. All these requirements may affect the ability of IVM oocytes to be fertilized by standard in vitro insemination. Thus, ICSI is the preferred insemination method for these cases, as it allows the hardened ZP of a denuded IVM oocyte to be bypassed.

Preimplantation Genetic Testing

Preimplantation genetic testing (PGT) is the primary method for detecting multiple types of genetic embryo anomalies. For instance, numerical chromosomal anomalies within the embryo can be detected by PGT for aneuploidy screening (PGT-A), common in women of advanced reproductive age. While the presence of structural anomalies such as translocation or deletions can be identified by PGT for structural rearrangement (PGT-SR), PGT for monogenic disorders (PGT-M) can screen embryos for genetic mutations, providing valuable information on conceptuses regarding a particular heritable genetic disorder (PGT-M) or aneuploidy (PGT-A).

Initially, PGT was performed on individual blastomeres of day-3 embryos at the six- to eight-cell stage. However, at this phase of development, the embryo has not completed its self-selection in terms of its ability to implant. Moreover, the removal of one or two blastomeres with a high level of pluripotency may affect the embryo’s developmental competence [Reference Kirkegaard, Hindkjaer and Ingerslev61]. Therefore, the need to assess a larger number of cells by trophectoderm biopsies has become the standard, as this does not appear to have any negative effect on the implantation rate.

Aside from the embryo stage, the genetic assessment has evolved as well. While FISH was the earliest technique used for genetic testing, followed by comparative genome hybridization (CGH) and comprehensive chromosome screening (CCS), PGT is now primarily performed by next-generation sequencing [Reference Fragouli62].

While both PGT-A and PGT-M have become increasingly common [Reference Coates, Kung, Mounts, Hesla, Bankowski, Barbieri, Ata, Cohen and Munne63, Reference Forman, Hong, Ferry, Tao, Taylor, Levy, Treff and Scott64], PGT-M is utilized by couples, often fertile, to identify the risk of a conceptus carrying a heritable defect. Conversely, PGT-A has been performed for approximately 31% of all ART cycles in 2016 alone [Reference Palmerola, Vitez, Amrane, Fischer and Forman65]. Although PGT can be used with standard in vitro insemination, it has been strongly recommended that PGT be used in conjunction with ICSI for several reasons [32]. As ICSI requires the removal of cumulus cells from the oocyte, there would be no maternal genetic material remaining in the culture media or the trophectoderm biopsy sample that could alter test results. As ICSI requires only a single spermatozoon to inseminate the oocyte, there is no risk of paternal DNA contamination, as is the case with in vitro insemination where multiple spermatozoa attach to the ZP and may contaminate the molecular genetic technique. This was demonstrated by a recent study that reported a higher incidence of mosaicism in embryos inseminated by standard IVF cycles in comparison to ICSI [Reference Palmerola, Vitez, Amrane, Fischer and Forman65]. In addition, the higher fertilization rate achieved by ICSI would provide more embryos available for genetic assessment [Reference Jun, O’Leary, Jackson and Racowsky66].

While the universal adoption of PGT remains a matter of debate – concerns remain about putative embryo injury and genetic technical error contributing to embryo “wastage” for the above-mentioned reasons – ICSI is the preferable insemination method to use with PGT to avoid DNA contaminants that may contribute to the misinterpretation of results.