Abstract
Accurate prediction of oocyte maturation is a critical determinant of success in in vitro fertilization-embryo transfer (IVF-ET) procedures. This review provides a comprehensive analysis of the various predictive approaches employed to assess oocyte maturity, including single indicators, combined indicators, and predictive models. Factors such as ovarian reserve, patient characteristics, and controlled ovarian hyperstimulation (COH) strategies can significantly influence oocyte maturation rates. Single indicators, including hormone levels, ultrasound parameters, and clinical parameters, have been extensively studied. However, their predictive power may be limited when used in isolation. Combined indicators, integrating multiple parameters, have demonstrated improved predictive performance compared to single indicators. Additionally, predictive models and algorithms, such as machine learning and deep learning models, have emerged as promising tools for assessing oocyte maturity. These models leverage advanced statistical and computational methods to analyze complex datasets and identify patterns that can predict oocyte maturation rates with potentially higher accuracy. Despite these advancements, several gaps and limitations persist, including limited generalizability, lack of standardization, insufficient external validation, and the need to incorporate patient-specific factors and emerging technologies. The review highlights potential areas for further research, such as multicenter collaborative studies, integration of advanced omics technologies, development of personalized prediction models, and investigation of trigger time optimization strategies. Recommendations for clinical practice include utilizing a combination of indicators, adopting validated predictive models, tailoring approaches based on individual patient characteristics, continuous monitoring and adjustment, and fostering multidisciplinary collaboration. Accurate prediction of oocyte maturation holds profound implications for improving the success rates of IVF-ET and enhancing the chances of achieving a healthy pregnancy. Continued research, innovative approaches, and the implementation of evidence-based practices are essential to optimize assisted reproductive outcomes.
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Introduction
In vitro fertilization-embryo transfer (IVF-ET) has revolutionized the field of assisted reproductive technology, offering hope to countless individuals and couples struggling with infertility [1]. This intricate process involves the retrieval of mature oocytes from the ovaries, followed by their fertilization with sperm in a laboratory setting, and the subsequent transfer of the resulting embryos into the uterus. As a crucial step in this period, oocyte maturation plays a pivotal role in determining the success of IVF-ET [1,2,3].
Despite the remarkable advancements in IVF-ET techniques, clinicians and patients alike still face significant challenges and risks. One of the most concerning issues is the failure to retrieve eggs or a low percentage of mature oocytes among the retrieved eggs [4]. The incidence of failed oocyte retrieval in IVF cycles is approximately 1–2%, which may be attributed to various factors, including empty follicles, technical difficulties, early ovulation, or incorrect use of human chorionic gonadotropin (hCG) injection [5]. Moreover, oocyte quality directly influences the outcome of IVF-ET, as immature or abnormal oocytes may compromise fertilization, embryo development, and, ultimately, the chances of a successful pregnancy [6].
Accurate prediction of oocyte maturity is therefore the first and most crucial step for clinicians in the IVF-ET process. Accompanied by controlled ovarian hyperstimulation (COH), the selection of the appropriate trigger time for oocyte maturation is also a critical factor in achieving a higher rate of mature oocytes [7]. Numerous studies have focused on developing predictive methods for oocyte maturity by utilizing hormone levels, ultrasound parameters, or other clinical indicators [7,8,9]. However, the predictive value of these individual indicators can vary significantly, highlighting the need for a more comprehensive and integrated approach.
We aimed to provide a comprehensive analysis of the various predictive indicators, models, and strategies employed to assess oocyte maturation during IVF-ET. We also explored single indicators, combined indicators, and predictive models used during COH, with a particular emphasis on the period before and after the hCG trigger. By critically evaluating the existing literature and methodologies, we intended to identify the most effective approaches for optimizing oocyte maturation prediction, ultimately improving the success rates of IVF-ET, and enhancing the chances of achieving a healthy pregnancy.
Ovarian reserve and patient characteristics
The ovarian reserve, which refers to both the quantity and quality of remaining oocytes within the ovaries, plays a critical role in determining the success of oocyte maturation during IVF-ET. Both normal and abnormal ovarian reserve can influence the outcome of the procedure. In individuals with a normal ovarian reserve, ovaries typically respond favorably to COH, resulting in the recruitment of multiple follicles and the production of mature oocytes [10]. However, variations in ovarian reserve and patient characteristics can still influence oocyte maturation even within this group [11]. Conversely, patients with abnormal ovarian reserves, such as diminished ovarian reserve (DOR) or polycystic ovarian syndrome (PCOS), face distinct challenges in achieving optimal oocyte maturation [12, 13]. In cases of DOR, the ovarian response to COH may be suboptimal, leading to fewer retrieved oocytes and an increased risk of encountering immature oocytes. Nevertheless, excessive follicular recruitment may occur, potentially compromising oocyte quality and maturity in PCOS patients [14]. Patient characteristics, encompassing age, body mass index (BMI), hormonal profiles, and medical history, also exert significant influence on oocyte maturation during IVF-ET (Table 1) [15,16,17,18,19,20,21,22]. Advanced maternal age is a well-established risk factor for poor IVF outcomes, including reduced oocyte maturity. Scantamburlo et al. [23] found that older age was associated with a lower number of mature oocytes retrieved and poorer IVF outcomes, including higher miscarriage rates. Several studies have investigated the impact of BMI on oocyte maturation and IVF outcomes [17, 24,25,26,27]. Amiri et al. [28] reported that higher BMI was linked to poorer oocyte quality and lower maturation rates, potentially because of hormonal imbalances and other metabolic factors associated with obesity.
Predictive indicators and methods
Single indicators
Studies have explored the use of various single indicators to predict oocyte maturation during IVF-ET, which can be broadly categorized into hormone levels, ultrasound parameters, and other clinical parameters. The assessment of female hormone levels, such as estradiol (E2), progesterone, and anti-Müllerian hormone (AMH), has been extensively studied as a potential predictor of oocyte maturation. Taheri and Vaughan have demonstrated a positive correlation between higher estradiol levels on the day of the human chorionic gonadotropin (hCG) trigger and an increased number of mature oocytes retrieved [29, 30]. The estradiol/follicle ratio has been proposed as a promising indicator, with the ratio between 250 and 750 pmol/L/oocyte associated with improved oocyte maturation rates and IVF outcomes acrossing the different protocol [30]. Yang et al. [31] demonstrated that patients on the flare GnRH-agonist protocol with elevated estradiol to oocyte ratios (EOR) had lower pregnancy and implantation rates. In contrast, Orvieto et al. [32] found that while EOR does not predict the success of a GnRH-agonist protocol, an EOR range of 100–200 pg/mL in patients on a GnRH-antagonist protocol provides the best chance for a positive outcome.
While progesterone is essential for successful implantation and pregnancy maintenance, Huang et al. [33] suggested that elevated progesterone levels before the hCG trigger have been linked to suboptimal oocyte maturity and compromised IVF outcomes, and the cutoff of progesterone was 2.0 ng/ml for patients receiving long GnRH agonist protocol. High progesterone levels before the hCG trigger can interfere with the normal progression of oocyte nuclear and cytoplasmic maturation, leading to the production of immature or dysmature oocytes. Consequently, elevated progesterone levels during this critical period have been associated with lower proportions of mature oocytes retrieved, lower fertilization rates, and lower-quality embryos, ultimately compromising IVF success rates. Woo et al. [34] and Zhao et al. [35] have reported a negative correlation between elevated progesterone levels on the day of the hCG trigger and oocyte maturation rates, further supporting the potential adverse effects of premature progesterone elevation on oocyte quality. However, the threshold for defining elevated progesterone levels and its impact on oocyte maturity remains a subject of ongoing research [33]. AMH has emerged as a valuable marker of ovarian reserve and oocyte quality, which is produced by the granulosa cells of preantral and small antral follicles. Studies have demonstrated a positive association between higher AMH levels and an increased number of mature oocytes retrieved [16, 36,37,38]. Moreover, lower AMH levels have been associated with a reduced likelihood of live birth following IVF-ET [39, 40].
Ultrasound parameters, such as follicle size and endometrial thickness, have also been investigated as potential predictors of oocyte maturation [41, 42]. Silverberg et al. [43] reported that larger follicle size on the day of the hCG trigger was associated with a higher proportion of mature oocytes retrieved. Similarly, Correia et al. [26] found that incorporating follicle size into a predictive model improved the accuracy of determining the optimal timing for final oocyte maturation. Additionally, endometrial thickness has been explored as a potential predictor of oocyte maturity and IVF outcomes. Lv et al. [44] demonstrated that optimal endometrial thickness on the day of the hCG trigger was correlated with higher oocyte maturity rates and improved live birth rates following IVF-ET. However, the optimal endometrial thickness cut-off values may vary across different patient populations and require further investigation [45]. The ovarian response to COH has been studied as a potential indicator of oocyte maturation. Cortés-Vazquez et al. [27] reported that patients with a higher ovarian response to stimulation, as measured by the number of follicles developed, tended to have a higher number of mature oocytes retrieved. However, excessive ovarian response may also be associated with compromised oocyte quality and maturity [46]. Table 2 summarizes some other key studies investigating the predictive value of these single indicators with the suggested cut-off values. It is important to note that the optimal cut-off values or ranges may vary across different patient populations, stimulation protocols, and clinical settings. Therefore, these cut-off values should be interpreted with caution, and that they may need to be adjusted or validated for specific patient populations or clinical contexts.
Combined indicators
Recognizing the limitations of relying solely on single indicators, researchers have increasingly explored the utility of combining multiple indicators to enhance the accuracy of predicting oocyte maturation [4, 24, 31, 47,48,49]. By integrating various hormonal, ultrasound, and clinical parameters, these combined indicators aim to provide a more comprehensive assessment and improve the predictive power.
One promising approach is to combine hormonal indicators. A study by Barroso et al. [51] evaluated a combination of AMH, FSH, and E2 levels for predicting oocyte maturation rates in women undergoing IVF. The authors found that this combined hormonal panel outperformed any single hormone indicator, achieving a higher predictive accuracy for both the number of mature oocytes retrieved and fertilization rates. Permadi et al. [52] evaluated a combined indicator comprising AMH and antral follicle count (AFC) in a short protocol. They found a strong positive correlation between the antral follicle count (AFC) and the number of oocytes retrieved, with AFC being the best predictor, followed by the combination of AMH and AFC, and then AMH alone. This contrasts with findings by Nelson et al. [51], who reported that AMH was the best predictor of outcomes, followed by the AMH-AFC combination and AFC alone. Moreover, the results align with those of Jayaprakasan et al. [53] and Liao et al. [54], who also found that AFC is a better predictor of ovarian response and clinical pregnancy rates compared to AMH or the combination of AFC and AMH. This suggests that AFC may be a more reliable indicator of ovarian reserve in women without discordant ovarian markers.
In addition to hormonal indicators, ultrasound parameters have been incorporated into combined assessment tools. These parameters provide valuable information about ovarian reserve, follicular development, and endometrial receptivity, all of which can influence oocyte maturation and IVF outcomes. A study by Chen et al. [55] investigated the morphology and perifollicular blood flow (PFBF) indicators of follicles on the hCG injection day during IVF cycles. They found that larger follicle diameters correlated with increased peak systolic velocity and decreased resistance index. Additionally, follicle size was positively associated with oocyte maturation, fertilization, and cleavage rates, though the largest follicles showed a significant drop in normal fertilization rates and high-quality embryos compared to mature follicles. Liang et al. [56] developed a multivariate classifiers-based follicle volume biomarker using 3D ultrasound to better predict oocyte maturity and optimize hCG administration timing in IVF. Their method outperformed conventional 2D ultrasound measurements and improved accuracy in predicting ovarian hyper-response.
Furthermore, researchers have explored the integration of clinical factors, such as age, BMI, and ovarian response to stimulation, with hormonal and ultrasound parameters. These factors can influence ovarian reserve, ovarian response, and oocyte quality, making them relevant for predicting oocyte maturation. Agarwal et al. [57] conducted a prospective study demonstrating that serum levels of LH, FSH, and progesterone (P4) 12 h after a GnRHa trigger are predictive of oocyte maturity. They found that lower levels of LH and P4 were significantly associated with reduced oocyte maturity, fertilization rates, and grade 1 embryos. Nevertheless, the development and validation of these combined indicator tools require careful statistical analysis, consideration of potential confounding factors, and external validation across diverse patient populations. Ongoing research efforts are focused on refining these integrated approaches, exploring new indicator combinations, and evaluating their clinical utility in predicting oocyte maturation and optimizing IVF outcomes.
Predictive models
Building upon the concept of combined indicators, researchers have developed various predictive models and algorithms to assess oocyte maturity during IVF-ET [58,59,60,61,62,63,64]. These models leverage advanced statistical techniques, machine learning algorithms, or artificial intelligence to integrate multiple parameters and identify patterns that can accurately predict oocyte maturation rates. While predictive models offer a more sophisticated and data-driven approach, their performance can vary depending on the specific parameters included, the modeling techniques employed, and the characteristics of the study population. It is crucial to evaluate the strengths and limitations of these models, considering factors such as generalizability, reproducibility, and clinical applicability.
In a study by Enatsu et al. [58], a predictive model was developed using a random forest algorithm, incorporating age, AMH, AFC, BMI, FSH, E2, hCG dose, and COH duration. This model achieved an AUC of 0.81 for predicting oocyte maturation rates and 0.75 for predicting live birth rates, highlighting the potential of combining multiple parameters. Fu et al. [60] employed a gradient boosting decision tree model to predict oocyte maturation rates. The model included age, AMH, AFC, BMI, FSH, LH, E2, progesterone, follicle size, and endometrial thickness. With an AUC of 0.85, this combined model demonstrated superior predictive performance compared to individual indicators. Recently, Hanassab et al. [61] proposed a combined indicator comprising age, AMH, AFC, BMI, FSH, E2, and follicle size for predicting oocyte maturation rates. This combined indicator achieved an AUC of 0.79, outperforming individual parameters and highlighting the utility of integrating multiple factors. Vogiatzi et al. [64] developed an artificial neural network model for predicting oocyte maturation rates, incorporating age, AMH, AFC, BMI, FSH, LH, E2, progesterone, follicle size, endometrial thickness, and COH duration. This model achieved an impressive AUC of 0.88 in a multicenter study, showcasing the potential of advanced machine learning techniques in combination with multiple parameters.
Reuvenny et al. [63] utilized data from 9622 cycles between 2018 and 2022, and an XGBoost algorithm suggested trigger days based on MII oocyte predictions, prediction errors, and outlier detection results. Evaluation involved a test dataset with three quality groups, comparing suggested trigger days with actual physician choices. Results demonstrated significant increases in oocyte and MII oocyte numbers across all quality groups, indicating the potential for improved cycle outcomes. Implementing such models could enhance decision-making, workload balance, and protocol standardization while catering to individual patient needs. Ferrand et al. [59] built the machine-learning models to predict the number of oocytes retrieved from COH through a dataset of 11,286 cycles. The result showed key factors influencing predictions included antral follicle count, basal AMH, and FSH levels. They also highlighted the potential of utilizing secure frameworks like Substra for analyzing sensitive fertility data. Houri et al. [62] developed a machine learning XGBoost algorithms for predicting oocyte maturation rates in a retrospective study. The model incorporated peak estradiol level on trigger day, estradiol level on antagonist initiation day, average gonadotropin dose per day, and progesterone level on trigger day, achieving a 75% accuracy rate in predicting high oocyte maturation rates.
Strengths of these predictive models include their ability to integrate complex datasets, identify intricate patterns, and potentially predict oocyte maturity rates with higher accuracy compared to traditional approaches. Additionally, some models, such as the artificial neural network, can effectively handle nonlinear relationships and complex interactions among multiple variables [64]. However, limitations and challenges associated with these predictive models should also be considered. Their performance heavily depends on the quality and representativeness of the training data, as well as the model’s ability to generalize to diverse patient populations [60]. Overfitting, where the model performs well on the training data but fails to generalize to new data, is a common issue that needs to be addressed through appropriate validation and regularization techniques.
Furthermore, the interpretability and transparency of some complex models, such as deep learning algorithms, can be a challenge, making it difficult to understand the underlying decision-making process. This can raise concerns regarding the clinical applicability and acceptance of these models by healthcare professionals and patients [64]. Ongoing research efforts are focused on addressing these limitations, exploring new modeling techniques, and validating the performance of these predictive models across multiple clinical settings. Additionally, the integration of emerging technologies, such as proteomics, metabolomics, and genomics, may further enhance the predictive power of these models by providing additional insights into the underlying biological processes influencing oocyte maturation [65]. Besides the traditional clinical or COH period-based parameters, Fjeldstad et al. [66] conducted a study to develop a deep learning image analysis model aimed at assessing oocyte quality by predicting blastocyst development from images of denuded mature oocytes. Utilizing 37,133 static oocyte images from eight fertility clinics across six countries, the model achieved an AUC of 0.64, balanced accuracy of 0.60, specificity of 0.55, and sensitivity of 0.65 on the test dataset, with the highest performance observed in the age group 38–39 years. This research complements other predictive models based on clinical and COH parameters, offering a novel approach through image-based analysis. Table 3 summarizes studies that have explored combined indicators and predictive models for assessing oocyte maturation.
COH and trigger time
The process of COH involves the administration of exogenous hormones to stimulate the ovaries, promoting the recruitment and growth of multiple follicles simultaneously [67]. Different COH protocols are employed, each with its own advantages and considerations. Some commonly used protocols include the following: (a) GnRH agonist long protocol involves initial downregulation of the pituitary gland using a GnRH agonist, followed by ovarian stimulation with gonadotropins. The downregulation prevents premature ovulation and allows for better control over follicular development. (b) While a GnRH antagonist protocol is introduced during the late follicular phase to prevent premature ovulation without prior downregulation, which can shorten the duration of treatment and reduce the risk of ovarian hyperstimulation syndrome (OHSS) [68]. (c) Moreover, short protocol involves starting gonadotropin stimulation in the early follicular phase without prior downregulation, which can be advantageous for patients with a poor ovarian reserve or those who do not respond well to the long protocol [69]. (d) Mild stimulation protocols aim to minimize the risk of OHSS by using lower doses of gonadotropins or alternative medications, such as clomiphene citrate or letrozole. Mild stimulation can be beneficial for patients with a high risk of OHSS or those who prefer a less intensive treatment regimen [70].
In addition to COH, selecting the optimal time for triggering ovulation is another critical factor in maximizing oocyte maturity rates. The trigger time refers to the precise moment when final oocyte maturation is induced, typically through the administration of hCG or a synthetic analog, such as a GnRH agonist [71]. Accurate timing of the trigger is essential, as premature triggering can lead to the retrieval of immature oocytes, while delayed triggering may result in ovulation occurring before the oocyte retrieval procedure, compromising IVF outcomes [72]. The selection of the appropriate trigger time is a delicate balance, as it needs to account for individual patient characteristics, ovarian response to stimulation, and the specific COH protocol employed [50]. Furthermore, the choice of trigger agent (hCG or GnRH agonist) can also influence oocyte maturation rates and IVF outcomes [73]. The hCG trigger has traditionally been used to induce final oocyte maturation by mimicking the natural LH surge and supporting luteal phase function; however, it carries a higher risk of OHSS, especially in high responders. Alternatively, the GnRH agonist trigger induces an endogenous LH surge by stimulating the pituitary gland, significantly reducing the risk of OHSS but potentially requiring intensive luteal phase support due to a shorter duration of the LH surge.
The maturation of oocytes is a complex process influenced by various physiological and genetic factors [74]. During the follicular phase, the growing follicles produce estradiol, which plays a key role in preparing the oocyte and the endometrium for potential implantation. The LH surge induced by the trigger completes the oocyte maturation process, leading to resumption of meiosis and subsequent oocyte release. Genetic factors also play a critical role in oocyte quality and maturation [75]. Variations in genes related to folliculogenesis, hormone receptors, and oocyte metabolism can affect an individual’s response to stimulation and overall IVF outcomes. Personalized approaches to COH and trigger timing, considering both physiological and genetic factors, are essential for optimizing success rates.
Limitations
Despite the advancements in predictive approaches, several gaps and limitations persist in the existing literature and methods. Firstly, many studies have been conducted in single-center settings or on specific patient populations, which may limit the generalizability of their findings to broader contexts. Secondly, the use of varying definitions, protocols, and methodologies across studies can make it challenging to compare and synthesize results effectively. Moreover, some predictive models have shown promising results within their respective study populations, and there is a need for more extensive external validation to ensure their robustness and clinical applicability across diverse settings. Finally, the integration of emerging technologies, such as proteomics, metabolomics, and genomics, may provide additional insights and improve the accuracy of oocyte maturation prediction.
Future directions and recommendations
Based on the findings, several potential areas for further investigation and development can be considered. Initially, further research is needed to investigate the impact of patient-specific factors, such as genetics, lifestyle, and environmental exposures, on oocyte maturation and incorporate these factors into predictive models. Based on these considerations, conducting large-scale, multicenter studies with standardized protocols and diverse patient populations would enhance the generalizability and robustness of predictive models and indicators. Following this, integration of advanced omics technologies: incorporating data from emerging technologies, such as proteomics, metabolomics, and genomics, into predictive models could provide deeper insights into the molecular mechanisms underlying oocyte maturation and potentially improve prediction accuracy. Subsequently, exploring the integration of patient-specific factors would be an appropriate way to improve the evaluation ability, including genetics, lifestyle, and environmental exposures, into predictive models which may lead to more personalized and tailored approaches for oocyte maturation prediction.
Conclusion
Accurately predicting oocyte maturation is essential for the success of IVF-ET procedures. Combining multiple indicators and leveraging advanced predictive models can enhance accuracy, but overcoming existing challenges through standardization and the integration of multidisciplinary approaches remains critical for further advancements.
Availability of data and materials
Not applicable.
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This study was granted by Zigong Key Scientific and Technology Project (2021YLSF25, 2023-YGY-1–01, 2022ZCYGY06, 2022ZCYGY01), Natural Science Foundation of Sichuan (2022NSFSC1287), and Zigong Heath Commission Science Project (21YB067, 22YB060).
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LNH, conceptualization, writing — original draft, writing — review and editing, and supervision; QX, investigation and writing — review and editing; JL, resources, data curation, and writing — review and editing; YL, investigation and review and editing; and WC, supervision, review, editing, and project administration. All authors read and approved the final manuscript.
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He, LN., Xu, Q., Lin, J. et al. Predictive strategies for oocyte maturation in IVF cycles: from single indicators to integrated models. Middle East Fertil Soc J 29, 33 (2024). https://doi.org/10.1186/s43043-024-00193-7
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DOI: https://doi.org/10.1186/s43043-024-00193-7