Cervical cancer remains a major global public health challenge, with approximately 640,000 new cases and 350,000 deaths reported worldwide in 2022, ranking as the fourth most common malignancy among women. The disease burden is disproportionately concentrated in low Human Development Index (HDI) regions, where limited access to human papillomavirus (HPV) vaccination, screening, and early treatment continues to drive high incidence and mortality rates. Epidemiological projections based on Bayesian age-period-cohort models estimate that cervical cancer incidence may increase by more than 50% by 2050 if current prevention strategies are not substantially strengthened. Persistent infection with high-risk human papillomavirus (hrHPV), particularly HPV-16 and HPV-18, represents the central initiating event in cervical carcinogenesis, primarily through the oncogenic activities of the viral E6 and E7 proteins, which inactivate p53 and pRb, respectively, thereby promoting genomic instability and immune evasion. Population-level data demonstrate marked reductions in cervical intraepithelial neoplasia grade 3 (CIN3) and invasive cancer among women vaccinated prior to sexual debut, reinforcing the largely preventable nature of this malignancy. Nevertheless, several cofactors, including tobacco exposure, long-term hormonal contraception, HIV-associated immunosuppression, and alterations in the cervicovaginal microenvironment, modulate the progression from HPV infection to invasive disease (1–3).

Although vaccination has proven highly effective, global HPV vaccine coverage remains alarmingly low. A recent systematic review encompassing 148 national immunization programs reported that, as of 2023, only 27% of girls worldwide had received at least one vaccine dose, and merely 20% had completed the full vaccination schedule, well below the 90% coverage target established by the World Health Organization for 2030. Moreover, the occurrence of breakthrough infections and persistent hrHPV carriage in vaccinated and unvaccinated populations underscores the need to identify additional biological determinants of viral persistence and malignant transformation. In this context, the cervicovaginal microbiome has emerged as a clinically relevant modulator of cervical cancer risk. Recent multi-omics and longitudinal cohort studies position the cervicovaginal microbiome as a functional axis interacting with HPV exposure and host genetics, influencing epithelial barrier integrity, innate immune activation, inflammatory tone, and local metabolite production (4–6). The magnitude and direction of these interactions differ across ethnic groups, hormonal states, and environmental settings. Similar microbial configurations may therefore exert distinct biological effects depending on host susceptibility and baseline immune tone. Framing microbiome-host interactions as gradients of risk rather than fixed causal pathways more accurately reflects current evidence (7, 8). Incorporating microbiome-derived biomarkers into cervical cancer prevention frameworks therefore represents a promising opportunity to enhance risk stratification and public health impact Importantly, while early studies were largely cross-sectional, recent longitudinal cohorts indicate that baseline cervicovaginal microbiome states precede and predict HPV persistence and disease progression, supporting temporal precedence as a prerequisite for causal inference (9–11).

Beyond static compositional changes, temporal regulation of host-microbiota interactions has gained attention as an additional layer of biological complexity in cervical carcinogenesis. Circadian misalignment, driven by irregular light exposure, sleep disruption, or altered feeding rhythms, has been shown to perturb microbial oscillatory behavior, leading to dysbiosis, immune desynchronization, and sustained low-grade inflammation. Approximately 10–15% of microbial taxa, including Lactobacillus and Bacteroides species, exhibit time-of-day dependent fluctuations in abundance and transcriptional activity, with downstream effects on metabolite production such as short-chain fatty acids and bile acids. Disruption of these rhythmic outputs compromises epithelial defense mechanisms and amplifies pro-inflammatory signaling pathways, processes increasingly recognized as contributors to HPV persistence and neoplastic progression within the cervicovaginal niche (12, 13).

Parallel advances in cancer biology further highlight the bidirectional interplay between microbial ecosystems and tumor progression (14). Tumor-derived extracellular vesicles have been shown to condition local and distant microenvironments by altering vascular permeability, immune cell recruitment, and stromal remodeling in an organ-specific manner. Importantly, several of these processes appear to be temporally regulated and synchronized with host circadian and immune rhythms. Although most evidence derives from solid tumors outside the cervix, these findings provide a mechanistic framework to explore how immune desynchronization and microbial dysbiosis may cooperate to facilitate HPV-driven cervical carcinogenesis (15).

High-resolution multi-omics studies increasingly portray the microbiome as an active regulator of tumor biology rather than a passive bystander. In the gastrointestinal tract, commensal taxa such as Akkermansia muciniphila, Faecalibacterium prausnitzii, and selected Bifidobacterium species enhance dendritic cell priming and CD8⁺ T-cell activation, correlating with improved responses to immune checkpoint inhibitors. Conversely, antibiotic-induced dysbiosis impairs therapeutic efficacy and promotes immune dysfunction. Microbial metabolites, including indole derivatives and short-chain fatty acids, modulate oxidative stress responses and influence sensitivity to chemotherapy in preclinical models. Beyond the gut, viable bacteria and fungi have been detected within tumor tissues across multiple cancer types, where they reshape metabolic fluxes, immune surveillance, and therapeutic response. Early-phase clinical trials of fecal microbiota transplantation (FMT) further support the translational relevance of microbiome modulation, although heterogeneity in outcomes highlights the need for precision-based approaches integrating microbial function, host immunity, and genetic context (16–18).

Building on this broader multi-omics framework, recent large-scale metagenomic and multi-center immunotherapy studies further reinforce the functional relevance of the microbiome in cancer progression and treatment response. In particular, a conserved gut microbial signature enriched in Akkermansia, Faecalibacterium, and Bifidobacterium species has been associated with improved outcomes to PD-1 and combined PD-1/CTLA-4 blockade across multiple solid tumor types, including melanoma and lung cancer (19). Antibiotic-induced disruption of these communities correlates with impaired antitumor immunity and therapeutic resistance. Complementing these observations, intratumoral microbiota have emerged as active modulators of tumor metabolism, immune surveillance, and drug response, with bacteria detected intracellularly within cancer cells and immune compartments. Although preclinical FMT studies demonstrate reproducible restoration of immunotherapy efficacy, early clinical trials and meta-analyses reveal substantial inter-patient heterogeneity and unresolved safety concerns, underscoring the current translational limitations of microbiome-based interventions in oncology (20, 21).

Within this broader oncological landscape, the cervicovaginal tract constitutes the primary ecological niche for HPV acquisition, persistence, and malignant progression. In many individuals, Lactobacillus crispatus-dominant communities are commonly associated with a low-pH, lactic acid-rich environment that restricts viral replication and supports mucosal immune homeostasis; however, stable and asymptomatic cervicovaginal ecosystems can also occur under alternative microbial configurations depending on host factors and functional outputs rather than taxonomic dominance alone. In contrast, shifts toward anaerobe-dominated community state types, characterized by taxa such as Gardnerella, Prevotella, and Sneathia, are consistently associated with increased risk of persistent hrHPV infection, high-grade cervical lesions, and invasive cancer. Metagenomic and metabolomic studies supporting an emerging model in which dysbiosis-associated metabolites may influence epithelial integrity, interferon signaling, and epigenetic regulation, potentially intersecting with HPV oncogene–driven pathways. These insights have stimulated interest in microbiome-informed diagnostics and early interventions aimed at restoring microbial equilibrium and enhancing viral clearance (22–24).

Longitudinal and integrative studies further demonstrate that baseline microbiome configurations predict subsequent HPV clearance or persistence over time, providing evidence for temporal directionality rather than static association. Women harboring Lactobacillus-dominated communities exhibit enhanced antiviral immunity and higher rates of viral clearance, whereas anaerobe-enriched dysbiotic states are consistently associated with immune dysfunction, sustained inflammation, and increased risk of lesion progression. Metagenomic and metatranscriptomic analyses reveal that HPV infection itself can reshape microbial gene expression and metabolic output, reinforcing a bidirectional feedback loop between viral oncogenesis and microbial dysbiosis. Supporting evidence from other mucosal sites, including the oral cavity, further suggests that HPV-associated microbial alterations may represent a conserved host–microbe interaction pattern across epithelial tissues, providing comparative insight into HPV-driven carcinogenesis beyond the cervix (25–27). However, whether these conserved patterns reflect shared causal mechanisms or parallel dysbiotic responses remains to be established.

Nevertheless, establishing causality in human microbiome research remains inherently challenging, given the dynamic and context-dependent nature of microbial ecosystems. Despite rapid advances in cervicovaginal microbiome research, several limitations constrain current interpretation and clinical translation. Most available studies are cross-sectional, limiting causal inference between microbial dysbiosis and cervical carcinogenesis. Methodological heterogeneity, including variability in sampling procedures, sequencing strategies (16S rRNA versus shotgun metagenomics), bioinformatic pipelines, and cohort composition, complicates cross-study comparisons. The low-biomass nature of cervicovaginal samples further increases susceptibility to contamination and technical bias, particularly in tumor-adjacent tissues. In addition, populations from low-resource settings, where cervical cancer burden is highest, remain underrepresented in existing datasets (28–30). This review therefore aims to critically synthesize mechanistic, multi-omics, and translational evidence while explicitly acknowledging current gaps, with the goal of identifying robust biological signals and guiding future microbiome-informed strategies for cervical cancer prevention and management. Accordingly, while accumulating longitudinal, mechanistic, and interventional evidence supports a contributory causal role of the cervicovaginal microbiome, definitive causality will require large-scale prospective studies with repeated sampling and controlled microbiome-targeted interventions (Figure 1).

Several cross-sectional and metagenomic studies identify microbiome-derived signatures as potential non-invasive biomarkers for early detection and risk stratification. Distinct bacterial taxa, microbial genetic variants, and metabolite patterns have been shown to correlate with the continuum from HPV infection to CIN and invasive carcinoma. For example, a cross-sectional 16S rRNA V3 analysis of vaginal swabs reported positive associations of Lactobacillus iners, Streptococcus agalactiae, and Streptococcus anginosus with increasing lesion severity (117). Similarly, L. iners, Prevotella bivia, and other commensals were linked to enhanced HPV acquisition, persistence, and progression to CIN in integrated microbial-metabolomic studies (118). Elevated abundance of Sneathia sanguinegens, Anaerococcus tetradius, and Peptostreptococcus anaerobius, alongside depletion of L. jensenii, has also been consistently observed in high-grade CIN and cervical cancer. Notably, Sneathia species appear as robust metagenomic markers enriched across all carcinogenic stages (119–121).

Whole-genome metagenomic sequencing has further refined the diagnostic potential of microbial signatures. In one cohort, women with cervical lesions displayed reduced Lactobacillus spp., while Bifidobacteriaceae breve, Atopobium vaginae, and low-abundance L. crispatus were associated with higher risk of preinvasive lesions and cancer. The same study identified distinct single nucleotide variation (SNV) patterns that differentiated HPV infection, preinvasive lesions, and invasive carcinoma, with SNV-based biomarkers outperforming species-level markers (AUC = 0.87 vs. 0.78) (122).

Integration of microbiome data with immune and metabolic mediators adds further prognostic granularity. A cross-sectional study demonstrated that proinflammatory cytokines (IL-6, TNFα, TRAIL), apoptotic mediators (sFas, sFasL), and angiogenic factors (FGF2, HGF, VEGF) correlated positively with cervical cancer but inversely with low-diversity vaginal microbiota. Vaginal pH and H₂O₂, key modulators of microbial beta diversity, were also associated with dysplasia and cancer progression. Multi-omic integration identified three patient clusters, cancer-associated, high-diversity/inflammation, and low-diversity/inflammation, highlighting distinct molecular trajectories of cervical carcinogenesis (123, 124). Importantly, biomarker performance frequently declines when models trained in one population are applied to geographically or ethnically distinct cohorts. Baseline microbiome structure, host genetic background, and environmental exposures modify both interaction strength and predictive accuracy. External validation across diverse settings remains essential before clinical implementation (125, 126).

Metabolomic profiling strengthens this diagnostic framework. Lesion progression has been associated with enrichment of Atopobium and Sneathia, reduction in Lactobacillus and Streptococcus, and accumulation of metabolites such as N-methylalanine, phenylacetaldehyde, succinic acid, and glucose-6-phosphate (99). Additional studies have identified ceramides and sphingomyelins as hallmarks of high-grade lesions (127) and discriminative metabolites such as 3-hydroxybutyrate, eicosenoate, and oleate-vaccenate, which distinguish cervical cancer from healthy controls with high accuracy (AUC = 0.90) (128).

Machine-learning approaches add predictive power. A random forest model identified 33 optimal bacterial predictors, with L. iners emerging as the most discriminative taxon (AUC = 0.952) (117). These findings are supported by a systematic review (129) and multiple cross-sectional analyses (118), which consistently associate L. iners with CIN2/3 risk. Furthermore, SNV-based analyses highlight specific mutational patterns (e.g., higher C > A, C > G, and T > G substitutions in preinvasive lesions vs. distinct profiles in carcinoma), reinforcing their utility for malignant risk stratification (122).

Despite strong evidence, several barriers limit clinical translation. The cervicovaginal microbiome is dynamic, influenced by hormones, diet, hygiene, and lifestyle, while geographic and demographic variability complicates biomarker generalization (121, 130). Current sequencing and analytic platforms lack sufficient sensitivity, and reproducibility is often compromised by sampling and bioinformatic variability (124). Current research focuses on (i) validating biomarkers across diverse cohorts, (ii) elucidating gut-cervical metabolic crosstalk, (iii) spatially mapping microbial intratumoral niches associated with immune escape and therapy resistance, and (iv) developing standardized, cost-effective pipelines suitable for clinical implementation, emphasizing cross-compartment, function-oriented analyses that integrate metabolic and immune readouts under rigorous contamination control to capture axis-level microbiome effects relevant to cervical cancer (131–133).

Probiotic interventions designed to restore microbial equilibrium are gaining increasing recognition as potential adjunctive measures in cervical cancer prevention. By re-establishing a Lactobacillus-dominated vaginal environment, such approaches may facilitate HPV clearance and counteract pro-tumorigenic dysbiosis. In a prospective pilot study, Verhoeven et al. reported that oral probiotic supplementation significantly enhanced HPV clearance rates (60% vs. 31% in controls) (134). Similarly, a randomized clinical trial using intravaginal Lactobacillus rhamnosus BMX54 documented HPV elimination in 31.2% of participants (135), while a recent pilot study employing intravaginal Lactobacillus crispatus demonstrated a notable reduction in viral load (136). Beyond viral clearance, preclinical models suggest that Lactobacilli possess direct antitumoral properties, including the induction of apoptosis, suppression of HPV E6/E7 oncogenes, and inhibition of pro-inflammatory pathways (137, 138). Nevertheless, the absence of large, randomized trials and safety concerns in immunocompromised women undergoing cancer therapy currently preclude their routine clinical application.

Ecological resistance may partially explain inconsistent engraftment of exogenous probiotics in dysbiotic cervicovaginal ecosystems. Established anaerobic consortia occupy metabolic niches and form biofilm-protected networks that resist recolonization by beneficial Lactobacillus strains. Effective therapeutic strategies must therefore consider disruption of existing interspecies cooperation and niche occupancy, not just supplementation, to shift community structure toward health-associated states. Integrating ecological principles into therapeutic design could improve prognostic power and intervention success in preventing HPV progression (139, 140).

Complementary findings from phase 2 and 3 clinical trials reinforce the translational potential of intravaginal probiotic and antimicrobial formulations. Intravaginal administration of Lactobacillus crispatus (Lactin-V) demonstrated significant protection against recurrent urogenital infections by maintaining high-level vaginal colonization and reducing relapse risk (141). Likewise, novel boric-acid–based antibiofilm agents, such as TOL-463, achieved high cure rates in bacterial vaginosis and vulvovaginal candidiasis while preserving protective Lactobacillus populations (142). A single-dose oral formulation of secnidazole further proved to be well-tolerated and effective in eradicating biofilm-associated anaerobes without compromising beneficial microbiota (143). Collectively, these data suggest that vaginal biofilm disruption and targeted microbial repletion can be safely combined to restore mucosal homeostasis and potentially enhance therapeutic outcomes in HPV-related neoplasia.

Parallel evidence highlights the potential of microbiome-modulating strategies to augment immunotherapy efficacy and mitigate treatment-related toxicities in oncology. A recent meta-analysis encompassing retrospective and prospective studies demonstrated that probiotics significantly improved both overall and progression-free survival in patients with non-small cell lung cancer, melanoma, and other solid tumors receiving immune checkpoint inhibitors (ICIs), particularly in antibiotic-exposed individuals (144, 145). Mechanistic data indicate that antibiotic exposure reduces the antitumor efficacy of anti-PD-L1 therapy in non-small cell lung cancer patients with high PD-L1 expression (146). Although ICIs are not yet standard in cervical cancer therapy, multiple ongoing clinical trials are assessing pembrolizumab in newly diagnosed or recurrent/metastatic disease (147). Emerging translational frameworks propose combining probiotic consortia or prebiotic substrates with ICIs to reshape systemic immunity and enhance checkpoint responsiveness (120). These trials underscore the possibility that microbiome modulation could enhance ICI responsiveness in cervical cancer as well.

Beyond probiotics, additional strategies aim to selectively target pro-tumorigenic microbial niches while sparing protective commensals. These include localized antimicrobials, engineered probiotics, and evidence-based prebiotic or dietary interventions, contingent on the identification of microbial “hotspots” that drive carcinogenic pathways (133). Prebiotic-based therapies are also emerging; for instance, Papilocare, a topical gel enriched with the prebiotic Bioecolia, has demonstrated efficacy in HPV-related cervical lesions, though further validation is warranted (148). Another promising frontier is microbiome editing, in which engineered microorganisms or derivatives such as bacterially derived antibodies are designed to selectively eliminate tumor cells (149). Current and experimental protocols also encompass biofilm disruptors, vaginally delivered Lactobacillus formulations, and next-generation antimicrobials that integrate precision delivery systems with host-compatible substrates (142, 143). While conceptually compelling, these approaches remain experimental and require rigorous translational evaluation before clinical adoption.

Vaginal microbiota transplantation (VMT) represents another innovative intervention, involving the transfer of vaginal fluid from healthy donors to individuals with vaginal dysbiosis. Early studies suggest that VMT can reconstitute a balanced microbial community (120), and an ongoing Phase I-II clinical trial is assessing its safety and efficacy (NCT04046900). Although VMT may theoretically shift the vaginal microbiota from an inflammatory to a protective state in HPV-positive or lesion-bearing patients, the approach remains investigational, with unresolved issues including donor screening, standardization of protocols, and potential risks such as pathogen transmission or long-term immune consequences (150). Recent reviews emphasize that the future of VMT will depend on integration with precision-profiling frameworks, where donor selection is guided by genomic and metabolomic compatibility (120).

Antibiotic interventions, though capable of altering both gut and vaginal microbiota composition, risk destabilizing protective microbial communities. Antibiotic treatment has been shown to reduce gut microbiota diversity, which, due to the interconnection between gut and vaginal microbiomes, may also disrupt vaginal homeostasis (151). The combined use of antibiotics and probiotics has thus been proposed as a way to modulate both ecosystems and potentially influence cervical lesion dynamics, though this remains experimental. Current guidance from the European Society of Gynaecological Oncology emphasizes the urgent need for mechanistic studies, while cautioning that available evidence does not yet support routine microbiota manipulation for cervical cancer prevention or therapy (152).

Importantly, probiotics may alleviate treatment-related complications such as diarrhea, oral mucositis, and infections, as shown in umbrella reviews of interventional trials (153). Yet, their use in immunocompromised populations remains tightly regulated by health authorities including the FDA, FAO/WHO, NMPA, ANVISA, and FSANZ. Advances in shotgun metagenomics have revealed functional alterations in the vaginal microbiome linked to persistent HPV infection and cervical dysplasia (154). Still, the clinical utility of microbiota modulation for preventing or regressing cervical lesions has not been established, and interactions with cofactors such as smoking, co-infections, hormonal contraception, and nutritional status must be carefully considered (155).

Microbiome-based interventions, including probiotics, prebiotics, microbiome editing, and vaginal microbiota transplantation, constitute a rapidly advancing field with strong translational potential in cervical cancer. However, regulatory barriers, limited mechanistic evidence, and unresolved safety concerns currently restrict their use to clinical research settings. Until large-scale data become available, implementation should remain within rigorously controlled clinical trials.

Current data indicate that the microbiome acts as a dynamic and context-dependent contributor that modulates carcinogenic trajectories rather than functioning as a standalone etiological factor. Studies have consistently shown that cervicovaginal dysbiosis, marked by depletion of Lactobacillus species and enrichment of anaerobic taxa such as Gardnerella, Atopobium, and Sneathia, promotes persistent HPV infection and progression to CIN and invasive carcinoma (89, 121, 152). These microbial alterations have been individually associated with chronic inflammation, oxidative stress, epithelial barrier disruption, and modulation of host immune responses. However, the sequencing, interaction strength, and causal hierarchy among these processes remain to be fully clarified (22, 30, 97). Crucially, cervicovaginal microbiome states should not be interpreted as binary healthy or pathogenic configurations. Protective or deleterious effects emerge from context-dependent interactions among microbial composition, metabolic activity, host immunity, hormonal milieu, and population-specific factors, rather than from Lactobacillus dominance alone (137, 156). Cervicovaginal microbiome configurations therefore shape risk in a probabilistic manner. Their biological impact depends on interaction strength, temporal stability, and host context, rather than on fixed taxonomic dominance alone (157–159).

Beyond descriptive associations, recent research has advanced toward mechanistic and translational understanding. The role of bacterial metabolites, particularly SCFAs such as butyrate, has gained prominence. Butyrate exerts tumor-suppressive properties by inhibiting cervical cancer cell proliferation, inducing apoptosis, and reshaping epigenetic regulation, positioning it as a metabolite of therapeutic interest (79). Likewise, microbiome-metabolome integration studies reveal correlations between cervicovaginal microbial profiles and altered host metabolites such as 9,10-DiHOME and glycocholic acid, which may serve as biomarkers for HPV persistence and early detection of cervical lesions. Circadian misalignment has also been linked to shifts in microbial taxa, including Lactobacillus and Bacteroides, whose rhythmic activity modulates epithelial defense and inflammatory tone, adding a temporal dimension to cervical carcinogenesis (30, 160). Leveraging microbiome-derived biomarkers enables more precise diagnostics and risk stratification.

Therapeutically, the modulation of the cervicovaginal microbiota emerges as a promising strategy. Probiotic and prebiotic interventions have demonstrated potential to restore Lactobacillus dominance, enhance HPV clearance, and reduce recurrence of cervical lesions (137, 152). Probiotic formulations such as oral and intravaginal Lactobacillus rhamnosus and Lactobacillus crispatus have increased HPV clearance and decreased viral load in clinical trials (134). These bacteria exhibit antitumoral activity by suppressing HPV E6/E7 oncogenes, inducing apoptosis, and reducing pro-inflammatory signaling (138). Complementary studies with Lactobacillus crispatus (Lactin-V) and antibiofilm agents like TOL-463 further demonstrate that microbial repletion coupled with biofilm disruption can safely restore vaginal homeostasis (141).

Emerging evidence also links microbiome modulation with improved cancer immunotherapy outcomes. Probiotics enhance survival in patients treated with immune checkpoint inhibitors (ICIs), mitigating the negative impact of antibiotics on anti–PD-L1 efficacy (145). Although ICIs are not yet standard in cervical cancer, ongoing pembrolizumab trials suggest potential synergy when combined with microbiome-based interventions (147). Other novel strategies, including prebiotic gels such as Papilocare, microbiome editing with engineered probiotics, and vaginal microbiota transplantation (VMT), offer innovative approaches to restore protective microbial communities (148). However, rigorous donor screening, long-term monitoring, and ethical frameworks are required before these therapies reach clinical application (120).

The intratumoral microbiome also represents an emerging dimension of investigation. Evidence indicates that microbial communities within cervical tumors may influence oncogene expression, immune evasion, and therapeutic response (89). Integration of intratumoral and cervicovaginal microbiome profiles could uncover novel microbial signatures predictive of prognosis and therapeutic outcomes. Additionally, cross-talk between the gut and genital tract microbiota has been recognized as a key axis in modulating estrogen metabolism, immune responses, and systemic inflammation, further linking distant microbial ecosystems to cervical cancer progression (22, 156, 161). Deciphering these interactions could inspire multi-level interventions targeting both local and systemic microbial networks.

From a clinical standpoint, the potential of microbiome-based diagnostics and therapeutics aligns with the broader agenda of precision oncology. Predictive models built on microbiome profiles demonstrate high discriminatory power for distinguishing healthy, HPV-infected, CIN, and invasive cancer states (22, 79, 120). These tools, if validated in multi-ethnic and geographically diverse cohorts, could significantly improve screening programs, particularly in low-resource settings where cervical cancer burden remains disproportionately high (30, 137). Embedding microbiome markers within existing HPV screening frameworks may refine triage, reduce overtreatment, and optimize resource allocation, especially where vaccination remains suboptimal.

Looking ahead, several challenges and opportunities shape future research. Methodological standardization is essential, as heterogeneity in sampling, sequencing, and data analysis hinders comparability among studies (22, 97). Longitudinal designs and harmonized protocols are needed to capture dynamic microbiome shifts during disease progression and therapy. Multi-omics integration, encompassing metagenomics, metabolomics, transcriptomics, and immunogenomics, will be key to disentangling host-microbe-metabolite networks underlying cervical oncogenesis (30, 79). Beyond technical considerations, the clinical translation of microbiome-based interventions raises important ethical and regulatory challenges. Robust governance frameworks will be required to ensure the safety, efficacy, and long-term monitoring of emerging strategies such as FMT and rationally engineered microbial consortia, while also addressing issues of standardization, patient stratification, and equitable access across healthcare systems (120, 162).