1,25(OH)₂D₃ plays a pivotal role in orchestrating innate immune responses, enhancing antimicrobial defense while preventing excessive inflammatory reactions that could lead to tissue damage (Table 1). Its typical mechanism involves VDR-mediated transcriptional activation of the Cathelicidin Antimicrobial Peptide (CAMP) gene, inducing the production of antimicrobial peptides, particularly cathelicidin LL-37 (28). Additionally, 1,25(OH)₂D₃ induces expression of nucleotide-binding oligomerization domain 2 (NOD2), which upon activation by bacterial muramyl dipeptide stimulates NF-κB signaling and subsequently induces human β-defensin 2 (DEFB2/HBD2) expression, establishing Vitamin D₃ as both a direct and indirect regulator of antimicrobial peptide production (29, 30). 1,25(OH)₂D₃ modulates the phenotype and function of monocyte and macrophage through multiple mechanisms: suppressing pro-inflammatory cytokine expression, including tumor necrosis factor (TNF)-α, interleukin (IL)-1β, IL-6, upregulating negative regulators such as mitogen-activated protein kinase (MAPK) phosphatase-1 (31), and modulating microRNA expression profiles (32). Notably, Vitamin D₃ promotes the anti-inflammatory M2-like macrophage polarization through Peroxisome Proliferator−Activated Receptor γ (PPAR γ) signaling pathways (33) (Figure 1C). In dendritic cells, 1,25(OH)₂D₃ inhibits maturation processes and arrests developmental progression while inducing tolerogenic phenotypic characteristics (Figure 1D). This manifests specifically as downregulation of major histocompatibility complex class II molecules (MHC-II) and costimulatory molecules (CD40, CD80, CD86) (34), enhanced IL-10 secretion, and upregulation of inhibitory molecules including Programmed Death-Ligand 1(PD-L1) (35). Furthermore, Vitamin D₃ attenuates natural killer cell(NK cell) activity, effectively suppressing IFN-γ production while reducing both cytotoxicity and lytic function (36) (Figure 1G). Clinical studies and in vitro experiments demonstrate that Vitamin D₃ supplementation increases antimicrobial peptide expression in peripheral blood mononuclear cells (PBMCs) (37) and reduces susceptibility to respiratory infections (38), though the magnitude of effect varies considerably with baseline Vitamin D₃ status, seasonal factors, and individual genetic variation (39).

1,25(OH)₂D₃ exerts comprehensive regulatory effects on adaptive immunity, generally promoting anti-inflammatory and tolerogenic responses. During CD4⁺ T helper cell (Th) differentiation, it selectively inhibits Th1 and Th17 lineage development while promoting regulatory T cell (Treg) formation and, to a lesser extent, supporting Th2 responses (Figure 1E). Mechanistically (Table 1), 1,25(OH)₂D₃ downregulates master transcription factors driving Th1 (40) (T-bet, T-box expressed in T cells) and Th17 (41) (ROR-γt, RAR-related Orphan Receptor Gamma t) differentiation while simultaneously enhancing Forkhead Box P3 (FoxP3) expression in developing Treg cells (42). CD8⁺ cytotoxic T lymphocytes (CTL) are similarly subject to 1,25(OH)₂D₃ regulation: 1,25(OH)₂D₃ reduces perforin and granzyme B expression, decreases pro-inflammatory cytokine production, thereby attenuating cytotoxic potential (43) (Figure 1D). In the B cell compartment, 1,25(OH)₂D₃ inhibits maturation and differentiation into plasma cells and memory cells (40) (Figure 1F); reduces antibody production by decreasing T follicular helper cell (Tfh) to secrete IL-21 and downregulating C−X−C motif chemokine ligand 13 (CXCL13) expression (44) while promoting the regulatory B cell (Breg) phenotype through inducting IL-10 expression (45). These synergistic effects collectively maintain immune tolerance and regulate autoimmune responses. Recent evidence also reveals that Vitamin D₃ interacts with the gut microbiome, indirectly influencing adaptive immune function through modulation of microbial composition and metabolite production, adding another layer of complexity to its immunoregulatory repertoire (46). Beyond peripheral immunomodulation, Vitamin D₃ also contributes to the establishment of central tolerance in the thymus. Thymic epithelial cells express VDR and CYP27B1, and Artusa et al. demonstrated that CYP27B1-deficient mice exhibit impaired differentiation of autoimmune regulator (Aire)-expressing medullary thymic epithelial cells (mTECs), defective negative selection of autoreactive T cells, ultimately leading to autoantibody production and premature thymic aging (47). These findings reveal a potential mechanism by which Vitamin D₃ prevents autoimmune diseases through regulation of thymic function.

The 1,25(OH)₂D₃-VDR complex upregulates Inhibitor of Kappa B Alpha (IκBα) protein levels, stabilizing this inhibitor and preventing nuclear translocation of NF-κB subunits (p50, p65), thereby suppressing transcription of pro-inflammatory genes including IL-1β, IL-6, and TNF-α (48, 49) (Figure 2A). Recent studies confirm that 1,25(OH)₂D₃ significantly suppresses NF-κB activation in endometrial inflammation (50). Additionally, 1,25(OH)₂D₃ has been shown to inhibit microRNA-mediated regulation of the NF-κB signaling pathway, potentially representing a novel mechanism for inflammatory control (51).

Vitamin D₃ effectively inhibits NLRP3 inflammasome assembly and activation through dual mechanisms: blocking NLRP3 deubiquitination (52) and suppressing upstream NF-κB signaling (53), thereby reducing IL-1β and IL-18 production (Figure 2B). Furthermore, Vitamin D₃ promotes autophagy (54), facilitating clearance of inflammatory triggers, and activates the Hippo−Yes−associated protein 1 (Hippo−YAP1) signaling pathway (55). Recent evidence demonstrates that 1,25(OH)₂D₃ enhances the Sirtuin 3 (SIRT3)-Superoxide Dismutase 2 (SOD2) pathway, ameliorating mitochondrial oxidative stress and reducing mitochondrial reactive oxygen species (mtROS) accumulation, thereby indirectly inhibiting NLRP3 inflammasome activation (56).

VDR activation downregulates Kelch-like ECH-associated protein 1 (Keap1, Nrf2’s cytoplasmic inhibitor), promoting Nrf2 nuclear translocation and activation of antioxidant response elements (57, 58) (Figure 2C). This process triggers upregulation of cytoprotective enzymes including superoxide dismutase, catalase, heme oxygenase-1, and glutathione S-transferase (59). In neurodegenerative disease and ischemia models, 1,25(OH)₂D₃-mediated Nrf2 activation inhibits ferroptosis, significantly enhancing cell survival rates (60). These antioxidant effects additionally contribute to alleviating chronic inflammation associated with metabolic and cardiovascular diseases (61, 62).

Through coordinated suppression of pro-inflammatory pathways and enhancement of antioxidant defense mechanisms, Vitamin D₃ establishes a finely tuned balance between immunomodulation and cytoprotection. Its net effect is highly context-dependent, highlighting its unique role as a physiological modulator rather than a simple immunosuppressant. While these molecular mechanisms have been extensively validated in vitro, their translation to clinical applications reveals significant complexity requiring careful consideration of individual patient factors.

Several empirical guideline suggests that daily supplementation of 1000 IU Vitamin D₃ increases serum 25(OH)D levels by approximately 7–10 ng/mL, with greater per-unit dose effects observed at lower baseline levels (63, 67, 68) (Box 1). Special populations require individualized approaches: obese individuals need 2–3 times the standard dose to achieve comparable serum concentrations (66, 69, 70) while patients with chronic kidney disease or granulomatous diseases may be particularly susceptible to hypercalcemia, necessitating lower doses or alternative formulations (71) (Box 1). For elderly individuals, Gallagher pointed out that daily dosing should not exceed 3000 IU, with serum 25(OH)D levels maintained below 40–45 ng/mL to prevent adverse effects including increased fall risk (72) (Box 1). Regarding formulation choices, Vitamin D₃ is better than Vitamin D₂ in raising 25(OH)D levels, and multiple studies have demonstrated that daily Vitamin D₃ supplementation is significantly more efficacious than intermittent high-dose regimens (e.g., weekly or monthly) (73, 74), possibly because the latter fails to maintain stable serum 25(OH)D levels or to achieve benefits on specific endpoints (65, 75). Regular monitoring of serum calcium during supplementation is essential to prevent hypercalcemia from long-term high-dose use. Hypercalcemia is the primary adverse effect of long-term high-dose Vitamin D₃ supplementation, manifesting as nausea, vomiting, polyuria, polydipsia, and fatigue. Without timely intervention, severe cases may progress to complications including nephrolithiasis, renal insufficiency, cardiac arrhythmias, and soft tissue calcification (76) (Table 2). Notably, hypercalciuria may precede hypercalcemia and independently increases the risk of kidney stone formation. High-risk populations primarily include patients with chronic kidney disease, granulomatous diseases (such as sarcoidosis and tuberculosis), and primary hyperparathyroidism. Therefore, regular monitoring of serum and urinary calcium levels during supplementation—particularly when daily doses exceed 4000 IU—is essential (67). If hypercalcemia is detected, supplementation should be discontinued immediately. Ultimately, Vitamin D₃ should serve as adjunctive therapy in immune-mediated diseases, integrated into comprehensive treatment plans rather than replacing standard treatment. Clinicians should develop individualized dosing strategies based on baseline Vitamin D₃ levels, genetic polymorphisms, inflammatory markers, season, geographic location, age, BMI, and other relevant factors.

Genetic studies reveal that polymorphisms in genes including GC, CYP27B1, CYP2R1, VDR, CYP24A1, NADSYN1, CUBN, and DHCR7 significantly influence Vitamin D₃ status (77), indicating that patient responses to supplementation are genetically determined. Genetic analysis can help determine optimal supplementation doses, enabling early identification and stratified management of “low responders” versus “high responders.” Meta-analyses demonstrate that TaqI polymorphism TT variant alleles and FokI variant FF alleles correlate positively with Vitamin D₃ supplementation response, potentially allowing dose reduction (78). Conversely, FokI variant CC allele and ApaI A allele carriers may require higher maintenance doses (79). Moreover, DBP gene variants rs7041 and rs4588 correlate with both 25(OH)D level variation and supplementation effectiveness (80).

Cross-sectional studies consistently show that Vitamin D₃-sufficient patients (≥30 ng/mL) exhibit significantly lower inflammatory markers including C-reactive protein (CRP) and IL-6 compared to deficient groups (81). A randomized controlled trial demonstrated that patients receiving 2000 IU Vitamin D₃ daily showed significantly greater IL-6 reduction compared to those receiving 1000 IU daily (82), suggesting higher doses may be necessary for effective systemic inflammation suppression. Evidence supports 20 ng/mL as the minimum target for mechanistic inflammation control, with 28ng/mL as the ideal target for optimizing adaptive immunomodulation (83). Future controlled trials investigating Vitamin D₃ supplementation efficacy across different baseline levels, inflammatory markers, and immune indicators are essential to determine optimal doses and achieve truly stratified, personalized treatment.

Vitamin D₃ deficiency is prevalent among psoriasis patients and may correlate with disease activity. Cross-sectional studies show that approximately 57.8% of psoriasis patients have Vitamin D₃ deficiency, rising to 80.9% during winter months with minimal sunlight, significantly exceeding healthy population rates (84). Genetic studies further reveal individual differences in Vitamin D₃ metabolism: VDR gene ApaI and TaqI polymorphisms not only correlate with psoriasis susceptibility but also affect patient 25(OH)D levels, with ApaI AA genotype patients showing the lowest serum 25(OH)D levels (85). Notably, disease severity may also influence Vitamin D₃ levels, with observations showing greater 25(OH)D level increases in moderate psoriasis patients compared to mild and severe cases (86). Mechanistically, Vitamin D₃ acts through multiple pathways in psoriasis (Figure 3A) (Table 3): regulating keratinocyte growth and differentiation (87), enhancing antimicrobial barrier function through LL-37 induction (88), suppressing pathogenic Th1/Th17 responses while promoting Tregs (89), and inhibiting DCs and macrophage activation (90). These mechanisms collectively address psoriasis-specific epidermal and immunological abnormalities.

Topical 1,25(OH)₂D₃ analogues (such as calcipotriol) are first-line treatments for psoriasis, often used in combination with corticosteroids (91) or phototherapy (92) to enhance efficacy. Studies show calcipotriol monotherapy can achieve 59% reduction in Psoriasis Area and Severity Index (PASI) after 8 weeks of treatment. One trial demonstrated that a 4-week course of calcipotriol–betamethasone combination therapy led to Physician Global Assessment (PGA) 0/1 (clear or nearly clear) rates of 72.6%, 56.5%, and 66.7% in mild, moderate, and severe psoriasis patients, respectively (93). Notably, topical medication efficacy is primarily driven by high concentrations achieved at lesion sites, with minimal correlation to patient serum 25(OH)D levels.

According to current international S3 guidelines and American Academy of Dermatology guidelines (94) for mild, localized patients: 1,25(OH)₂D₃ analogue monotherapy is preferred, applied twice daily. For moderate patients: 1,25(OH)₂D₃ analogues combined with topical corticosteroids (such as combination preparations) are recommended to enhance efficacy, with a transition to intermittent use after initial response to maintain efficacy and reduce side effects. For severe patients, systemic therapy should be the primary approach, with topical combination preparations as adjunctive treatment. This further confirms that Vitamin D₃ should serve as adjunctive therapy rather than primary treatment, mainly correcting deficiency. Extensive clinical trials support the safety and efficacy of topical 1,25(OH)₂D₃ analogues, whereas evidence for benefit from oral supplementation is primarily observational (95). Recent studies also indicate that Vitamin D₃ status can affect response to biologic therapies, suggesting that maintaining adequate 25(OH)D may optimize outcomes when using TNF-α or IL-17 inhibitors (96).

Vitamin D₃ deficiency is extremely prevalent in SLE patients. Studies indicate that up to 96% of SLE patients have Vitamin D₃ insufficiency (25(OH)D < 30 ng/mL), with 27% showing severe deficiency (25(OH)D < 15 ng/mL) (97). Observational studies consistently find negative correlations between serum 25(OH)D levels and disease activity in SLE patients (98). The immunomodulatory mechanisms of Vitamin D₃ align highly with SLE pathophysiology (Figure 3B) (Table 3): promoting Treg cells development while suppressing Th17 and Tfh (99); reducing B cell autoantibody production (100); regulating apoptotic pathways by upregulating anti-apoptotic protein B-cell lymphoma 2 (Bcl-2) and downregulating pro-apoptotic mediators (101); and reversing lupus T cell-specific DNA methylation abnormalities (102). These effects collectively reduce autoimmune response activity and mitigate inflammatory tissue damage.

However, clinical research on Vitamin D₃ supplementation yields inconsistent results. Vitamin D₃ supplementation as adjunctive therapy may modestly reduce Systemic Lupus Erythematosus Disease Activity Index (SLEDAI) scores and improve fatigue symptoms but cannot replace standard immunosuppressive regimens (103) (Box 1). Different studies show contradictory effects on anti-dsDNA antibodies and complement component 4, with overall conclusions showing no significant improvement. Some studies also failed to demonstrate that Vitamin D₃ supplementation improves various biomarkers in SLE patients; This suggests that its benefits may be limited to specific subgroups (such as severely deficient patients or those with seasonal variation).

Currently, no consensus guidelines exist for immunomodulatory dosing of Vitamin D₃ in autoimmune rheumatic diseases, despite in vitro experiments suggesting high-dose Vitamin D₃ may induce immunomodulatory effects. Research indicates that Vitamin D₃ supplementation shows better therapeutic effects in patients with lower Vitamin D₃ levels (104). For children, especially those on long-term corticosteroids, Vitamin D₃ requirements are at least twice the age-recommended intake (approximately 2000 IU/day) (63). Additionally, certain polymorphisms (such as VDR BsmI and FokI variants) may influence SLE risk in Asian populations (105), and factors such as VDR gene polymorphisms can predict treatment response. Therefore, future trials should stratify subjects based on baseline Vitamin D₃ levels, gene polymorphisms, and concomitant medications to identify populations with maximal benefit.

Vitamin D₃ deficiency is common in RA patients. Observational studies suggest associations between Vitamin D₃ status and RA risk. For example, the large-scale Iowa Women’s Health Study found that higher dietary Vitamin D₃ intake correlated with 34% reduced RA risk (106). Vitamin D₃ supplementation may provide anti-inflammatory and bone-protective effects. Mechanistic studies show (Figure 3C) (Table 3) that Vitamin D₃ suppresses Th17 differentiation and matrix metalloproteinase expression while promoting Treg responses (107), and maintains bone health through regulation of Receptor Activator of Nuclear Factor Kappa-B Ligand (RANKL)/osteoprotegerin (OPG) (108).

However, clinical studies on Vitamin D₃ treatment in established RA have yielded inconsistent conclusions. One randomized controlled trial found no significant effects of Vitamin D₃ supplementation on Erythrocyte Sedimentation Rate (ESR) and Disease Activity Score in 28 Joints (DAS28) (109, 110). This may relate to differences in study design, dosing, duration, and patient baseline characteristics. Evidence for optimal dosing remains insufficient, and gene polymorphisms in Vitamin D₃ metabolic pathways may influence effects (111). A national randomized controlled trial (Vitamin D₃ and Omega-3 Trial) including over 25,000 participants showed that daily supplementation with 2000 IU Vitamin D₃, over a median follow-up of 5.3 years, significantly reduced overall autoimmune disease incidence (including RA) by 22% (7). In another randomized double-blind placebo-controlled study, adding a single 300,000 IU Vitamin D₃ dose to standard therapy improved patient overall health status (mean serum 25(OH)D levels increased from baseline 16 ± 4 ng/mL to endpoint 28 ± 4.3 ng/mL), with no adverse reactions over three months (112). Dose-response studies show optimal anti-inflammatory effects with daily supplementation below 3,500 IU, with diminished effects above this dose (113); another study suggests better efficacy with weekly supplementation below 50,000 IU (114). Clinical practice should include regular Vitamin D₃ level monitoring with dose adjustments based on individual circumstances to maintain serum 25(OH)D within appropriate ranges without inducing hypercalcemia. Given these complex dose-response relationships and individual differences, implementing stratified Vitamin D₃ treatment strategies for RA patients is crucial.

Type 1 diabetes mellitus (T1DM) is a chronic autoimmune disorder characterized by pancreatic β-cell destruction and absolute insulin deficiency, predominantly affecting children and adolescents (115). Global T1DM prevalence reached approximately 8.4 million in 2021, with projections estimating 13.5–17.4 million cases by 2040 (116).

Vitamin D₃ deficiency is highly prevalent among T1DM patients, with meta-analysis indicating approximately 45% of children/adolescents with T1DM exhibit Vitamin D₃ insufficiency (117). Observational studies consistently demonstrate an inverse association between serum Vitamin D₃ levels and T1DM risk (118). Meta-analyses indicate that Vitamin D₃ supplementation during infancy may reduce T1DM risk by approximately 30% (119). These epidemiological findings suggest a potentially significant role for Vitamin D₃ in T1DM prevention. The protective effects of Vitamin D₃ in T1DM involve multiple mechanisms (Figure 3D) (Table 3). First, 1,25(OH)₂D₃ enhances β-cell insulin secretion through calcium signaling regulation and insulin gene transcription (120). Second, 1,25(OH)₂D₃ improves peripheral insulin sensitivity via Peroxisome Proliferator−Activated Receptor δ (PPAR-δ) activation (121). Third, 1,25(OH)₂D₃ protects pancreatic β-cells from autoimmune destruction by reducing pro-inflammatory cytokines (TNF-α, IL-1β) (122) and exerting antioxidant effects (123). Additionally, 1,25(OH)₂D₃ downregulates antigen-presenting molecules such as cathepsin G, thereby suppressing autoreactive T-cell activation and delaying β-cell immune destruction (124). The Vitamin D₃ regulation of thymic central tolerance described above (Section 3.2) is directly relevant to T1DM prevention: Artusa et al. also found that aged CYP27B1-knockout mice developed anti-islet autoantibodies and glucose intolerance (47). Since infancy represents the period of peak thymic activity, Vitamin D₃ supplementation during this window helps maintain normal negative selection, preventing autoreactive T cells from escaping to attack pancreatic β-cells. These mechanisms are particularly critical in early disease stages when 60–95% of β-cells are already compromised at diagnosis (125), as Vitamin D₃ supplementation may preserve residual β-cell function and exert immunomodulatory effects.

Numerous reviews and meta-analyses have established associations between genetic variants in Vitamin D₃-related genes and diabetes susceptibility. Studies have shown that among children with T1DM in China, carriers of the C allele of CYP2R1 (rs1993116) have a higher risk of developing T1DM than those carrying the T allele (126). A prospective cohort study of 101 newly diagnosed T1DM children demonstrated that adequate Vitamin D₃ status (≥30 ng/mL) and VDR gene FokI and TaqI polymorphisms were associated with better preservation of residual β-cell mass and function (127). However, findings remain inconsistent. For instance, a large Mendelian randomization study found no significant association between these polymorphisms and T1DM risk, suggesting that the role of genetic background requires further elucidation (128).

Regarding clinical interventions, the efficacy of Vitamin D₃ supplementation on glycemic control in established T1DM remains controversial. Some studies indicate that Vitamin D₃ supplementation (cholecalciferol 2000 IU/day) elevates serum 25(OH)D levels without significantly improving glycemic parameters such as Hemoglobin A1c (HbA1c) (129). Conversely, other studies report reductions in fasting glucose, mean daily glucose, and insulin requirements (130), along with attenuated inflammatory responses during the honeymoon period (the early post-diagnosis phase characterized by residual β-cell function and lower insulin requirements) through decreased serum TNF-α levels, thereby prolonging honeymoon duration (131). Importantly, the protective effects of Vitamin D₃ on pancreatic β-cell function are evident only within the first year of disease onset (newly diagnosed T1DM patients) (132), and 25(OH)D levels directly correlating with fasting C-peptide levels in newly diagnosed adolescents and adults (133). Additionally, accumulating evidence suggests that combined therapy with Vitamin D₃ and dipeptidyl peptidase-4 inhibitors (DPP-4i) may preserve β-cell function in adults with latent autoimmune diabetes (134). Major diabetes associations have not yet recommended routine Vitamin D₃ supplementation for improving glycemic control in T1DM, primarily due to evidence heterogeneity and undefined optimal dosing (129, 135). Nevertheless, low Vitamin D₃ status may be associated with increased diabetic ketoacidosis risk (136), hypoglycemic events, and poor metabolic control (137)in newly diagnosed children with T1DM. Therefore, correcting Vitamin D₃ deficiency remains important for overall disease management and patient health, although optimal supplementation dosages and intervention timing require validation through larger prospective studies.

Inflammatory bowel disease (IBD) encompasses chronic relapsing inflammatory disorders of the gastrointestinal tract, affecting approximately 4.9 million individuals worldwide, primarily comprising Crohn’s disease (CD) and ulcerative colitis (UC) (138). Animal models and epidemiological studies consistently demonstrate significant associations between low Vitamin D₃ levels and IBD risk (139). An Italian study reported mean Vitamin D₃ concentrations of 18.9 ± 10.2 ng/mL in IBD patients, significantly lower than healthy controls (140). Prospective studies indicate that each 1-μg increment in Vitamin D₃ intake reduces IBD risk by 51%, with this association persisting after adjustment for confounding factors (141). Vitamin D₃ participates in IBD pathophysiology through multiple mechanisms (Figure 3E) (Table 3). First, 1,25(OH)₂D₃ exerts immunomodulatory effects by enhancing antimicrobial protein expression and activating the nucleotide-binding oligomerization domain containing 2 (NOD2)-HBD2 signaling pathway (30): 1,25(OH)₂D₃ induces NOD2 expression, which activates NF-κB signaling to induce HBD2 production (30). This synergistic enhancement is abolished in CD patients with homozygous NOD2 mutations (29), providing a molecular link between Vitamin D₃ deficiency and CD genetic susceptibility, thereby regulating immune cells and inflammatory cascades (30). Second, 1,25(OH)₂D₃ strengthens intestinal epithelial barrier function by inducing tight junction protein expression, including zonula occludens-1 (ZO-1) and claudin-1 (142). Additionally, Vitamin D₃ may further promote intestinal health through gut microbiota modulation (143). Notably, these effects may exhibit individual variability influenced by factors including sex, hypertension, and smoking.

Clinical efficacy studies of Vitamin D₃ supplementation demonstrate considerable heterogeneity. In pediatric and adolescent populations, meta-analyses indicate that Vitamin D₃ supplementation (≥2000 IU/day for 12 weeks) significantly improves serum 25(OH)D concentrations and inflammatory markers with favorable safety profiles (144). In adults, supplementation with 40,000 IU/week for 8 weeks reduces disease activity indices, calprotectin, and serum C-reactive protein (CRP) levels while increasing albumin concentrations (145). Cohort studies reveal that elevated 25(OH)D levels correlate with reduced bowel resection risk, decreasing overall IBD risk by 34% and UC risk by 46%, although this association is not significant in CD patients (146). However, some studies found no significant correlations between serum 25(OH)D changes and endoscopic findings, calprotectin, Pediatric Crohn’s Disease Activity Index (PCDAI), or Pediatric Ulcerative Colitis Activity Index (PUCAI) scores, highlighting the need for further research to clarify clinical utility (147). VDR gene polymorphisms are closely associated with IBD susceptibility. Meta-analyses demonstrate that the FokI polymorphism ff allele confers elevated UC risk in Asian populations, while the ApaI polymorphism a allele confers CD protection in European populations (148). The TaqI polymorphism TT genotype associates with increased UC and CD risk in males, while the BsmI B allele correlates with elevated CD risk in East Asian populations (149). These genetic findings further support the critical role of Vitamin D₃ in IBD pathogenesis.

Despite accumulating evidence, while the American Gastroenterological Association recommends Vitamin D₃ monitoring for all IBD patients, optimal supplementation dosages remain unestablished (150). Ananthakrishnan proposes that individualized dosing based on baseline Vitamin D₃ status: 1000–2000 IU/day for mild deficiency, 2000–4000 IU/day for severe deficiency until target achievement, followed by 1000 IU/day maintenance (151). Given the substantial individual variability in Vitamin D₃’s role in IBD prevention and management, high-quality randomized controlled trials are needed to define stratified management strategies, including optimal dosing, treatment timing, and subtype-specific approaches for different IBD phenotypes.

Synthesizing evidence across five diseases, Vitamin D₃ clinical translation exhibits a characteristic coexistence of “mechanistic certainty” and “therapeutic heterogeneity.” Topical analogs demonstrate robust efficacy in psoriasis, whereas oral supplementation in SLE, RA, T1DM, and IBD is highly dependent on baseline Vitamin D₃ status, VDR polymorphisms, and disease stage. This reveals a core therapeutic logic: efficacy is pronounced with topical administration targeting defined cellular populations, while systemic immunomodulation requires precise identification of responder subgroups. The clinical translational significance of Vitamin D₃ lies in its role as a critical nexus linking nutrition, immunity, and metabolism, offering a low-cost, low-toxicity adjunctive therapeutic option for immune-mediated diseases. Current guidelines generally do not recommend routine Vitamin D₃ status assessment in the general asymptomatic population, given the high testing costs and absence of universally accepted diagnostic thresholds (152–154). While routine screening for high-risk groups (including individuals with obesity, elderly patients, those on chronic glucocorticoid therapy, and patients with autoimmune or chronic diseases) remains controversial, the latest international expert consensus advocates baseline 25(OH)D evaluation with individualized supplementation protocols tailored to baseline levels, body weight, concurrent medications, and clinical context (66). The approach of empirical supplementation coupled solely with serum calcium monitoring is not recommended, as hypercalcemia represents a late manifestation of Vitamin D₃ intoxication and does not reflect Vitamin D₃ status or tissue-level activity (68, 155). More importantly, this therapeutic heterogeneity has catalyzed a paradigm shift from empirical supplementation toward precision medicine—enabling individualized stratified treatment through integration of biomarkers including baseline 25(OH)D levels, VDR genotypes, and disease activity indices. This approach not only optimizes the clinical application of Vitamin D₃ itself but also establishes a methodological framework for translational research on other nutrients and immunomodulatory agents. Future research should focus on developing multidimensional predictive models, defining disease-specific dosing regimens, and elucidating synergistic mechanisms with biologics, ultimately achieving the transition from “one-size-fits-all” to precision intervention—thereby opening new avenues for the comprehensive management of immune-mediated diseases.