Decoding the Spectrum of Anorexia Nervosa: Clinical Impact, Molecular Insights, and Therapeutic Perspectives

Cardiovascular abnormalities represent some of the most frequent medical complications of AN, occurring in up to 87% of patients. Clinical manifestations encompass left ventricular atrophy, mitral valve prolapse, bradycardia, hypotension (often orthostatic), QTc prolongation, arrhythmias, pericarditis, ischemic heart disease, and heart failure (HF). Mortality due to cardiovascular causes is particularly elevated, with epidemiological data indicating a two- to threefold higher risk compared with the general population [29,30]. In a large Taiwanese cohort comprising 2081 patients with AN, Tseng et al. reported a 4.8% cumulative incidence of major adverse cardiovascular events (MACEs) over a five-year follow-up period. The risk of HF, structural cardiac abnormalities, and conduction disturbances was greatest shortly after diagnosis, whereas the incidence of ischemic heart disease rose significantly only by the fifth year. Older age and male sex were identified as independent risk factors for adverse cardiovascular outcomes [31].

Bradycardia, reported in 36–95% of patients, and hypotension, observed in up to 85%, correlate inversely with body mass index (BMI) and often necessitate hospitalization when BMI falls below 15 kg/m² [30,32,33,34,35]. Bradycardia likely reflects an adaptive decrease in basal metabolic rate, whereas hypotension arises from autonomic dysregulation characterized by increased vagal tone. QTc prolongation, observed in up to 40% of patients, becomes clinically significant when exceeding 600 ms due to the risk of ventricular tachycardia, torsades de pointes, and sudden cardiac death [34]. Electrolyte abnormalities, particularly hypokalemia and hypomagnesemia, are common precipitants, although QTc prolongation may also occur independently of electrolyte imbalance, implicating autonomic dysfunction. Certain antipsychotic agents may further exacerbate repolarization disturbances [36,37,38].

Structural myocardial alterations are also well documented. Echocardiography often reveals reduced left ventricular mass index proportional to the degree of undernutrition [34,35]. Histopathological findings include mitochondrial swelling, myxoid and lipofuscin accumulation, and interstitial fibrosis [39]. Thiamine deficiency contributes significantly to myocardial dysfunction, and beriberi cardiomyopathy may coexist [40]. Mitral valve prolapse, affecting up to 25% of patients, likely results from disproportion between ventricular chamber size and leaflet dimensions and typically resolves with weight restoration [30]. Pericardial effusion, observed in up to one-third of patients, is associated with thyroid hormone alterations and hypoalbuminemia and generally regresses following nutritional rehabilitation [30,34].

The refeeding phase is a particularly vulnerable period, as the metabolic transition from catabolism to anabolism can trigger refeeding syndrome, typically manifesting with hypokalemia, hypomagnesemia, and hypophosphatemia within the first 10 days of nutritional reintroduction. These shifts impair myocardial energy metabolism and oxygen delivery, predisposing to arrhythmias and HF even in the presence of preserved ejection fraction [32,34,41,42]. Thiamine deficiency may further exacerbate cardiac dysfunction. Proactive supplementation with electrolytes and thiamine during refeeding is therefore essential to prevent these potentially fatal complications [32].

Pulmonary complications in AN are less common but clinically relevant. Isolated reports describe spontaneous pneumothorax and pneumomediastinum [43]. Proposed mechanisms include malnutrition-induced bullae or bleb formation predisposing to alveolar rupture, as well as acute intrathoracic pressure changes from forceful vomiting [44]. Aspiration pneumonia may also occur in advanced stages, likely secondary to impaired pharyngeal muscle coordination from severe malnutrition. An increased frequency of emphysema has also been noted, with some authors proposing the entity of "nutritional emphysema," though its pathogenesis and validity remain debated [30,45].

Patients with AN, particularly those with the binge–purge subtype, frequently display sustained overactivity of the hypothalamic–pituitary–adrenal (HPA) axis, reflected by elevated levels of corticotropin-releasing hormone (CRH) and adrenocorticotropic hormone (ACTH) [75]. A rare case of ACTH deficiency with secondary adrenal insufficiency has also been documented [76]. Excessive CRH and ACTH secretion contributes to hypercortisolemia, with affected individuals often exhibiting increased salivary and 24 h urinary cortisol levels [77]. The cortisol awakening response is typically exaggerated, especially in the binge–purge subtype compared with the restrictive subtype [78]. In contrast, hair cortisol concentration, a biomarker of long-term cortisol exposure, does not appear elevated and shows weak correlation with urinary cortisol output, possibly indicating altered cortisol incorporation or enzyme dysregulation secondary to severe malnutrition [79]. Weight restoration generally leads to normalization of circulating cortisol levels; however, persistent HPA axis abnormalities have been reported. Schmalbach et al. observed that, despite normalized basal cortisol, individuals with AN demonstrated a blunted cortisol response to acute stress, a pattern more closely associated with residual eating-disorder psychopathology and psychological distress than with BMI [80]. Pharmacological suppression of cortisol is not recommended, given the absence of proven benefit and the potential risks of adrenal insufficiency and further weight loss [81].

Prolonged starvation in AN is characterized by increased growth hormone (GH) secretion and pulsatility, accompanied by markedly reduced circulating insulin-like growth factor 1 (IGF-1) levels. This paradoxical pattern likely reflects a compensatory adaptation aimed at maintaining euglycemia through enhanced gluconeogenesis and promoting lipolysis. In AN, however, GH hypersecretion occurs in the context of GH resistance, mediated by reduced insulin concentrations and elevated fibroblast growth factor 21 (FGF21), both of which impair GH receptor signaling and hepatic IGF-1 synthesis [77,81]. Growth hormone secretagogue receptor (GHSR) signaling has also been implicated in circadian adaptation during periods of food restriction. In a murine model of AN, GHSR-deficient mice exhibited impaired circadian adjustment, with diminished daytime and pre-prandial activity [82]. Although premorbid stature in AN is generally normal, adult height often remains below midparental expectations. Partial catch-up growth may occur with nutritional rehabilitation; however, final stature depends on chronological age, bone age, growth velocity during hospitalization, and concurrent changes in luteinizing hormone (LH) secretion [83]. Growth hormone therapy has demonstrated potential benefits in patients with persistent AN-related growth failure, increasing linear growth velocity compared with placebo over a 12-month period [84].

Menstrual irregularities are highly prevalent in AN, with functional hypogonadotropic hypogonadism (FHH) most commonly manifesting as amenorrhea, reported in up to 85% of cases. Loss of adipose tissue leads to leptin deficiency, disrupting kisspeptin-mediated stimulation of hypothalamic gonadotropin-releasing hormone (GnRH) neurons. This impairs pulsatile GnRH secretion and subsequently reduces LH and follicle-stimulating hormone (FSH) output. As a result, ovarian estradiol and testicular testosterone production decline [77,81]. Weight restoration typically reverses FHH, though menstrual recovery may take up to one year, and approximately 20% of women fail to resume menses despite normalization of body weight [81,85]. Among weight-restored individuals, higher estradiol concentrations and greater LH/FSH responsiveness to GnRH predict menstruation resumption. Specific endocrine thresholds, such as the presence of at least two LH pulses within four hours and an LH/GnRH response ≥33 IU/L, have demonstrated strong predictive value independent of body weight [86]. Despite amenorrhea, conception remains possible; thus, early fertility counseling is recommended due to increased obstetric risks, including low birth weight, preterm delivery, and intrauterine growth restriction [87,88].

Typical clinical manifestations of AN, including dry skin, hypothermia, hypotension, and bradycardia, frequently reflect underlying thyroid dysfunction. Severe malnutrition often induces a non-thyroidal illness syndrome (NTIS), characterized by reduced triiodothyronine (T3), elevated reverse T3 (rT3), and thyroid-stimulating hormone (TSH) and free thyroxine (fT4) levels within the low-normal range [89,90]. Suppression of hypothalamic-pituitary-thyroid (HPT) axis activity, indicated by reduced fT3 and a decreased fT3/fT4 ratio, appears more pronounced in individuals with severe depressive symptoms [91]. An fT3/fT4 ratio below 2.0 has been proposed as a biomarker distinguishing NTIS from central hypothyroidism in adolescents [92]. Thyroid hormone alterations generally improve with nutritional rehabilitation, although complete normalization is not universal. Animal studies suggest that early nutritional support may prevent T3 decline during fasting by modulating deiodinase activity and leptin signaling [93]. Exogenous thyroid hormone replacement is not recommended, as it may disrupt adaptive hypometabolism and heighten cardiovascular risk [81].

Individuals with AN may exhibit impaired osmoregulation, as evidenced by lower plasma sodium and osmolality, elevated antidiuretic hormone (ADH) concentrations, and diminished urine-concentrating capacity. ADH responses appear dysregulated, with persistently dilute urine particularly in chronic illness [94]. In contrast, copeptin, used as a stable surrogate marker of ADH, does not differ between medically stable patients with AN and healthy controls, suggesting that ADH activity may not be elevated under normohydrated conditions [95]. Notably, central diabetes insipidus can emerge during the refeeding phase, with MRI findings of absent posterior pituitary high signal (PPHS) indicating ADH granule depletion [96,97].

Oxytocin dysregulation has also been implicated in AN pathophysiology, with reduced serum and cerebrospinal fluid levels reported [81,98]. Elevated postprandial oxytocin concentrations have been associated with heightened anxiety and depressive symptoms, independent of cortisol and largely unaffected by leptin status [99]. Conversely, other studies have described postprandial oxytocin declines, more pronounced in atypical AN, potentially contributing to appetite dysregulation [100]. Associations between oxytocin and psychopathology may vary by subtype, with restrictive AN showing broadly negative correlations across symptom domains, while binge–purge AN is more closely linked to depressive symptoms [101]. These findings have prompted investigation of intranasal oxytocin (IN-OT) as a therapeutic strategy. A pilot inpatient trial reported reductions in eating-related preoccupations, cognitive rigidity, and salivary cortisol responses. However, a subsequent multicenter randomized controlled trial (RCT) failed to replicate these results, suggesting that treatment effects may depend on baseline symptom severity and comorbid psychiatric profiles [102,103].

Fat mass depletion in AN may produce significant alterations in adipokine secretion. Leptin, a key regulator of satiety, neuroendocrine function, and metabolic homeostasis, is reduced, initiating starvation-adaptive processes that operate through both threshold-dependent "switches" and graded, tissue-specific modulation [104]. Low leptin contributes to hyperactivity, a relationship absent post-recovery, when activity aligns more closely with core psychopathology [105,106]. Ghrelin signaling is impaired via increased methylation of the growth hormone secretagogue receptor 1a (GHSR1a) promoter, consistent with "ghrelin resistance," explaining the lack of compensatory hyperphagia despite elevated circulating and exogenous ghrelin, while anxiety, food preoccupation, and altered reward processing persist [107]. Elevated liver-expressed antimicrobial peptide 2 (LEAP2), an endogenous GHSR antagonist, may reinforce this selective resistance, highlighting complex interactions between metabolic signals and neural reward circuits [108]. Circulating adiponectin, which is typically elevated during caloric restriction, is influenced by metabolic and inflammatory mediators such as insulin, resistin, triglycerides, and interleukin (IL)-6. Its concentrations correlate positively with GH pulsatility but remain unaltered by short-term GH elevations, suggesting regulation primarily by fat mass rather than by acute endocrine fluctuations [109,110].

Nutritional deprivation has long been implicated in immune dysregulation, and accumulating data suggest that AN is accompanied by distinct alterations in both innate and adaptive immunity [139,140]. However, the available evidence remains heterogeneous and is often limited by small cohort sizes. Components of innate immunity appear blunted, although the contribution of specific subsets such as macrophages and dendritic cells has yet to be fully characterized [141]. Circulating levels of macrophage inhibitory cytokine-1 (MIC-1) tend to rise during starvation and decline following refeeding, a fluctuation that may be potentiated by hyperinsulinemia [142,143]. Natural killer (NK) cell counts are generally reduced, while their cytotoxic function appears largely preserved [141,144].

Adaptive immune responses are likewise perturbed. Although the proliferative capacity of T cells is usually maintained, an elevated CD4⁺/CD8⁺ ratio is frequently observed, largely due to selective depletion of CD8⁺ subsets, a shift that could impair antiviral defenses [145]. Overexpression of the C-X-C chemokine receptor type 4 (CXCR4) on CD4⁺ T cells has been associated with both psychological distress and nutritional status in adolescents with AN [146], whereas regulatory T cell (Treg) function appears relatively preserved [147]. Findings regarding humoral immunity are ambiguous. B cell counts may be normal or elevated, with restrictive-type AN showing expansion of antigen-experienced subsets alongside depletion of immunoregulatory populations [148]. Antibody titers are typically reduced or within normal limits, yet vaccine responsiveness remains intact [141,149]. Reports also suggest aberrant T–B cell crosstalk, and a decreased neutrophil-to-lymphocyte ratio (NLR) has been proposed as a potential marker of disease severity [141,150].

Cytokine profiling has yielded similarly variable results, although most studies report elevated concentrations of pro-inflammatory cytokines, including IL-1β, IL-6, and IL-8 [151]. Prostaglandin E₂ (PGE₂) has been implicated in IL-1β-driven anorexic behavior, albeit with strain-specific variability [152]. Findings regarding tumor necrosis factor-alpha (TNF-α) remain inconsistent. For instance, one study demonstrated in vitro release comparable to controls, whereas lipopolysaccharide (LPS)-stimulated secretion appeared attenuated, possibly reflecting reduced monocyte availability. Other investigations reported increased IL-6 and transforming growth factor-beta (TGF-β) without significant TNF-α alterations, while some data support spontaneous TNF-α production [151,153]. Reduced interferon-gamma (IFN-γ) secretion by lymphocytes has also been described, though findings are not uniform across studies [151,154].

Importantly, immune abnormalities may emerge even in the early stages of AN, with improvements in cytokine profiles during treatment paralleling reductions in depressive symptoms [155]. Restrictive-type AN may not initially exhibit overt pro-inflammatory activation; nonetheless, disturbances in immune-related mediators such as C-X-C motif chemokine ligand 1 (CXCL1) and matrix metalloproteinase-8 (MMP-8) have been documented [156]. Complement activity remains underexplored, although reduced C3 levels have been correlated with disease severity and improve with weight restoration [157]. Oxidative stress also appears to modulate immune function, as indicated by reduced serum uric acid and total antioxidant capacity, both of which normalize following nutritional rehabilitation [158,159].

While some immune abnormalities in AN resemble those observed in primary malnutrition, the overlap is only partial, suggesting that caloric restriction alone does not fully account for the immunological phenotype of AN [141]. Endocrine factors, particularly adipokines such as leptin and adiponectin, likely exert additional modulatory effects on immune responses [160]. Collectively, the available evidence supports an immunological contribution to the pathophysiology of AN, although its precise clinical significance remains incompletely defined. The partially autoimmune potential of AN is further suggested by its co-occurrence with immune-mediated diseases, particularly those affecting the gastrointestinal tract, such as celiac disease (CeD) and inflammatory bowel disease (IBD). In the case of CeD, comparable patterns of immune dysregulation have been described, albeit mediated through distinct mechanisms of aberrant immune activation and inflammatory signaling [161]. On the other hand, the relationship between AN and IBD remains less consistent. Population-based data and genetic analyses yield divergent findings regarding both the strength and direction of association between AN and specific IBD subtypes, namely Crohn's disease (CD) and ulcerative colitis (UC). Overall, the mechanistic basis underlying the interplay between AN and immune-mediated GI disorders remains unclear and warrants further investigation [162,163,164]. Additional immune-related phenomena include hepatic cytolysis linked to anti-hypoxia-inducible factor 1-alpha (HIF-1α) autoantibodies, and reactivation of latent human herpesviruses 6 and 7 (HHV-6, HHV-7) leading to pityriasis rosea. Interestingly, reduced salivary immunoglobulin M (IgM) concentrations have been correlated with increased dental plaque accumulation in subjects with AN [50,165,166,167].

The gut microbiota, comprising bacteria, viruses, fungi, and archaea, and its genomic counterpart, the gut microbiome, play a central role in maintaining host homeostasis. Disruption of this balance gives rise to gut dysbiosis, which in AN is marked by increased intestinal permeability, reduced microbial diversity, and distinct compositional alterations. These include elevated levels of Enterobacterales, Proteobacteria, and Methanobrevibacter smithii, alongside reductions in Faecalibacterium prausnitzii and Firmicutes [168,169,170]. Beyond bacterial shifts, patients with AN demonstrate diminished viral–bacterial interactions and enrichment of microbial pathways linked to neurotransmitter degradation, suggesting that dysbiosis may contribute to neurobiological processes underlying the disorder [171]. Within this context, the gut–brain axis (GBA), a bidirectional communication network integrating immune, hormonal, and metabolic signals, has become a major focus of contemporary research [172,173].

Loss of intestinal barrier integrity facilitates the translocation of LPS from Gram-negative bacteria into the circulation via disrupted tight junction proteins, a phenomenon commonly referred to as "leaky gut". This process elicits an immune response marked by the release of pro-inflammatory cytokines, including IL-6 and TNF-α, which can cross the blood–brain barrier and promote neuroinflammation [170]. The hypothalamus, enriched in cytokine receptors and central to appetite regulation, is particularly sensitive to these signals. Toll-like receptor 2 (TLR-2) and toll-like receptor 4 (TLR-4) activation of microglia, leading to NLR family pyrin domain-containing protein 3 (NLRP3) inflammasome activation, provides a key pathway through which peripheral immune disturbances may disrupt hypothalamic function [174,175,176]. The role of the hypothalamus in weakening immune defense and further destabilizing intestinal barrier integrity is underscored by the chronic hyperactivity of the HPA axis observed in AN, manifested in elevated cortisol secretion, particularly in the binge–purge subtype [177].

Metabolic signaling through short-chain fatty acids (SCFAs) constitutes another mechanism shaping neuroinflammation. SCFAs, such as butyrate, are generated by bacterial fermentation of dietary fibers, and patients with AN have been shown to display reduced fecal concentrations of butyrate and acetate compared with healthy controls [178]. Diminished butyrate production has also been associated with lower levels of brain-derived neurotrophic factor (BDNF), impairing neuronal growth, survival, and plasticity, and thereby contributing to disturbances of appetite regulation and mood [179]. Other microbiota-derived metabolites, including caseinolytic peptidase B (ClpB), can mimic the anorexigenic hormone α-melanocyte-stimulating hormone (α-MSH), further enhancing appetite suppression [172]. In addition, severely ill patients may demonstrate reduced circulating concentrations of diazepam-binding inhibitor (DBI). A decline in DBI weakens inhibitory control over anorexigenic signals such as growth differentiation factor 15 (GDF15) and lipocalin-2 (LCN2), thereby reinforcing restrictive eating behaviors [180].

Altered tryptophan metabolism represents an additional pathway through which the gut influences brain function in AN. Gut microbes divert tryptophan away from serotonin (5-HT) synthesis, reducing the substrate available for neurotransmitter production. Combined with dietary restriction, this leads to further 5-HT depletion, increasing vulnerability to mood disturbances and cognitive deficits [181]. Autonomic dysregulation may boost these effects, as the gut–vagus nerve pathway serves as a critical conduit for microbial signaling to the brain. Evidence from animal studies indicates that vagal input can modulate dopamine release, inflammatory responses, and emotional behavior, although human data remain mixed [182].

Overall, current evidence indicates that gut dysbiosis in AN disrupts neuroimmune, neuroendocrine, and neurotrophic processes through the GBA. This interplay positions the gut microbiome not only as a potential biomarker of disease progression but also as a promising therapeutic target. Figure 5 presents the role of the GBA in the development and progression of AN.

The management of AN requires a coordinated, multidisciplinary approach integrating the expertise of psychiatrists, psychologists, and medical–nutrition specialists. Nutritional education should be initiated at the outset and reinforced throughout treatment, with the goal of establishing sustainable, health-promoting eating behaviors. The involvement of registered dietitians is essential to ensure safe and progressive weight restoration. Traditional refeeding protocols typically began with approximately 1200 kcal/day; however, more recent strategies employing 1400–1600 kcal/day have been shown to be safe when patients are closely monitored. Vigilance for refeeding syndrome remains paramount, given its potential lethality during early nutritional rehabilitation. Electrolyte levels must be assessed regularly, and supplementation with thiamine, riboflavin, vitamin D, calcium, and other essential micronutrients should be administered. A realistic weight-gain target is approximately 0.5 kg per week [183]. Table 1 depicts recent studies of nutritional management in patients with AN.

Psychotherapy remains the cornerstone of AN treatment. Evidence-based modalities include family-based interventions, cognitive behavioral therapy (CBT), and the Maudsley model for adults. Emerging approaches, such as the provision of calorie-dense foods in prepackaged formats, have been investigated to enhance dietary adherence. Acceptance and commitment therapy (ACT), which emphasizes restructuring maladaptive cognitions, fostering intrinsic motivation, and reinforcing value-driven behaviors, has also garnered increasing attention. On the contrary, pharmacological interventions have demonstrated limited efficacy. Antidepressants, in particular, yield minimal clinical benefit. To date, no effective pharmacological treatment for AN has been established, a therapeutic gap that has prompted intensified research into alternative strategies [194,195].