Beyond adrenal fatigue: reframing the adrenal stress index through neutrophil-mediated glucocorticoid resistance

Stress and inflammation are ubiquitous drivers of chronic disease, yet the clinical tools to assess the organism’s capacity to cope with these stressors remain a subject of intense debate. Among these tools, the Adrenal Stress Index (ASI) – a non-invasive salivary test measuring the diurnal rhythm of cortisol and dehydroepiandrosterone sulfate (DHEAS) – occupies a controversial niche (1, 2). The rationale for the ASI lies in the unique properties of saliva as a biological fluid. Unlike serum cortisol, which primarily reflects the total hormone concentration (largely bound to corticosteroid-binding globulin, CBG, and albumin), salivary cortisol correlates strongly with the free, biologically active fraction of the hormone (3). Since only the free hormone can passively diffuse into cells and bind to glucocorticoid receptors, salivary levels provide a superior readout of tissue-level glucocorticoid exposure compared to total serum levels, particularly in states where binding globulins are altered, such as insulin resistance, inflammation, or estrogen therapy (4). Furthermore, the non-invasive nature of saliva collection allows for repeated sampling, enabling the assessment of the circadian slope and the Cortisol Awakening Response (CAR), dynamic features that a single blood draw misses completely.

This dynamic resolution also underscores the limitations of urinary analysis, such as 24-hour urinary free cortisol or catecholamines. While urinary measures provide a useful integrated assessment of total daily hormone production, they fail to capture the critical circadian variations – the peaks and troughs – that characterize a healthy HPA axis response (5). Moreover, urinary catecholamines (epinephrine and norepinephrine) primarily reflect the cumulative sympathetic-adrenal-medullary (SAM) activity and are heavily influenced by renal clearance and total volume, whereas salivary cortisol offers a real-time, non-integrated proxy of the unbound steroid fraction (4, 6). By bypassing the “averaging” effect of urinary collection, the ASI provides a superior temporal resolution for identifying specific patterns of chronodisruption.

Despite these physiological advantages, a sharp dichotomy persists between mainstream endocrinology and functional medicine regarding the utility of the ASI. Mainstream endocrinology operates on a binary model of adrenal function: the gland is either competent or insufficient (Addison’s disease), hyperactive (Cushing’s syndrome) or normal. From this perspective, “sub-clinical” deviations in cortisol rhythm are often viewed as irrelevant noise. Consequently, the ASI is frequently dismissed as redundant because it does not add value to the diagnosis of overt adrenal pathology (7, 8).

Conversely, functional and integrative medicine practitioners rely on the ASI to detect “dysregulation” long before overt pathology appears. However, this approach has been hampered by the scientifically flawed nomenclature of “Adrenal Fatigue”. This term implies that the adrenal glands themselves become “tired” or depleted due to chronic stress – a concept that lacks histological and physiological evidence outside of autoimmunity or infarction (8).

The central hypothesis of this paper is that the conflict is one of interpretation, not measurement. The ASI is not a test of “adrenal secretory capacity” (which is indeed robust and rarely fails), but may reflect aspects of allostatic load and inflammatory resilience (9). When we measure salivary cortisol and DHEAS, we are not asking “Can the adrenals work?”, but rather “How is the neuro-endocrine-immune system adapting to the environment?”. By reframing the ASI away from the discredited “adrenal fatigue” model and towards a systems biology framework involving neutrophil function, CBG cleavage, and anabolic buffering, we propose a hypothesis-driven interpretive framework for investigating the biological cost of adaptation.

A critical limitation of conventional endocrine assessment is the assumption that systemic hormone levels linearly reflect tissue-level action. In the case of cortisol, this assumption is flawed. In circulation, cortisol is predominantly protein-bound, with approximately 90% sequestered by corticosteroid-binding globulin (CBG) or albumin (10). While this reservoir buffers plasma levels, it restricts the hormone’s immediate bioavailability.

The key to targeted anti–inflammatory action lies in the delivery mechanism mediated by neutrophils. At sites of inflammation, neutrophils secrete neutrophil elastase, a protease stored in azurophilic granules, which specifically cleaves the reactive center loop of CBG (10, 11). This cleavage induces a conformational change that reduces CBG’s affinity for cortisol by orders of magnitude, effectively “dumping” free cortisol precisely where it is needed to quench inflammation (10, 11).

Crucially, the enzymatic arsenal of neutrophils is finite. Azurophilic granules are synthesized exclusively during the promyelocyte stage of granulopoiesis in the bone marrow (12). Once a neutrophil enters circulation, it cannot replenish these granules (13). In acute inflammation, the bone marrow responds by releasing fresh waves of competent neutrophils. However, under conditions of chronic, low–grade inflammation (as seen in metabolic syndrome or chronic stress), the demand for elastase outstrips the maturation capacity of granulocytes. This leads to the release of “exhausted” or immature neutrophils that lack sufficient azurophilic granules (14).

We propose that the clinical phenomenon often mislabeled as “adrenal fatigue” is, in many cases, a state of acquired local glucocorticoid resistance. The adrenal cortex may produce adequate cortisol (hence normal serum levels), but the delivery mechanism – neutrophil-mediated CBG cleavage – has failed due to granule depletion. The result is a paradox: systemic cortisol sufficiency coexistence with tissue-level glucocorticoid deficiency, leading to unremitting inflammation. The ASI, by measuring free salivary cortisol (which correlates with the unbound fraction), may offer a closer approximation of this bioavailable pool than total serum cortisol (Figure 1).

Dehydroepiandrosterone sulfate (DHEAS), the most abundant circulating steroid in humans (15, 16), has long been dismissed as a mere precursor pool or a weak androgen. However, its physiological role is far more complex. Beyond its classical role as a steroid precursor, accumulating evidence indicates that DHEAS exerts direct immunomodulatory and neuroprotective effects (15–18). Experimental and clinical studies have shown that DHEAS can counterbalance glucocorticoid-induced immune suppression, modulate cytokine production, and preserve cellular immune competence under chronic stress conditions (17, 19). Moreover, age-related declines in DHEAS have been associated with increased inflammatory burden, frailty, and impaired stress resilience (20–22).

Recent integrative models of endocrine–immune interaction have emphasized the importance of considering cortisol and DHEAS not as independent variables, but as components of a coordinated adaptive system in which their dynamic balance reflects the organism’s capacity to maintain metabolic and inflammatory homeostasis. (17, 23, 24).

While cortisol mobilizes energy substrates to survive immediate threats (catabolism), DHEAS signals tissue repair, immune potentiation, and synaptic plasticity (anabolism). The molar ratio between cortisol and DHEAS is therefore a fundamental metric of the organism’s allostatic state. A decline in DHEAS is not merely a sign of aging (adrenopause); it is a biomarker of accelerated biological weathering.

Clinically, low DHEAS levels are consistently associated with sarcopenia, frailty, and cardiovascular mortality (20, 21). In the context of the ASI, DHEAS may serve as a proxy for the organism’s anabolic reserve (16, 25) within the context of integrated endocrine–immune adaptation (15, 17). Its measurement allows clinicians to distinguish between a stress response that is well-compensated (high cortisol, maintained DHEAS) and one that has become maladaptive (high/normal cortisol, depleted DHEAS), a distinction that serum cortisol alone cannot provide.

When viewed through the framework proposed here, ASI patterns can be described as functional configurations of circadian glucocorticoid availability and anabolic buffering rather than as evidence of glandular “fatigue”. Importantly, the associations reported in the literature between salivary patterns and clinical or immune-related features are heterogeneous; therefore, the profiles below are presented as descriptive research phenotypes intended to guide empirical testing.

Overall, these profiles are not proposed as diagnostic categories but as hypothesis-generating phenotypes that may help structure future mechanistic and longitudinal studies at the interface of circadian endocrinology, inflammation, and stress physiology.

The findings and the mechanistic framework presented here suggest that the clinical utility of the Adrenal Stress Index (ASI) has been historically misunderstood due to a reductionist view of the endocrine system. Conventional endocrine assessment primarily focuses on systemic hormone concentrations, whereas the ASI, by capturing the free fraction and the circadian rhythm, may offer a dynamic readout related to allostatic load and the efficiency of the cortisol delivery system.

The transition from the clinically vague concept of “adrenal fatigue” to the rigorous model of HPA-Immune Chronodisruption represents more than a semantic shift; it is a necessary evolution in the management of chronic inflammatory diseases. As we propose, the Adrenal Stress Index (ASI) is not a measure of glandular failure, but a functional proxy for the organism’s ability to maintain allostatic homeostasis under persistent demand.

Our hypothesis proposes a possible mechanistic link in the current understanding of glucocorticoid dynamics by identifying the neutrophil-CBG-elastase axis as a potential site of failure in chronic stress. This model is presented as a testable hypothesis intended to stimulate further experimental and clinical investigation. By recognizing that the bioavailability of cortisol is dependent on a finite pool of effector-cell granules, this framework may help explain the “silent” inflammation seen in patients with normal serum cortisol but flattened salivary profiles. In this light, the ASI may be considered as a functional interpretive tool for acquired local glucocorticoid resistance, offering a functional window into the tissue-level availability of the hormone that systemic blood tests cannot provide.

Furthermore, the integration of DHEAS as a metabolic buffer and the analysis of circadian rhythmicity move the focus from hormone levels to hormone timing and balance. The loss of the cortisol slope and the collapse of the anabolic reserve (DHEAS) are not just symptoms of stress; they are drivers of further systemic decline, contributing to a self–perpetuating cycle of metabolic and immune weathering.

Future research should also investigate the stability and variability of these quantitative descriptors across repeated measurements in the same individuals, in order to distinguish state-dependent fluctuations from trait-level regulatory patterns. If our hypothesis is correct, the restoration of HPA rhythmicity and the protection of the “neutrophil pool” could represent potential targets for future investigation.

These observations support the value of integrative approaches to endocrine physiology. We must now embrace a systemic, chronobiological approach to endocrinology, where the ASI may serve as a functional observational tool, documenting the organism’s complex, and often failing, struggle to sustain the energetic and inflammatory costs of life. Future research should also consider the potential influence of Early Life Stress (ELS), which is known to shape adult HPA axis regulation and inflammatory physiology, and may therefore contribute to interindividual variability in ASI profiles.

The author(s) declared that financial support was not received for this work and/or its publication.

The original contributions presented in the study are included in the article/supplementary material. Further inquiries can be directed to the corresponding author.

GC: Conceptualization, Writing – original draft, Writing – review & editing.

GC was employed by company MEDYLAB S.r.l.

The author(s) declared that generative AI was used in the creation of this manuscript. During the preparation of this work, the author used Gemini (Google) in order to refine the technical English prose, improve the structural flow of the manuscript, and assist in the generation of figures. After using this tool, the author reviewed and edited the content as needed and takes full responsibility for the content of the publication.

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