Glucocorticoids (GCs) and the Glucocorticoid Receptor (GR): Mechanisms, Classification Frameworks, and the Latest Advances (with a Product Selection Table)
Glucocorticoids (GCs) and the Glucocorticoid Receptor (GR): Mechanisms, Classification Frameworks, and the Latest Advances (with a Product Selection Table)
What are glucocorticoids?
Glucocorticoids (GCs) are a class of steroid hormones synthesized in the adrenal cortex from cholesterol, produced mainly in the zona fasciculata. In humans, the predominant endogenous glucocorticoid is cortisol (with corticosterone usually lower), whereas in rats/mice corticosterone is the main glucocorticoid.
Common point of confusion:
“Corticosteroids” is a broader umbrella term that typically includes:
What are the “typical features” of glucocorticoids?
Think of them as “chemical signals that can cross membranes.” The typical features of glucocorticoids (GCs) can be summarized in four sentences:
Where do glucocorticoids act—and what are they “doing” in each domain?
A. Physiology: Why does the body need them?
B. Medicine and pharmacy: Why are they “super commonly used drugs”?
What is the glucocorticoid receptor GR (glucocorticoid receptor)?
GR is the principal receptor mediating glucocorticoid actions. It is an intracellular, ligand-dependent transcriptional regulator belonging to the nuclear receptor superfamily. The human gene is NR3C1 (nuclear receptor subfamily 3 group C member 1).
How does GR work? (A 4-step “cytoplasm-to-nucleus” sequence)
Structurally, GR typically consists of an N-terminal transactivation domain (NTD/AF-1), a DNA-binding domain (DBD, with zinc fingers), a hinge region, and a ligand-binding domain (LBD/AF-2).
A useful analogy: the hormone is the key and GR is the lock—but once unlocked, GR goes on to “rewrite the switch states” of a large set of genes.
Note: Molecular chaperones are “protein assistants” that help receptors maintain proper conformation and complete assembly/transport; FKBP51/52 are co-chaperones.
GR is crucial: a “master valve” for many diseases and drug effects
There are three main reasons:
How can GR be “classified”?
Classification axis | Subtype/option | One-line definition | Key details / common pitfalls |
1. By receptor itself (isoforms) | GRα (glucocorticoid receptor alpha) | The canonical dominant form: binds glucocorticoids and mediates most classic effects | Not a single protein form: even within GRα, alternative translation initiation can yield multiple N-terminal variants (often referred to as GR-A/B/C/D in the literature), which may differ in activity spectra and gene selectivity—so “GRα” can still show strong tissue differences |
| GRβ (glucocorticoid receptor beta) | Produced by alternative splicing; generally thought not to bind conventional glucocorticoids, and can negatively regulate GRα in some contexts (dominant-negative) | Pitfall: treating GRβ only as a “brake.” In some models, GRβ may also have GRα-independent functions (highly context-dependent) |
| Other GR isoforms | Beyond α/β, NR3C1 can generate other splice/translation-start combinations (often named GRγ, GR-P, etc. in reviews) | “GR is not just α/β” |
2. By signaling output mode (signaling modes) | Genomic actions | After nuclear entry, GR regulates transcription—most systematic and central mode | Three typical “nuclear landing routes”: (1) direct binding to GREs; (2) tethering to inflammatory transcription factors such as NF-κB and AP-1; (3) downregulation via negative regulatory elements (e.g., nGRE, negative GRE) |
| Non-genomic actions | Faster (seconds–minutes) effects via membrane/cytoplasmic interactions that influence signaling pathways | Can occur in many contexts; mechanisms may involve membrane-initiated signaling, ion channels/kinase cascades, and rapid processes involving the classical receptor |
3. By pharmacological modulation (pharmacological regulation) | Agonists (most clinical therapies) | Activate GR to reshape inflammatory/immune and metabolic networks (strong efficacy) | Real-world key point: broad action spectrum → side effects also come from being “too broad”; “systemic vs local delivery” (inhaled/topical/intra-articular, etc.) strongly shifts the risk–benefit balance |
| Antagonists / blockers | Block GR signaling for situations where cortisol effects need to be reduced (e.g., strategies related to Cushing syndrome) | More specialized pathway; indications and monitoring requirements are stricter |
| Selective GR modulators (SEGRMs/SEGRAs) | Goal: improve the therapeutic index—retain key efficacy while reducing some adverse effects | Separating efficacy from side effects is not equivalent to the old simplistic dichotomy “transactivation = side effects, transrepression = efficacy”; it is better viewed as distinct gene-regulatory spectra/co-regulator recruitment profiles and biased signaling |
Common research or application scenarios
Scenario (research/application) | What it is typically “doing” | Common readouts/methods (research) | Key considerations |
Physiology / stress biology (HPA axis) | During stress/inflammation/fasting: coordinates energy and immune responses; uses negative feedback to restore homeostasis | Cortisol/ACTH dynamics; GR nuclear translocation; transcriptomic changes | “Homeostasis maintenance + stress peaks” belong to one integrated system; timing matters |
Inflammation & immunology basic research | GR reshapes inflammatory gene networks: suppresses excessive inflammation and promotes resolution/convergence | ChIP-seq/ATAC-seq; GRE reporter assays; interactions/tethering with NF-κB/AP-1 | Not simply “turning off immunity”—it’s network remodeling; strong cell-type dependence |
Respiratory: asthma/COPD (ICS as a core therapy) | Suppresses airway inflammation, improves symptoms and reduces exacerbations; a major research focus is steroid insensitivity/resistance | Airway-cell GR/HDAC2; cytokine profiles; clinical endotype stratification | “Steroid resistance” spans multiple layers (GR isoforms, chromatin, oxidative stress, etc.) |
Rheumatology/autoimmunity (RA, SLE, vasculitis, etc.) | Rapidly suppresses inflammatory “peaks,” bridging until immunomodulators/biologics take effect | Inflammation scores, CRP; dose-tapering trials; target-organ assessment | Benefit vs risk depends strongly on dose/duration/route (local vs systemic) |
Dermatology / ophthalmology / ENT (topical, eye drops, nasal sprays) | Suppresses local inflammation while minimizing systemic exposure | Local symptom scales; skin barrier/corneal metrics | “High local potency + low systemic exposure” is a common logic (but long-term use still requires caution) |
Transplantation / allergy & immunosuppression regimens | Suppresses rejection/allergic cascades as one component of multi-drug regimens | Immune-cell profiling; rejection markers; infection monitoring | The core long-term tension is balancing immunosuppression with infection risk |
Oncology & hematology (“supportive therapy + GR biology in some cancers”) | Regimen support (antiemetic/anti-allergy/anti-inflammatory/anti-edema, etc.); GR is also studied in tumor cell fate and drug resistance in some contexts | Apoptosis/transcriptomics; combination studies with chemo/immunotherapy | The same pathway can be beneficial or harmful depending on tumor type and context—interpretation must be cancer-specific and scenario-specific |
Endocrinology: Cushing syndrome (hypercortisolism) and pharmacologic counteraction | Use GR antagonism/modulation to reduce “excess cortisol effects” such as hypertension/hyperglycemia | Clinical endpoints (BP/glucose metabolism/symptoms); safety monitoring | Representative direction: selective GR modulators (e.g., clinical studies of relacorilant) |
Neuropsychiatry / stress-related disease research | Study phenotypes linked to excessive GR activation; explore more “precise” interventions | Animal stress models; brain-region-specific multi-omics; GR-related gene regulation | Emerging tool direction: GR degraders such as PROTACs to “turn down” overly strong GR signaling |
Drug development: improving therapeutic index | Aim to “retain anti-inflammatory benefits while reducing metabolic/bone side effects” | Co-regulator recruitment profiles; tissue selectivity; long-term safety models | Consensus: no longer equivalent to the old “transactivation = side effects / transrepression = efficacy” dichotomy—mechanisms are more complex |
A representative case of “decoupling side effects” | Clinical translation of “decoupled/selective” steroids/modulators | Clinical benefit vs adverse bone/glucose metabolic effects | Example: vamorolone (Agamree) as a representative “selective/decoupled” steroid has received FDA approval (DMD) |
Abbreviations
Latest Research Advances
Level | Directional takeaway | Representative points/examples | Why it matters |
Mechanistic | GR is no longer viewed as a “simple nuclear on/off switch” | New structural & biophysical picture: elucidating GR conformations, inter-domain communication, and how chaperones (Hsp90/Hsp70, etc.) coordinately regulate GR maturation/activation—helping explain “why the same ligand can yield different transcriptional programs.” | Moves “same drug, different efficacy/side effects” from a phenomenon-level observation toward mechanism: differences may arise from conformational and complex-dynamics states. |
| A classic question is still evolving: monomer/dimer/higher-order states | Oligomerization/conformational states are being updated: 2025 work discusses relationships between GR oligomeric conformations and function, indicating the long-standing “monomer vs dimer vs higher-order forms” question is still being refined. | Impacts how we interpret the sources of “transcriptional regulation modes / dose effects / cell-type differences.” |
| The evidence chain linking “isoforms → individual differences” is becoming more systematic | GRα/GRβ and additional isoforms (alternative splicing, alternative translation start sites, etc.) are being more systematically organized, helping explain tissue specificity and inter-individual differences/resistance. | Provides a more citable, actionable mechanistic framework for “individual variability / glucocorticoid resistance.” |
Pharmacology | Moving from “agonist/antagonist” toward “selective modulation + new tool modalities” | Clinical translation of selective/‘decoupled’ steroids: vamorolone has received FDA approval for DMD and is viewed as a milestone toward improving benefit–risk. | Demonstrates that “selective/decoupled” is not just a concept—real-world translation is beginning to emerge. |
| New SEGRMs/SGRMs continue to appear (mostly early-stage) | GRM-01 (2025): animal models suggest an exploratory direction of separating anti-inflammatory efficacy from adverse effects on glucose/bone metabolism (still early/Phase 1–leaning). | Signals that the direction is advancing, but evidence level must be stated cautiously (early-stage/animal). |
| Cushing syndrome: clinical evidence continues to accumulate | relacorilant: includes Phase 3 and extension studies; Phase 3 (GRACE/GRADIENT) and long-term extension studies have reported evidence for improvements in clinical endpoints such as hypertension and glycemic metabolism; regulatory approval should follow official final conclusions. | Represents a practical clinical pathway for “blocking/modulating excessive cortisol effects” that continues to strengthen. |
| A new route: “not antagonism, but degradation” | GR PROTAC degraders (Nature Communications 2023): as research tools/potential therapeutic concepts, representing a new toolchain. | Expands the toolbox from “modulating activity” to “directly removing the receptor.” |
Disease | Glucocorticoid resistance and precision stratification are increasingly emphasized | Severe asthma steroid insensitivity/resistance remains a core challenge; reviews emphasize individualized stratification and summarize multi-layer mechanisms. | Reframes “why some patients don’t respond” from a single-target issue to a “stratification + multi-node network” issue. |
| Genetic variation–phenotype links continue to emerge | Ongoing association studies between NR3C1 variants and asthma severity/control (effects depend on cohort and phenotype definitions). | Reminder: such findings may help explain differences, but over-extrapolation should be avoided. |
Major Bottlenecks
Bottleneck | Core reason (why it’s hard) | What it means for R&D / clinical practice / research |
It is difficult to fully decouple efficacy from side effects | The old dichotomy (“transactivation = side effects / transrepression = efficacy”) is weakening; reality looks more like GR selectively reshaping networks under different tissue/chromatin/co-regulator contexts. | Designing an SEGRM that is “perfect for everyone” is very hard; the same molecule may show different benefit–risk profiles across tissues. |
Large inter-individual variability & lack of pre-treatment predictors | Influenced by many factors—GR isoform ratios, chaperones/co-regulators, local metabolism, epigenetics, etc.—yet stable, generalizable predictive systems are lacking. | In practice, it is hard to predict upfront who will benefit more and who will be more prone to side effects; trial-and-error costs are high. |
Glucocorticoid resistance/insensitivity remains a long-standing pain point | In severe asthma/chronic airway inflammation, resistance involves oxidative stress, chromatin regulation (e.g., HDAC2-related pathways), and multi-step GR signaling imbalance; single-point fixes are often insufficient. | Requires “stratification + combination intervention/multi-target” thinking; a single mechanism is often not enough. |
No robust unified framework for rapid non-genomic effects | Rapid effects (seconds–minutes) are established, but receptor localization, membrane-related mechanisms, and tissue contributions are complex. | “How to leverage/avoid rapid effects” is still hard to engineer; conclusions can vary across models. |
Representative Product Selection Table Related to Glucocorticoids & Receptors
(GR/MR tool compounds × systemic/benchmark & soluble forms × local formulations/sustained-release)
First decide what you’re doing, then choose the table:
Table 1 | Receptor Tool Compounds: GR/MR Modulation, Antagonism, and Probes (Mechanistic Validation / Pathway Dissection)
Category | CAS No. | Aladdin Cat. No. | Name | Specification / Purity | Product application or highlights |
Glucocorticoid receptor-related | GR modulation/antagonism | 1496510-51-0 | Relacorilant | Moligand™, ≥98% | Selective GR modulator/antagonist-direction small molecule; for GR pathway blockade, resistance/metabolic-effect studies, and controls. | |
Glucocorticoid receptor-related | GR antagonist | 2222344-98-9 | ORIC-101 | ≥99% | GR antagonist-direction small molecule; commonly used for GR blockade, combination-mechanism studies, and “anti-glucocorticoid” pharmacology controls. | |
Glucocorticoid receptor-related | Selective GR modulator | 1018679-79-2 | CORT-108297 | ≥97% | Tool compound in the selective GR modulator direction; used to differentiate downstream GR pathways (e.g., transactivation vs transrepression) in mechanistic studies. | |
Glucocorticoid receptor-related | High-affinity GR agonist (research probe) | 1110-40-3 | Cortivazol | _ | Ultra-high-affinity GR agonist probe; for receptor binding/occupancy, signal amplification, and mechanistic validation experiments. | |
Glucocorticoid receptor-related | GR modulation/antagonism | 1496508-34-9 | Dazucorilant | _ | GR modulator/antagonist-direction small molecule; used for “anti-glucocorticoid effects,” stress/metabolism-related pharmacology, and mechanistic controls. | |
Glucocorticoid receptor-related | GR (also PR) antagonist | 84371-65-3 | Mifepristone | Moligand™, ≥98% | Common GR blockade control (also has PR antagonism); used in stress-axis/metabolism and “anti-glucocorticoid effect” mechanism studies. | |
Glucocorticoid receptor-related | Selective GR agonist (research probe) | 74915-64-3 | RU28362 | Moligand™ | Research-grade selective GR agonist tool compound; for receptor signaling pathways, selectivity, and mechanism-dissection experiments. | |
Mineralocorticoid receptor-related | GC biosynthetic precursor/metabolic-pathway control | 152-58-9 | 11-Deoxycortisol / Cortexolone | Moligand™, ≥98% | Mineralocorticoid-like (biased toward MR agonism) control; used for mineralocorticoid/electrolyte-homeostasis models and receptor selectivity studies. | |
Mineralocorticoid receptor-related | MR agonist | 64-85-7 | 11-Deoxycorticosterone | Moligand™, ≥97% (HPLC) | Classic steroid control in the MR-agonist direction; often used to distinguish GR vs MR effects and compare receptor pathways. | |
Mineralocorticoid-like | MR agonist (also GC) | 514-36-3 | Fludrocortisone acetate | ≥98% | Representative mineralocorticoid-like steroid (prominent MR activity, with some GC activity); used as a control for receptor selectivity and electrolyte-homeostasis studies. |
Table 2 | Systemic/Benchmark Glucocorticoids + Standards + Water-Soluble / Injectable Forms
Category | CAS No. | Aladdin Cat. No. | Name | Specification / Purity | Product application or highlights |
Analytical standard / reference standard | Glucocorticoid | 52-21-1 | Prednisolone acetate | Analytical reference standard | Commonly used for LC/LC-MS quantitative calibration, method development, and QC; can also serve as a control for topical/ophthalmic steroid formulations. | |
Analytical standard / standard solution | Glucocorticoid | 83-43-2 | Methylprednisolone standard solution | Moligand™, analytical standard, 100 ng/µl in Acetonitrile | Pre-made standard solution (in acetonitrile) for direct use in LC/LC-MS calibration curves and recovery/matrix-effect evaluation. | |
Analytical standard / standard solution | Glucocorticoid | 378-44-9 | Betamethasone solution reference material in methanol | Moligand™, analytical standard, 1.00 mg/ml | Pre-made standard solution (in methanol) for rapid quantification, method verification, and inter-batch consistency controls. | |
Analytical standard | Endogenous glucocorticoid (corticosterone) | 50-22-6 | Corticosterone | Moligand™, analytical standard | Dominant GC in rodents (commonly used in HPA-axis/stress research); for quantitative assays and endocrine-model controls. | |
Endogenous glucocorticoid | Cell-culture grade | 50-23-7 | H657409 | Hydrocortisone | Moligand™, animal-free, low endotoxin, for cell culture, ≥98% | Endogenous “cortisol” control; animal-free/low endotoxin—better suited for cell-culture supplementation of GC signaling or receptor-activation experiments. |
Endogenous glucocorticoid | Metabolism/enzymology control | 53-06-5 | Cortisone | Moligand™, ≥97% | Requires conversion by 11β-HSD to active cortisol; commonly used as a control for metabolism/enzymology, endocrinology, and receptor studies. | |
Esterified precursor | Glucocorticoid | 50-04-4 | Cortisone acetate | ≥98% (HPLC) | Acetate ester (precursor/esterified form); for metabolism/receptor comparisons and formulation controls. | |
Systemic use | Glucocorticoid | 53-03-2 | Prednisone | Moligand™, ≥98% | Classic systemic GC prodrug; for in vivo anti-inflammatory/immune models and cross-steroid benchmarking. | |
Systemic use / control | Glucocorticoid | 50-24-8 | Prednisolone | ≥98% | Classic systemic GC; often used as an in vivo pharmacodynamics control and for comparing solubility/effect differences among its salts/esters. | |
Systemic use | Glucocorticoid | 14484-47-0 | Deflazacort | Moligand™, ≥98% (HPLC) | Representative systemic steroid; for in vivo anti-inflammatory/immunosuppression models and potency comparisons across GCs. | |
API/GMP raw material | Glucocorticoid | 50-02-2 | Dexamethasone | ≥98% | Suitable as an experimental control for formulation development and process/quality-research studies. | |
Water-soluble salt/solution | Glucocorticoid (phosphate) | 125-02-0 | Prednisolone disodium phosphate | Moligand™, 10 mM in Water | Water-soluble phosphate solution for direct dosing/addition in aqueous systems (cell/in vitro); also commonly used as a control for injectable/water-soluble forms. | |
Water-soluble salt / injectable precursor | Glucocorticoid (phosphate) | 2392-39-4 | Dexamethasone sodium phosphate | Moligand™, ≥98% | Highly water-soluble sodium phosphate; suitable for aqueous cell studies and animal dosing; often used as a potent GR agonist/anti-inflammatory benchmark. | |
Water-soluble salt / injectable precursor | Glucocorticoid (hemisuccinate) | 2375-03-3 | 6α-Methylprednisolone 21-hemisuccinate sodium salt | ≥98% | Water-soluble sodium hemisuccinate (common injectable form); convenient for aqueous preparation and in vivo dosing/rapid-onset controls. | |
Water-soluble salt / injectable precursor | Glucocorticoid (succinate) | 125-04-2 | Hydrocortisone sodium succinate | ≥98% | Highly water-soluble sodium succinate; suitable for aqueous systems and rapid animal dosing—controls for “rapidly usable injectable forms.” | |
Injectable precursor (succinate ester) | Glucocorticoid | 2203-97-6 | Hydrocortisone succinate | ≥95% | Succinate ester increases water solubility (often paired conceptually with the sodium salt); for injection/aqueous preparation and in vivo dosing controls. | |
Parent glucocorticoid | Research/control | 124-94-7 | Triamcinolone | Moligand™, ≥99% | Parent triamcinolone (non-acetonide); for GC anti-inflammatory controls, SAR comparisons, or derivative/formulation research. |
Table 3 | Local-Use Focus (Inhaled/Nasal/Ophthalmic/Topical) + Sustained-Release Injection / Formulation Precursors
Category | CAS No. | Aladdin Cat. No. | Name | Specification / Purity | Product application or highlights |
Local sustained-release injection / topical | Medium-potency glucocorticoid | 76-25-5 | Triamcinolone acetonide | Moligand™, ≥99% | Representative triamcinolone “acetonide” steroid; often used in topical or local sustained-release injection studies as a control for “longer duration/stronger local effect.” | |
Local sustained-release injection | Glucocorticoid (long-acting) | 5611-51-8 | Triamcinolone hexacetonide | ≥98% | Typical long-acting sustained-release (intra-articular/local injection) control; for slow-release kinetics and arthritis/local inflammation model benchmarking. | |
Inhaled / nasal | Glucocorticoid | 5534-09-8 | Beclomethasone dipropionate | Moligand™, ≥98% (HPLC) | Classic inhaled/nasal steroid; dipropionate increases lipophilicity and local action—suitable for respiratory local anti-inflammatory controls. | |
Inhaled / nasal | Prodrug-type glucocorticoid | 126544-47-6 | Ciclesonide | Moligand™, ≥98% (HPLC) | Representative inhaled/nasal prodrug (locally activated); for studying “local action/reduced systemic exposure” mechanisms and formulation strategies. | |
Inhaled / nasal (also local intestinal use) | Glucocorticoid | 51333-22-3 | Budesonide | Moligand™, ≥98% | Classic inhaled/nasal steroid; also commonly used as a local anti-inflammatory control in airway/gut models and formulation research. | |
Inhaled / nasal | Glucocorticoid | 80474-14-2 | Fluticasone propionate | Moligand™, ≥97% | Classic inhaled/nasal steroid control; for airway local anti-inflammatory models, formulation, and stability studies. | |
Inhaled / nasal | Glucocorticoid (long-acting) | 397864-44-7 | Fluticasone furoate | Moligand™, ≥98% | High-potency, long-acting inhaled/nasal representative; for comparing airway local action, receptor potency, and retention properties. | |
Topical / nasal | High-potency glucocorticoid | 83919-23-7 | Mometasone furoate | ≥98% (HPLC) | Representative potent local steroid (commonly topical/nasal); for high-potency local anti-inflammatory controls and formulation research. | |
Ophthalmic local | Glucocorticoid (“soft steroid”) | 82034-46-6 | Loteprednol etabonate | Moligand™, ≥98% (HPLC) | Representative ophthalmic “soft steroid” (designed for rapid metabolic inactivation); for eye-drop/ocular-surface inflammation models and formulation research. | |
Ophthalmic local | Glucocorticoid | 426-13-1 | Fluorometholone | Moligand™, ≥98% (HPLC) | Common ophthalmic steroid control; for ocular local anti-inflammatory testing, eye-drop formulation screening, and stability studies. | |
Ophthalmic local | High-potency glucocorticoid | 23674-86-4 | Difluprednate | Moligand™, ≥98% | Representative potent fluorinated ophthalmic steroid; for eye-drop formulation / intraocular or ocular-surface inflammation model controls and method development. | |
Ophthalmic local | Glucocorticoid | 49697-38-3 | Rimexolone | Moligand™ | Representative ophthalmic steroid; for eye-drop screening, ocular-surface/anterior-segment inflammation models, and control experiments. | |
Topical dermatologic | Low–medium potency glucocorticoid | 638-94-8 | Desonide | Moligand™, ≥99% | Low–medium potency topical steroid control; for skin inflammation models, formulation screening, and permeability/retention evaluation. | |
Topical dermatologic | Medium potency glucocorticoid (ester) | 57524-89-7 | Hydrocortisone 17-valerate | ≥99% | Valerate increases lipophilicity and skin retention; for topical formulation, transdermal, and local efficacy controls. | |
Topical dermatologic | Medium potency glucocorticoid (ester) | 13609-67-1 | Hydrocortisone 17-butyrate | ≥98% (HPLC) | Representative butyrate ester for topical use; for topical formulation screening, local anti-inflammatory controls, and penetration assessment. | |
Topical dermatologic | Prodrug-type glucocorticoid | 74050-20-7 | Hydrocortisone aceponate (Hydrocortisone aceponate) | _ | Prodrug-type topical design (local activation/retention); commonly used for skin inflammation models, formulation, and transdermal evaluation. | |
Topical dermatologic | Medium potency glucocorticoid (ester) | 66734-13-2 | Alclometasone dipropionate | _ | Representative esterified topical steroid; for local skin anti-inflammatory controls and formulation screening. | |
Topical dermatologic | Medium potency glucocorticoid | 25122-57-0 | Clobetasone butyrate | ≥98% | Medium-potency topical steroid representative; for local anti-inflammatory controls, formulation work, and irritancy/tolerability comparisons. | |
Topical dermatologic | Prodrug-type glucocorticoid | 73771-04-7 | Prednicarbate | Moligand™, ≥99% | Prodrug-type topical design (locally activated / reduced systemic exposure tendency); commonly used for topical formulations and pharmacodynamic controls. | |
Topical dermatologic | Medium–high potency glucocorticoid | 2152-44-5 | Betamethasone 17-valerate | ≥98% | Valerate increases lipophilicity and local retention; for topical efficacy, permeation, and formulation-screening controls. | |
Topical dermatologic | Medium–high potency glucocorticoid (pivalate) | 2002-29-1 | Flumetasone pivalate | Moligand™ ≥98% | Pivalate increases lipophilicity and local retention; for topical formulation, permeation/retention, and efficacy control studies. | |
Skin/mucosal local | Glucocorticoid | 152-97-6 | Fluperolone | ≥96% | Representative local-use GC; for skin/mucosal local anti-inflammatory controls and related formulation research. | |
Topical dermatologic | High-potency glucocorticoid | 356-12-7 | Fluocinonide | Moligand™, ≥98% (HPLC) | High-potency topical steroid representative; for skin inflammation models, transdermal/retention evaluation, and formulation optimization. | |
Topical dermatologic | High-potency glucocorticoid (fluocinolone acetonide) | 67-73-2 | Fluocinolone acetonide | Moligand™, ≥98% | Typical potent topical glucocorticoid control; commonly used for skin inflammation/immune-response models, topical formulation screening, and “local retention/permeation” comparative studies. | |
Topical dermatologic | High-potency glucocorticoid | 382-67-2 | Desoximetasone | Moligand™, ≥98% | High-potency topical steroid representative; commonly used for topical anti-inflammatory controls, erythema/edema pharmacodynamic models, and formulation screening. | |
Topical dermatologic | High-potency glucocorticoid | 33564-31-7 | Diflorasone diacetate | Moligand™, ≥98% | High-potency “diacetate” topical representative; for formulation strategies to increase lipophilicity/skin retention and efficacy controls. | |
Topical dermatologic | High-potency glucocorticoid | 59198-70-8 | Diflucortolone valerate | ≥98% | High-potency “valerate” topical representative; for local anti-inflammatory controls, formulation, and skin retention/permeation research. | |
Topical dermatologic | High-potency glucocorticoid (di-ester) | 5593-20-4 | Betamethasone 17,21-dipropionate | ≥97% | Di-ester increases lipophilicity and skin retention; for high-potency topical controls, formulation, and permeation/retention evaluation. | |
Topical dermatologic | Ultra-high potency glucocorticoid | 25122-46-7 | Clobetasol propionate | Moligand™, ≥98% | Ultra-high potency topical steroid representative; for strong anti-inflammatory controls, high-agonism receptor-effect studies, or stringent skin models. | |
Topical dermatologic | Ultra-high potency glucocorticoid | 66852-54-8 | Halobetasol propionate | ≥98% | Ultra-high potency topical steroid representative; for strong anti-inflammatory controls, refractory skin models, and receptor-potency ceiling comparisons. | |
Esterified / lipophilic formulation precursor | Glucocorticoid | 1177-87-3 | D773875 | Dexamethasone acetate | Moligand™, ≥96% | Lipophilic acetate ester; suitable for organic-solvent preparation, local formulations/sustained release, or ophthalmic control studies. |
Esterified / local formulation | Glucocorticoid | 50-03-3 | Hydrocortisone acetate | ≥98% | Acetate ester commonly used for topical/local formulation controls; for formulation screening, stability, and local efficacy studies. | |
Esterified / formulation precursor | Glucocorticoid | 53-36-1 | 6α-Methylprednisolone 21-acetate | ≥98% | Methylprednisolone acetate; commonly used in formulation/sustained-release strategies, SAR comparisons, and control experiments. |
Note: The above are representative Aladdin catalog numbers. For additional specifications, please refer to the product tables at the end of this article or search the official website using the CAS number or product name.
Aladdin: https://www.aladdinsci.com/
