Skip to content Skip to footer

7 Critical Adrenal Washout CT Protocol Steps

The 3-phase adrenal washout CT protocol uses unenhanced, 60-second venous, and 15-minute delayed phases to separate benign adenomas from adrenocortical carcinoma, pheochromocytoma, and metastatic disease using validated HU and washout thresholds.

3-Phase Adrenal Washout CT Protocol: 7 Critical Steps for Accurate Mass Characterisation

At a glance: 3-phase adrenal washout protocol

Phase sequenceUnenhanced → 60-second venous → 15-minute delayed
Tube voltage120 kVp
Tube current150–250 mA (with automatic exposure control)
Pitch1.0
Rotation time0.5 seconds
Contrast volume95 mL non-ionic low-osmolar iodinated contrast
Flow rate3.0 mL/s
Saline chaser100 mL
Key benign thresholdUnenhanced ≤10 HU (lipid-rich); absolute washout >60% or relative washout >40% at 15 minutes (lipid-poor)
Primary scanning pitfallCutting the 15-minute delayed phase short
Primary interpretation pitfallHypervascular pheochromocytoma or metastasis mimicking adenoma washout

1. Introduction: why adrenal washout CT still matters

The 3-phase adrenal washout CT protocol remains one of the most heavily relied-upon problem-solving tools in abdominal imaging. Adrenal nodules are identified incidentally on a substantial proportion of routine abdominal CT examinations performed for unrelated indications, and the overwhelming majority of these are benign, non-functioning cortical adenomas. The clinical challenge is not detecting the adrenal mass — it is confidently separating that common benign adenoma from the rare but consequential adrenocortical carcinoma, metastasis, or pheochromocytoma without subjecting every patient to biopsy or unnecessary surveillance.

This protocol exploits a simple biological fact: benign cortical adenomas are typically rich in intracytoplasmic lipid, which lowers their baseline attenuation, and they take up and then rapidly release iodinated contrast media faster than most other adrenal masses. By acquiring an unenhanced phase, a 60-second venous phase, and a 15-minute delayed phase, the radiology team can calculate quantitative washout percentages that have been validated across decades of literature and remain embedded in current European and American guidelines.

Clinical context At 120 kVp, 150–250 mA, pitch 1.0, with a 95 mL contrast bolus at 3.0 mL/s followed by a 100 mL saline chaser, this protocol is engineered around one principle: timing is the diagnosis. The radiology team is not just acquiring images — it is acquiring a time-attenuation curve, and every minute of delay error propagates directly into the washout calculation.

Despite its long track record, washout CT has come under renewed scrutiny. Recent re-analyses of the foundational literature have questioned whether the 10 HU and washout thresholds were ever properly validated in true incidentaloma populations, and 2023 European Society of Endocrinology (ESE) guidance has shifted toward earlier reliance on hormonal screening.[1,2] This article presents the protocol as it is most widely practised today, while flagging where the evidence base is evolving — because radiographers, radiologists, and referring physicians all need to understand not just how the numbers are generated, but how much weight they should be given.

What follows is a complete operational reference: adrenal anatomy and HU values, the full seven-step scanning technique across 16- to 320-slice platforms, the contrast injection protocol, radiation dose benchmarks, the ten pathologies most likely to appear on an adrenal washout study, and — critically — a three-tier pitfall framework covering the distinct failure modes of radiographers, radiologists, and the non-radiology physicians who order and act on these reports.

The scale of the problem: why this protocol exists

Adrenal incidentalomas are detected on a meaningful fraction of all abdominal CT scans performed for entirely unrelated reasons, with reported prevalence rising with patient age and scan resolution. The vast majority — typically well over 80% in unselected incidentaloma cohorts — turn out to be non-functioning, benign cortical adenomas of no clinical consequence. Yet within that population sits a small minority of adrenocortical carcinomas, functioning tumours secreting cortisol, aldosterone, or catecholamines, and metastatic deposits from a primary malignancy elsewhere in the body.[4,9]

This statistical reality is precisely why a quantitative, reproducible imaging test matters so much. Sending every incidentally discovered adrenal nodule to biopsy or surgical excision would expose a very large number of patients with entirely benign disease to unnecessary procedural risk, cost, and anxiety. Conversely, dismissing every adrenal nodule as “probably an adenoma” without any quantitative threshold would inevitably miss a proportion of clinically important disease. The 3-phase washout protocol sits precisely at this decision point, translating a qualitative visual impression into a number that can be tracked, audited, and compared against a published threshold.

It is worth being explicit, however, that this is an area of active scientific debate. Recent large reanalyses — including a 2025 publication provocatively titled to question whether washout CT’s era is ending — have argued that several of the foundational washout studies were conducted in selected surgical or oncology populations rather than true unselected incidentaloma cohorts, and that real-world diagnostic performance in general radiology practice may be lower than the original thresholds imply.[1,7] This article presents the protocol as it is currently and widely practised, while being transparent about where the evidence is shifting, so that radiographers, radiologists, and clinicians can apply appropriate clinical judgement rather than mechanical rule-following.

There is also a straightforward health-economic argument for getting this protocol right. A single avoidable indeterminate result — caused by a truncated delayed phase, an inconsistent ROI, or an overly hedged report — does not simply disappear; it typically generates a follow-up MRI, a repeat CT at a later interval, an endocrinology referral, or in some cases a biopsy, each carrying its own cost, scheduling burden, and patient anxiety. Multiplied across the volume of adrenal incidentalomas a busy department encounters annually, the cumulative cost of avoidable indeterminate results is a meaningful departmental quality metric in its own right, distinct from the headline diagnostic accuracy of the protocol itself.

2. Adrenal anatomy and Hounsfield unit reference values

The adrenal glands sit in the retroperitoneal fat superomedial to each kidney, draped over the diaphragmatic crura. The right adrenal gland is typically pyramidal or triangular and lies posterior to the inferior vena cava, lateral to the right diaphragmatic crus, and superior to the right kidney’s upper pole. The left adrenal gland is more crescentic or arrowhead-shaped, lying medial to the upper pole of the left kidney, posterior to the pancreatic tail and splenic vessels, and lateral to the aorta. Each normal gland measures roughly 2–6 cm in length with limbs (the medial and lateral crura) typically less than 10 mm in thickness; any limb thickening beyond this raises suspicion for hyperplasia or infiltrative disease.

Functional anatomy: cortex and medulla

Each gland is composed of an outer cortex and inner medulla with distinct embryological origins, hormone products, and — critically for this protocol — distinct lipid content:

  • Zona glomerulosa (outermost cortex) — produces aldosterone; the source of primary aldosteronism when adenomatous.
  • Zona fasciculata (middle cortex, the bulk of the gland) — produces cortisol; the most lipid-rich layer and the principal reason cortical adenomas are often low-attenuation on unenhanced CT.
  • Zona reticularis (innermost cortex) — produces androgens.
  • Medulla — neural crest-derived chromaffin tissue producing catecholamines; the origin of pheochromocytoma.

Vascular supply and venous drainage

The adrenal gland has a unique triple arterial supply: the superior adrenal artery from the inferior phrenic artery, the middle adrenal artery arising directly from the aorta, and the inferior adrenal artery from the renal artery. Venous drainage is asymmetric and clinically important for adrenal vein sampling: the right adrenal vein drains directly and very short into the posterolateral inferior vena cava, while the left adrenal vein drains inferiorly into the left renal vein, typically joined by the left inferior phrenic vein. This asymmetry explains why right-sided adrenal vein catheterisation is technically more demanding during aldosteronoma localisation studies.

This same triple-supply, single-dominant-vein anatomy is directly relevant to laparoscopic and robotic adrenalectomy planning, where the surgical team relies on preoperative CT to anticipate vessel position and anatomical variants before the operative approach is chosen. A radiology report for a surgical candidate that simply states “adrenal mass present” without describing its relationship to the adjacent renal vessels, IVC, or splenic vessels provides materially less value to the operating surgeon than one that explicitly addresses these relationships, particularly for larger masses where vascular displacement or encasement changes the surgical approach.

Embryological origin and why it matters on imaging

The cortex and medulla arise from entirely different embryological tissues, and this distinction is not merely academic — it explains the imaging behaviour of every pathology discussed later in this article. The cortex develops from mesodermal coelomic epithelium adjacent to the developing gonad, which is why ectopic adrenocortical tissue can occasionally be found along the gonadal descent pathway. The medulla is neuroectodermal in origin, derived from migrating neural crest cells that also give rise to the sympathetic paraganglia — the same embryological lineage shared by extra-adrenal paragangliomas, which is why pheochromocytoma and paraganglioma are considered part of a single biological spectrum despite differing in anatomical location.

Lymphatic drainage

Adrenal lymphatic drainage follows the venous pathways closely: on the right, lymphatics drain toward the lateral aortic and retrocaval nodal groups; on the left, drainage follows the left renal vein toward the left para-aortic and renal hilar nodes. This matters directly for adrenocortical carcinoma staging, where nodal involvement along these specific chains should be actively sought on the same study, rather than relying on a generic “no significant lymphadenopathy” statement.

Relevant clinical anatomy: adrenal vein sampling and percutaneous biopsy approach

When a functioning aldosteronoma is suspected, adrenal vein sampling (AVS) is frequently required to lateralise the source of excess hormone production before surgery, since CT morphology alone is an unreliable predictor of which gland — or which nodule within a gland — is functionally responsible. The marked asymmetry in venous anatomy described above makes the right adrenal vein technically the more difficult target to catheterise selectively, owing to its short length and oblique, often variable, entry point into the posterolateral IVC; this is one of the most common reasons AVS procedures are reported as technically unsuccessful or non-lateralising.

For percutaneous biopsy of an indeterminate adrenal mass — reserved for cases where imaging and biochemical workup remain genuinely inconclusive — the approach is typically posterior or posterolateral, threading between the lung base, diaphragm, and kidney while avoiding the spleen on the left and the liver and IVC on the right. Biopsy is rarely required when the 3-phase washout protocol yields a clear benign result, which is precisely the cost-saving and risk-reducing rationale for performing the protocol correctly in the first place.

Normal variants and anatomical pitfalls

Several normal anatomical variants are routinely mistaken for pathology on adrenal CT, and recognising them prevents unnecessary downstream workup. A prominent, broad-based “Mercedes-Benz” or inverted-Y configuration of the limbs is a normal variant in many patients and should not by itself be read as nodular enlargement. Adjacent structures are also frequently misread as adrenal pathology: a tortuous splenic artery or vein looping near the left gland, a prominent gastric diverticulum adjacent to the left adrenal bed, or an accessory spleen sitting in the expected location of the left gland can all mimic a left adrenal nodule on a single axial slice. Multiplanar reformatting — reviewing coronal and sagittal reconstructions rather than relying on the axial plane alone — resolves the great majority of these pseudo-lesion pitfalls before they reach the report.

Right-sided pseudo-nodules are less common but occur where a prominent diaphragmatic crus or an adjacent hepatic lesion abutting the gland creates partial-volume averaging that suggests a discrete adrenal mass. In every case, the practical safeguard is the same: confirm that the suspected lesion is genuinely intrinsic to the gland on at least two imaging planes before committing it to a formal washout calculation, since an ROI placed partly on adjacent fat or vessel will produce a meaningless and potentially misleading attenuation value.

Adrenal and adrenal mass attenuation reference values
Structure / massUnenhanced HUVenous phase HU15-min delayed HUTypical washout pattern
Normal adrenal gland10–25 HU60–120 HU30–60 HURapid washout
Lipid-rich adenoma≤10 HU40–90 HU15–35 HURapid (diagnostic by unenhanced HU alone)
Lipid-poor adenoma10–30 HU60–110 HU20–45 HUAPW >60% / RPW >40%
Adrenocortical carcinoma20–45 HU (heterogeneous)70–130 HU55–110 HUSlow, incomplete washout
Metastasis20–40 HU60–120 HU45–95 HUSlow washout; overlaps with ACC
Pheochromocytoma10–40 HU100–180+ HU (avid)Variable — up to 25% show adenoma-like washoutUnreliable; biochemical correlation mandatory
Myelolipoma−30 to −90 HU (macroscopic fat)Variable, fat-containingVariablePathognomonic on fat attenuation, not washout
Adrenal cyst0–20 HU (near water)No enhancementNo enhancementNon-enhancing; thin wall
Acute adrenal haemorrhage50–90 HU (acute)Non-enhancing coreNon-enhancingDensity falls over weeks as it resolves
Adrenal hyperplasia10–30 HU, smooth thickened limbsDiffusely enhancingDiffuse washoutBilateral, limb thickness >10 mm
Anatomical pitfall The adrenal limb-thickness measurement must be taken perpendicular to the long axis of the limb, not as an oblique diagonal measurement, which can overestimate true thickness by several millimetres and falsely suggest hyperplasia in a normal gland.
🩻

Standardise adrenal protocol delivery across every scanner in your department

SATMED Health helps radiology teams build consistent, guideline-aligned contrast and timing protocols that travel with the patient, not the machine.

Explore Adrenal Protocol Solutions →

3. Scanning technique: the 7-step protocol

The 3-phase adrenal washout protocol is unforgiving of timing errors. Every step below is built around protecting the integrity of the three attenuation measurements that the entire diagnosis depends on.

  1. 1
    Patient preparation and positioning. Position the patient supine, arms raised above the head to eliminate streak artifact across the upper abdomen. Confirm fasting status if local policy requires it, screen renal function (eGFR) and prior contrast reaction history, and place a large-bore (18–20 gauge) antecubital intravenous line capable of sustaining a 3.0 mL/s injection. Explain the full duration of the examination to the patient before beginning — including the 15-minute interval between the second and third phases — since patients who understand they will be lying still, intermittently, for over twenty minutes in total are considerably less likely to move or request early removal from the table than those who were told only “this will be quick.”
  2. 2
    Unenhanced acquisition. Acquire a true non-contrast scan through the adrenal beds at 120 kVp, 150–250 mA with automatic exposure control, 0.5 second rotation time, and pitch 1.0. This unenhanced phase is non-negotiable — without it, only the relative (not absolute) washout percentage can be calculated, and the 10 HU lipid-rich threshold cannot be applied at all.
  3. 3
    Region-of-interest planning on the unenhanced phase. Place a region of interest (ROI) of at least 1 cm² (avoiding partial-volume averaging at the lesion margin) on the unenhanced image and record the mean HU. This value becomes the fixed reference point for every subsequent washout calculation, so it must be placed identically on each subsequent phase.
  4. 4
    Contrast injection. Power-inject 95 mL of low-osmolar non-ionic iodinated contrast at 3.0 mL/s, immediately followed by a 100 mL saline chaser at the same flow rate to maximise bolus compactness and reduce residual contrast dead-space in the tubing and central veins.
  5. 5
    Venous phase acquisition at 60 seconds. Acquire the second phase at a fixed 60-second delay from the start of injection (not a bolus-tracking trigger, since the adrenal glands are not the primary target of arterial enhancement). Re-measure the identical ROI and record the venous HU.
  6. 6
    Delayed phase acquisition at 15 minutes. Acquire the third and final phase at exactly 15 minutes post-injection. This interval is the single most common point of protocol failure in busy departments — flag the patient, set a timer, and do not allow table turnover pressure to compress this window.
  7. 7
    Washout calculation and documentation. Calculate the absolute percentage washout (APW) as [(venous HU − delayed HU) ÷ (venous HU − unenhanced HU)] × 100, and the relative percentage washout (RPW) as [(venous HU − delayed HU) ÷ venous HU] × 100. Document all three raw HU values alongside the calculated percentages in the report — not just the final classification — so any subsequent reviewer can audit the calculation.
Worked example Consider a 2.1 cm right adrenal nodule with an unenhanced attenuation of 18 HU, a venous-phase attenuation of 95 HU, and a delayed-phase attenuation (at a verified 15 minutes) of 32 HU. APW = [(95 − 32) ÷ (95 − 18)] × 100 = (63 ÷ 77) × 100 ≈ 82%, comfortably above the 60% benign threshold. RPW = [(95 − 32) ÷ 95] × 100 = (63 ÷ 95) × 100 ≈ 66%, also above the 40% benign threshold. Both calculations concur, supporting a confident classification as a lipid-poor adenoma — provided the morphology (smooth margin, homogeneous texture, no growth on comparison with prior imaging) is concordant. If the delayed phase had instead been acquired at 9 minutes rather than 15 due to a rushed workflow, the measured delayed HU would likely have been higher (less contrast washed out), artificially lowering both APW and RPW and potentially pushing a genuinely benign adenoma into the indeterminate range — precisely the scanning pitfall discussed later in this article.
Scanner platform comparison: adrenal washout protocol adaptation
Platform classTypical configurationAdrenal-specific adaptation
16-slice0.625–1.25 mm collimationSlightly longer rotation times reduce temporal resolution; ensure the 15-minute timer starts at injection, not at venous-phase acquisition, to avoid drift
64-slice0.625 mm collimation, sub-second rotationStandard workhorse configuration for this protocol; thin-section reconstructions (≤1.5 mm) improve small-lesion ROI accuracy
128–256-sliceWide-detector, dual-source capableEnables simultaneous dual-energy acquisition on the venous phase, allowing virtual unenhanced reconstruction as an internal cross-check
320-sliceVolumetric single-rotation coverageWhole-organ coverage in one rotation reduces motion misregistration between unenhanced and venous ROI placement

Dual-energy and photon-counting CT adaptations

Dual-energy CT (DECT) has matured into a genuinely useful adjunct for adrenal characterisation rather than a research curiosity. By generating virtual unenhanced (VUE) images directly from the contrast-enhanced venous phase, DECT can in principle estimate the unenhanced attenuation without a separate non-contrast acquisition — directly reducing dose. However, validation studies report important caveats.

The underlying physics matters for how these caveats manifest in practice. Dual-source and rapid kVp-switching systems acquire two genuinely separate energy spectra nearly simultaneously, while dual-layer detector systems separate low- and high-energy signal at the detector level from a single x-ray source and acquisition — each approach has slightly different noise characteristics and material decomposition accuracy, which is precisely why virtual unenhanced thresholds validated on one platform have not transferred cleanly to another without local recalibration. A department adopting VUE-based adrenal characterisation for the first time should not assume the published 10 HU lipid-rich threshold applies unmodified to their specific vendor and software version; published validation work has shown the adjusted threshold can sit closer to 20–22 HU on some dual-layer platforms once a systematic positive offset is accounted for.[18]

Dual-energy and photon-counting CT protocol comparison for adrenal lesions
TechniqueMechanismReported performancePractical caveat
Dual-source DECT (virtual unenhanced)Material decomposition of venous-phase acquisitionStrong correlation with true unenhanced HU in several cohorts[17]One dual-layer validation series found VUE overestimated attenuation, reducing sensitivity for the 10 HU threshold unless an adjusted cutoff (~22 HU) is applied[18]
Dual-layer detector DECTDepth-based spectral separation, single sourceHigh correlation between VUE and true unenhanced in adenomas and abdominal soft tissue[18]Threshold recalibration required per-vendor; do not assume thresholds are interchangeable across platforms
Iodine density mappingQuantifies iodine concentration independent of HUImproves separation of adenoma from metastasis when combined with VUE[24]Requires spectral-capable reconstruction software at time of reporting, not just acquisition
Photon-counting CT (PCCT)Direct photon energy discrimination, no scintillatorImproved spectral separation and noise performance at lower dose in early abdominal seriesAdrenal-specific washout validation literature is still maturing; treat as an emerging adjunct, not a protocol replacement

Deep learning reconstruction (DLR)

Deep learning reconstruction algorithms — distinct from AI lesion-classification tools discussed later in this article — denoise the raw projection or image data itself, allowing tube current or kVp reduction while preserving diagnostic image quality. For adrenal protocols specifically, DLR is most valuable on the unenhanced phase, where noise has historically forced technologists to choose between a higher dose and a noisier ROI measurement. Departments adopting DLR on 64-slice-and-above platforms have generally been able to reduce unenhanced-phase mA by 20–35% without measurably degrading ROI reproducibility, though formal adrenal-specific validation data remains limited and vendor-dependent; confirm performance with your own phantom or retrospective audit before relying on it clinically.

Technique tip Save the unenhanced-phase ROI coordinates (not just the value) if your PACS or workstation supports ROI propagation. Reapplying the identical ROI geometry on the venous and delayed phases — rather than eyeballing a “similar” location — removes one of the largest sources of intra-observer washout calculation variability.

Equipment calibration and reproducibility across scanners

Because this protocol depends on absolute HU values being comparable across three separate acquisitions, and ideally across separate examinations over time for surveillance purposes, scanner calibration is not a peripheral physics concern but a direct determinant of diagnostic reliability. Routine CT quality assurance programmes should specifically verify HU accuracy and stability for water and standard reference phantom materials at the kVp used in this protocol, and any scanner showing drift outside locally defined tolerance should be flagged before it is used for adrenal washout studies, since a systematic HU offset of even a few units can shift a genuinely borderline lesion across the benign threshold in either direction.

For departments running adrenal washout protocols across multiple scanners — common in larger hospital networks — establishing that HU measurements are reasonably consistent between platforms, and ideally cross-calibrated against a shared phantom, materially increases confidence when a follow-up examination for the same patient is performed on a different machine than the original study.

4. Contrast media protocol

Because the entire diagnostic logic of this protocol depends on a contrast time-attenuation curve, the injection parameters are not interchangeable with a generic abdominal CT protocol. Consistency between the venous and delayed measurements requires a bolus delivered the same way, every time.

3-phase adrenal washout contrast injection protocol
ParameterValueRationale
Contrast agentLow-osmolar, non-ionic iodinated contrast (typically 300–370 mg I/mL)Minimises injection-site discomfort and contrast reaction risk versus older ionic agents
Volume95 mLSufficient bolus mass to generate measurable venous-phase enhancement in adrenal tissue without unnecessary iodine load
Flow rate3.0 mL/sBalances adequate bolus compactness with venous access tolerance through an 18–20 gauge cannula
Saline chaser100 mLClears residual contrast from tubing and proximal veins, sharpening the bolus and reducing streak artifact from pooled contrast in the SVC/brachiocephalic veins
Venous phase delay60 seconds fixed delayTargets portal-venous equilibrium phase rather than arterial peak, since adrenal lesion characterisation depends on equilibrium-phase and delayed kinetics, not arterial vascularity alone
Delayed phase delay15 minutes fixed delayThe validated interval at which benign adenomas have washed out the majority of retained contrast while most non-adenomas have not

Pre-procedure renal function screening follows standard institutional contrast safety protocols; patients with significantly reduced eGFR may require modified hydration or, where clinically appropriate, an unenhanced-only limited protocol with deferral of washout calculation. Patients with a history of severe contrast reaction require premedication per local policy or consideration of an alternative non-contrast pathway (chemical-shift MRI) for adenoma characterisation where lipid-rich features are suspected.

Monitoring during the 15-minute interval

The mandatory 15-minute gap between the venous and delayed phases is not idle time. It is the window in which the injection site should be visually checked for delayed extravasation, the patient should be monitored for any delayed contrast reaction symptoms, and venous access should be confirmed as still patent in case the delayed phase reveals a need for an additional targeted acquisition. Departments that treat this interval purely as a scheduling inconvenience — rushing the patient out of the room and back in — both increase the risk of the primary scanning pitfall (a truncated delay) and lose a built-in safety monitoring opportunity.

Venous access should be re-confirmed, not assumed, immediately before the delayed acquisition; a line that has tissued or a patient who has needed to reposition can silently undermine the comparability of the delayed-phase measurement if a second, smaller “rescue” bolus is inadvertently given rather than recognising the line has failed.

Safety check Before injection, confirm the patient does not have a clinical or biochemical suspicion of pheochromocytoma unless adequate alpha-blockade or institutional safety pathway is already in place. While modern non-ionic contrast carries a substantially lower catecholamine-surge risk than older ionic agents, departments should still follow local policy regarding premedication or monitoring in suspected pheochromocytoma referrals.

When CT washout is not the right tool: MRI and special patient groups

Chemical-shift MRI offers an alternative, non-ionising route to characterising lipid-rich adenomas, exploiting the same intracytoplasmic lipid signature that drives the low unenhanced HU on CT, but detecting it through signal drop-out between in-phase and opposed-phase sequences rather than attenuation. This is a particularly useful alternative pathway for patients in whom repeated CT radiation exposure is a concern — young patients with an incidentaloma requiring interval surveillance, or patients who have already accumulated substantial cumulative dose from prior oncological staging studies. MRI does not, however, reliably replace CT washout for lipid-poor adenomas, where the contrast kinetics captured by the delayed CT phase have no direct MRI equivalent with comparable validation.

Pregnant patients with a suspected adrenal mass requiring urgent characterisation — most commonly in the context of suspected pheochromocytoma presenting with hypertensive crisis — should generally be directed toward MRI without gadolinium-based contrast in the first instance, reserving CT washout for situations where MRI is unavailable, contraindicated, or non-diagnostic, and always in direct discussion with the obstetric and endocrine teams regarding the urgency-versus-radiation trade-off. Paediatric adrenal masses differ sufficiently in their differential diagnosis — neuroblastoma being a key consideration rarely relevant in adults — that this adult-oriented washout protocol should not be applied unmodified to children without paediatric radiology input on both technique and interpretation.

💧

Reduce contrast variability between injectors and sites

SATMED Health’s injection-protocol tools help keep bolus timing, volume, and flow rate consistent across every scanner and every shift.

Explore Contrast Delivery Solutions →

5. Radiation dose benchmarks and reduction

A 3-phase protocol inherently delivers more radiation than a single-phase abdominal CT, since the adrenal beds are imaged three separate times. This makes dose optimisation at each phase — particularly the unenhanced phase, which contributes diagnostic value disproportionate to its dose if performed correctly — a genuine clinical priority rather than a box-ticking exercise.

Indicative diagnostic reference levels — 3-phase adrenal CT (adult standard-sized patient)
PhaseCTDIvol (mGy)DLP (mGy·cm)Effective dose (mSv)SSDE (mGy)
Unenhanced8–14120–2201.8–3.39–16
Venous (60s)9–15140–2402.1–3.610–17
Delayed (15 min)8–14120–2201.8–3.39–16
Total (3 phases)380–6805.7–10.2

These figures are indicative benchmarks consistent with the framework set out in ICRP Publication 135 and the European Society of Radiology literature review on CT diagnostic reference levels[13,14]; departments should establish and audit their own local DRLs against national survey data rather than treating any single published figure as a universal target, since scanner generation, reconstruction algorithm, and patient body habitus all materially shift the achievable dose for equivalent image quality.

Understanding the dose metrics in this table

CTDIvol describes the dose delivered to a standard reference phantom and is the metric most directly comparable across scanners and institutions, but it does not represent dose to an individual patient. Size-specific dose estimate (SSDE) corrects CTDIvol for the patient’s actual cross-sectional dimensions, and is the more clinically meaningful figure when comparing dose between a slender and an obese patient undergoing the identical nominal protocol. DLP integrates dose over the full scan length and is the figure used to estimate effective dose via region-specific conversion factors — useful for population-level risk communication, but, like all effective dose estimates, an approximation rather than a patient-specific measurement.

For a 3-phase protocol specifically, the cumulative DLP across all three acquisitions is the single most useful number to track at a departmental level, since it captures the full radiation burden of the complete examination rather than any individual phase in isolation. Departments performing high volumes of adrenal washout studies should periodically audit their own cumulative DLP distribution against the benchmark ranges above, flagging outlier cases for review rather than waiting for an external accreditation cycle to surface a systematic dose creep.

Five dose reduction strategies

  1. Limit the anatomical coverage of each phase. The venous and delayed phases do not need to cover the entire abdomen and pelvis if the unenhanced phase has already localised the lesion — a focused adrenal-bed acquisition on the later phases meaningfully reduces total DLP.
  2. Apply automatic exposure control (AEC) consistently across all three phases. Manually fixing mA “for consistency” across phases often means over-radiating the smaller-coverage delayed acquisition; AEC should be allowed to modulate per phase based on attenuation.
  3. Adopt iterative or deep learning reconstruction on the unenhanced phase specifically. Because the unenhanced HU measurement is the most noise-sensitive of the three (low-contrast, low-attenuation tissue), modern reconstruction algorithms allow meaningful mA reduction here without compromising the 10 HU threshold’s reliability.
  4. Consider omitting the unenhanced phase when prior imaging exists. If a genuinely unenhanced CT of the same lesion exists in the patient’s history within a clinically reasonable timeframe, some departments avoid re-acquiring it — though this requires confident, auditable access to the prior study and should follow a documented local policy, not ad hoc clinician discretion.
  5. Use dual-energy virtual unenhanced reconstruction where validated locally. As detailed in the scanning technique section, DECT-derived virtual unenhanced images can in principle replace the physical unenhanced acquisition entirely, removing one full phase of radiation — but only after local threshold validation, since reported sensitivity varies by vendor and detector technology.[17,18]

Quality assurance and departmental audit

Beyond per-patient dose tracking, departments performing this protocol at meaningful volume benefit from periodic structured audit: sampling a quarter’s worth of adrenal washout studies and confirming, independently of the original report, that the unenhanced phase truly preceded contrast, that the venous-to-delayed interval was genuinely 15 minutes (not just labelled as such in the protocol name), and that cumulative DLP figures sit within the locally agreed benchmark range. This kind of retrospective audit is one of the few reliable ways to catch a systematic workflow drift — for example, a scheduling change that has quietly compressed the delayed-phase interval across an entire department — before it accumulates into a meaningful body of mis-classified studies.

Alignment with international guidance This dose framework is aligned with the European Commission’s Radiation Protection N° 185 diagnostic reference level guidance, the American Association of Physicists in Medicine (AAPM) CT dose optimisation practice recommendations, and ICRP Publication 135 on diagnostic reference levels in medical imaging.[13]

6. Top 10 adrenal pathologies on washout CT

Adrenal incidentalomas span a spectrum from entirely benign and clinically irrelevant through to rare, aggressive malignancy. The cards below summarise the ten conditions most likely to be encountered on a 3-phase adrenal washout study, and — critically — how each one interacts with (or defeats) the washout calculation itself.

Suggested structured reporting elements Regardless of final classification, a complete adrenal washout report should explicitly state: lesion size in three dimensions, laterality, unenhanced HU, venous-phase HU, delayed-phase HU (with the actual delay time achieved, not assumed), calculated APW and RPW, margin and homogeneity description, comparison with any prior imaging, and an explicit recommendation (no further action / interval follow-up / additional imaging / endocrine referral / biochemical screening / biopsy consideration). Reports that state only the final classification without the underlying numbers deny subsequent reviewers — including the radiologist’s own future self — the ability to audit how that conclusion was reached.
1

Lipid-rich adenoma

≤10 HU unenhanced

The most common adrenal incidentaloma. Diagnosed directly from the unenhanced phase alone — washout calculation is not even required. Protocol impact: confirms the unenhanced phase is non-negotiable in this protocol’s design.

2

Lipid-poor adenoma

10–30 HU unenhanced; APW >60% / RPW >40%

Indistinguishable from non-adenomas on unenhanced HU alone. Requires the full 3-phase washout calculation to confirm benignity. Protocol impact: the entire rationale for the venous and delayed phases. Lipid-poor adenomas account for a substantial minority of all adenomas — roughly a quarter to a third in most surgical series — meaning the washout phases are doing genuine diagnostic work in a non-trivial proportion of incidentaloma referrals, not merely confirming a foregone conclusion.

3

Adrenocortical carcinoma (ACC)

20–45 HU, heterogeneous, often >4 cm

Rare but aggressive; shows slow, incomplete washout, irregular margins, internal necrosis, and occasionally calcification. Protocol impact: size and morphology must be reported alongside washout — a large heterogeneous mass with “borderline” washout is not reassuring. ACC carries a poor prognosis when diagnosis is delayed, making this the single pathology in this list where a missed or downgraded diagnosis carries the highest individual clinical consequence, despite its rarity relative to benign adenoma.[12]

4

Adrenal metastasis

20–40 HU unenhanced; slow washout, overlaps with ACC

The second most common reason for an indeterminate adrenal mass in oncology patients. Protocol impact: clinical history of primary malignancy should lower the threshold for biopsy even with borderline washout values. Lung and renal cell primaries are particularly frequent sources of adrenal metastatic disease, and bilateral involvement should prompt active staging review rather than being dismissed as bilateral hyperplasia.

5

Pheochromocytoma

Avid venous enhancement; washout unreliable in up to 25%

A biochemical, not purely radiological, diagnosis. Protocol impact: washout CT alone cannot safely exclude pheochromocytoma — plasma free metanephrines remain essential whenever clinical suspicion exists.[10,11] Classic but inconsistent CT features include marked, avid enhancement and occasional cystic or haemorrhagic degeneration in larger tumours; the clinical triad of episodic headache, palpitations, and diaphoresis should prompt biochemical screening regardless of how the CT appears.

6

Myelolipoma

−30 to −90 HU (macroscopic fat)

Benign and diagnosed on fat attenuation alone, not washout kinetics. Protocol impact: a wide-window, fat-sensitive ROI placement avoids a falsely “indeterminate” classification from averaging fat with adjacent soft tissue. Composed of mature adipose tissue interspersed with haematopoietic elements, myelolipomas can occasionally grow large enough to cause local mass effect or, rarely, spontaneous haemorrhage, but malignant transformation is essentially unreported.

7

Adrenal cyst

0–20 HU, non-enhancing, thin wall

Benign and essentially never requires washout calculation, since the defining feature is the complete absence of enhancement on the venous phase. Protocol impact: confirm true non-enhancement rather than assuming based on unenhanced HU alone. Wall thickening, septation, or any internal enhancing nodularity should prompt reclassification away from simple cyst toward a more concerning cystic neoplasm or degenerated haemorrhagic lesion.

8

Acute adrenal haemorrhage

50–90 HU acute, non-enhancing

Often unilateral, associated with trauma, anticoagulation, or critical illness (Waterhouse–Friderichsen-type physiology). Protocol impact: clinical correlation and short-interval follow-up to confirm density resolution distinguishes haemorrhage from a true enhancing mass. Bilateral adrenal haemorrhage is a recognised, time-critical cause of acute adrenal insufficiency and should prompt urgent endocrine consultation rather than routine outpatient follow-up.

9

Adrenal hyperplasia

10–30 HU, bilateral, limb thickness >10 mm

Diffuse rather than focal; relevant to primary aldosteronism and ACTH-dependent Cushing syndrome workups. Protocol impact: limb-thickness measurement technique (perpendicular, not oblique) materially affects whether this diagnosis is even considered. Macronodular hyperplasia in particular can mimic bilateral adenomas on cross-sectional imaging, and distinguishing the two patterns often depends as much on the biochemical and clinical picture as on the CT appearance itself.

10

Granulomatous infection (e.g., tuberculosis, histoplasmosis)

Variable, often bilateral enlargement ± calcification

An important differential in endemic regions and immunocompromised patients, occasionally progressing to adrenal insufficiency. Protocol impact: bilateral symmetric enlargement with calcification should prompt infectious and granulomatous differentials before assuming bilateral metastatic disease. A relevant travel, exposure, or immunosuppression history — actively sought rather than incidentally volunteered — often does more to narrow this differential than any single imaging feature.

Building a differential diagnosis from the washout calculation

None of these ten entities is reliably separated from the others by a single isolated data point. A practical reporting approach treats the unenhanced HU, the washout percentages, the lesion size, the margin characteristics, and the clinical history as a single integrated picture rather than a checklist applied in isolation. A 3 cm, smoothly marginated, homogeneous nodule with unenhanced attenuation of 8 HU requires no further discussion of washout at all — it is diagnostic of a lipid-rich adenoma on the unenhanced phase alone. A 5 cm heterogeneous mass with central necrosis and an absolute washout of 58% — technically just below the 60% benign threshold — should not be reported as “probably benign, just under threshold,” because the morphology alone in a mass of this size already raises adrenocortical carcinoma as a leading concern regardless of the washout number.[3,12] This is the central interpretive skill the radiologist pitfalls section below addresses in detail.

A third illustrative scenario worth holding in mind: a 1.8 cm right adrenal nodule, stable in size over two prior CT examinations spanning several years, with an unenhanced attenuation of 24 HU and an absolute washout of 52%. Taken in isolation at a single time point, this falls into genuinely indeterminate territory by the conventional thresholds. Taken together with the documented multi-year size stability, most experienced reviewers would reasonably favour a benign, slowly evolving lesion over an aggressive process — illustrating why access to, and active comparison with, prior imaging is frequently as diagnostically valuable as the washout calculation performed at any single visit.

📊

Bring structured washout reporting to every adrenal case

SATMED Health supports structured, auditable HU and washout documentation so every reviewer can see exactly how a classification was reached.

Explore Structured Reporting Solutions →

7. Pitfalls for radiographers

The primary scanning pitfall in this protocol is failing to wait the full 15 minutes for the delayed phase. Cutting the delay short prevents accurate washout calculations, leaving an otherwise classifiable mass indeterminate — and triggering exactly the follow-up imaging or biopsy this protocol exists to avoid.

This pitfall is particularly insidious because it rarely produces an obviously wrong-looking image. A delayed phase acquired at 10 or 11 minutes instead of 15 still looks like a perfectly reasonable delayed-phase scan to the eye — the error only becomes apparent at the calculation stage, when the washout percentage comes out lower than it should, and by then the patient has often left the department. Departments under throughput pressure are especially vulnerable to this failure mode, because a 15-minute mandatory gap per adrenal patient represents genuine lost table time that scheduling systems do not always account for. The mitigation is therefore as much about departmental workflow design — building the 15-minute interval explicitly into the appointment slot length — as it is about individual technologist vigilance.

Radiographer scanning pitfalls — 3-phase adrenal washout CT
CategoryDescriptionMitigation
Delayed-phase timingAcquiring the delayed phase before the full 15 minutes have elapsed under time or workflow pressureUse a dedicated, visible timer triggered at the start of injection, not at the end of the venous-phase acquisition; do not allow the scanner room to be vacated for another patient before the timer completes
ROI placement inconsistencyPlacing the unenhanced, venous, and delayed ROIs in slightly different positions within the lesion, introducing spurious washout variationUse ROI propagation tools where available; otherwise, document the exact slice level and approximate coordinates used for replication
Venous-phase trigger errorUsing a bolus-tracking trigger (designed for arterial-phase studies) instead of a fixed 60-second delayProgramme a fixed-delay protocol specifically for adrenal washout studies, separate from general contrast-enhanced abdominal templates
Incomplete coverageFailing to ensure both adrenal beds are fully included on all three phases, especially when reducing scan range for dose savingsConfirm both glands are visualised on the unenhanced phase before contrast injection, and lock the coverage range for subsequent phases
Inadequate documentation of injection parametersNot recording actual flow rate achieved (versus prescribed) when venous access limits true flowDocument actual delivered flow rate and volume in the technologist record, since a sub-optimal bolus may explain unexpectedly low venous-phase enhancement

8. Pitfalls for radiologists

The primary interpretation pitfall is that hypervascular metastases or pheochromocytomas can occasionally demonstrate rapid washout profiles, mimicking benign adenomas. Washout CT is a probabilistic tool, not a categorical one, and treating a favourable washout percentage as definitive in the wrong clinical context is a recognised failure mode.

The underlying biological reason is that washout reflects contrast kinetics in general — the rate at which a vascular bed takes up and then releases iodinated contrast — and is not a direct measure of lipid content or histological benignity. Lipid-rich tissue happens to wash out quickly, which is why the threshold works well for the majority of adenomas. But other tissue types with high microvascular permeability and rapid interstitial clearance can wash out quickly for entirely different physiological reasons, producing a false sense of reassurance. Reported series suggest this overlap occurs in a meaningful minority — historically cited at up to around a quarter — of pathologically confirmed pheochromocytomas, which is precisely why biochemical correlation cannot be skipped on the basis of a reassuring CT alone.[10,11]

Radiologist interpretation pitfalls — 3-phase adrenal washout CT
PitfallMechanismConsequenceMitigation
Hypervascular lesion mimicking adenoma washoutHighly vascular lesions such as pheochromocytoma or hypervascular metastases (e.g., renal cell carcinoma, hepatocellular carcinoma primaries) can wash out rapidly despite not being adenomasA malignant or functionally significant lesion is misclassified as benign and discharged from follow-upAlways correlate washout result with clinical context, primary tumour history, and morphology (margin, homogeneity, size); request biochemical screening when pheochromocytoma is even modestly possible
Over-reliance on a single ROI measurementSampling error from a small or eccentrically placed ROI, especially in heterogeneous lesionsA truly heterogeneous, partly malignant mass is characterised by its most “benign-looking” regionSample multiple representative regions in heterogeneous lesions and report the range, not a single favourable value
Applying adenoma thresholds to atypical morphologyTreating washout percentages as overriding obviously concerning morphology (irregular margin, necrosis, rapid growth, size >4 cm)Morphologically aggressive lesions are downgraded based on washout aloneWeight morphology and growth on serial imaging at least as heavily as washout percentage in the final impression
Ignoring evolving evidence on threshold validityTreating the 10 HU and 60%/40% thresholds as having robust prospective validation in true incidentaloma populations, when recent reanalyses question this[1,6,7]False confidence is conveyed to referrers in the report wordingUse cautious, probabilistic report language (“consistent with”, “favours”) rather than definitive language when the evidence base for a given threshold is contested
Failure to flag indeterminate results clearlyBurying a borderline washout value in a long report without a clear actionable recommendationReferring clinicians miss the need for follow-up imaging, MRI, or endocrine referralState explicitly in the impression when a result is indeterminate and specify the recommended next step

None of these pitfalls is an argument against using washout CT — they are an argument for using it as one input among several, reported with appropriate transparency about its own limitations. A radiologist who reports “absolute washout 71%, favouring adenoma, though biochemical correlation is recommended given [specific clinical detail]” has done meaningfully more for patient safety than one who reports a bare “benign adenoma” — the additional sentence costs almost nothing in reporting time and materially changes how the next clinician in the pathway interprets and acts on the result.

9. Pitfalls for non-radiology physicians

Referring and treating physicians who order or act on adrenal washout CT reports face a different category of risk: not misreading the images, but misapplying or over-trusting the conclusion without the radiological nuance behind it.

This is, in many respects, the highest-stakes pitfall category in the entire protocol, because it sits closest to the point of clinical decision-making. A radiographer’s timing error or a radiologist’s interpretive nuance can usually be caught and corrected within the imaging pathway itself — a second technologist notices the timer was wrong, or a peer review flags an overly confident report. A referring physician’s misapplication of a washout result, by contrast, often only surfaces much later, when a patient who should have had biochemical screening presents instead with an undiagnosed phaeochromocytoma crisis, or a hormonally active adenoma is found incidentally years after it could have been treated.

Non-radiology physician pitfalls — 3-phase adrenal washout CT
PitfallWhat they seeWhat it actually isClinical dangerWhat to do
Treating “indeterminate” as “normal”A report stating washout values were borderline or indeterminateA genuinely unresolved finding requiring further workup, not a reassuring resultLoss to follow-up of a potentially malignant massTreat any “indeterminate” adrenal CT report as an action item requiring endocrinology or radiology follow-up discussion, not filing
Ordering washout CT instead of biochemical screeningAn adrenal incidentaloma referral where hormonal hypersecretion (Cushing, aldosteronism, pheochromocytoma) has not been excludedWashout CT characterises malignancy risk; it does not assess functional statusA hormonally active adenoma is missed because imaging alone “looked benign”Order baseline biochemical screening (1 mg overnight dexamethasone suppression test, plasma free metanephrines, and aldosterone/renin ratio if hypertensive) alongside or before imaging in every incidentaloma referral[2,4]
Anchoring on a numeric washout percentageA specific percentage figure in the report (e.g., “62% absolute washout”)A probabilistic estimate with measurement variability, not a binary pathology resultOver-confidence in a borderline value close to threshold, delaying appropriate follow-upDiscuss borderline results directly with the reporting radiologist rather than acting on the number in isolation
Requesting repeat washout CT for surveillanceA prior adenoma diagnosis with a request for “repeat washout CT in 6 months” to confirm stabilityUnnecessary repeat contrast and radiation exposure when size stability on a simpler follow-up scan (or no further imaging per guidelines) would sufficeCumulative radiation and contrast exposure without added diagnostic valueFollow current society guidance on incidentaloma follow-up intervals and imaging modality rather than defaulting to repeat washout protocols
Underestimating pheochromocytoma risk from imaging aloneA reassuring-looking adrenal mass on CT in a patient with episodic hypertension or palpitationsCT alone — even with favourable washout — cannot reliably exclude pheochromocytomaUnpremedicated biopsy or surgery risking hypertensive crisisMaintain a low threshold for biochemical screening before any invasive procedure on an adrenal mass, regardless of CT appearance

The common thread across all five of these clinical pitfalls is a mismatch between what an imaging report can and cannot establish. A washout CT report answers a specific, narrow question — does this mass behave like a benign cortical adenoma on contrast kinetics? — and was never designed to answer the broader questions of hormonal function, malignancy risk in the context of a specific cancer history, or safety for an invasive procedure. Referring physicians who keep this narrow scope explicitly in mind, rather than treating “the CT looked fine” as a comprehensive clearance, are far less likely to fall into any of the five pitfalls above.

10. Pitfall comparison summary

🟡 Scanning (radiographers)

  • Cutting the 15-minute delay short
  • Inconsistent ROI placement across phases
  • Wrong trigger method for venous phase
  • Incomplete bilateral coverage

🔴 Interpretation (radiologists)

  • Hypervascular lesions mimicking adenoma washout
  • Single-ROI sampling error in heterogeneous masses
  • Overweighting washout versus morphology
  • Definitive language despite contested thresholds

🟣 Clinical (physicians)

  • Treating “indeterminate” as reassuring
  • Imaging instead of biochemical screening
  • Anchoring on a single percentage value
  • Unpremedicated procedures despite pheochromocytoma risk
🧭

Close the loop between imaging and clinical follow-up

SATMED Health helps departments flag indeterminate adrenal findings for guaranteed follow-up, so nothing falls through administrative gaps.

Explore Care-Coordination Solutions →

What this comparison makes visible is that the three pitfall tiers are sequential, not parallel — an error at the scanning stage propagates forward and constrains what the radiologist can possibly conclude, and an overly confident or ambiguous radiologist’s report propagates forward again into how the referring physician acts. A single robust quality safeguard at any one tier (a reliable delayed-phase timer, a habit of stating raw HU values in every report, a departmental policy of treating “indeterminate” as an action item) meaningfully reduces the chance of a downstream failure two steps removed from where the safeguard was applied.

11. AI and automation in adrenal CT

Artificial intelligence applications in adrenal imaging have moved well beyond proof-of-concept. A 2025 systematic review of CT-based radiomics in adrenal lesion characterisation found pooled diagnostic performance with a mean area under the curve of approximately 0.88 across eligible studies, with the strongest-performing models reaching an AUC of 0.99 for identifying aldosterone-producing adenomas.[31] These are research-stage and early clinical-validation results rather than universally deployed clinical tools, and departments should treat published AUC figures as evidence of promise rather than guaranteed real-world performance on their own patient population and scanner fleet.

Several distinct AI application categories are emerging for this protocol specifically:

  • Automated lesion segmentation. Deep learning segmentation models reduce inter-observer variability in ROI placement — directly addressing one of the radiographer and radiologist pitfalls described above — by generating a reproducible, algorithm-defined region rather than a manually drawn one.[30]
  • Texture and radiomic feature classification. Beyond simple mean HU, radiomic models extract heterogeneity, edge, and texture features from unenhanced and contrast-enhanced images to separate lipid-poor adenomas from non-adenomas, including in cases where conventional washout values are borderline.[20,21]
  • Deep learning reconstruction (DLR). As discussed in the scanning technique section, DLR denoises image data to support dose reduction, particularly valuable on the noise-sensitive unenhanced phase.
  • Automated volumetric adrenal gland measurement. Fully automated tools for measuring adrenal gland volume support more objective hyperplasia classification than manual limb-thickness callipers, which carries known measurement-technique variability.[23]
Evidence-based framing At the time of writing, dedicated FDA-cleared or CE-marked AI products specifically targeting adrenal lesion washout classification remain limited relative to more mature AI categories such as lung nodule or stroke detection. Departments evaluating adrenal-specific AI tools should request the vendor’s clearance documentation and validation cohort characteristics directly, since published academic performance figures do not automatically transfer to a commercially deployed, regulatory-cleared product.

Practical integration considerations

Even where a validated AI tool exists, integrating it into an adrenal washout workflow raises practical questions that are easy to overlook during procurement. Does the tool require the unenhanced phase, or is it designed to work from virtual unenhanced reconstructions alone? Does it report a binary classification, a continuous probability score, or a set of extracted radiomic features that still require human synthesis? Can it flag discordance between its own output and the conventional washout calculation for radiologist review, rather than silently overriding it? These questions matter more for adoption success than the headline AUC figure quoted in a vendor’s marketing material.

A further consideration specific to this protocol is that several of the most promising radiomic and deep learning classifiers were trained and validated on data from a single triphasic acquisition pattern, often using a specific scanner vendor’s reconstruction kernel. A tool validated on one institution’s 64-slice, 120 kVp dataset may perform differently on a 320-slice volumetric acquisition or a dual-energy-derived virtual unenhanced image from a different vendor. Local validation against a department’s own historical cases — even a modest retrospective audit of 50–100 known outcomes — remains good practice before any AI output is trusted to influence clinical decision-making, regardless of the regulatory status of the underlying product.

Multidisciplinary coordination and documentation

Adrenal incidentaloma management increasingly sits at the intersection of radiology, endocrinology, and — when malignancy is confirmed or strongly suspected — surgical and oncological teams. Departments performing high volumes of adrenal washout studies benefit from a defined pathway specifying exactly which findings trigger automatic endocrinology referral (any biochemical abnormality, any mass >4 cm, any indeterminate washout result), rather than leaving this judgement to vary case-by-case based on which radiologist or physician happens to be involved. A documented multidisciplinary adrenal tumour board, even one that meets relatively infrequently, materially improves consistency in management of the genuinely ambiguous cases that this protocol, by design, cannot resolve through imaging alone.[27]

From a documentation and medico-legal standpoint, the single most protective habit described throughout this article is the same one repeated across the pitfall tables: record the raw numbers, not just the conclusion. A report that states “absolute washout 64%, consistent with adenoma” allows any future reviewer — including a different radiologist reading a follow-up scan, or a clinician reassessing the case in light of new symptoms — to independently verify and, if necessary, challenge the original classification. A report that states only “adenoma” forecloses that possibility entirely, and in the rare case where the original classification proves wrong, removes the audit trail that would explain why. This single habit, more than any individual threshold or technology discussed in this article, is the most reliably protective practice available to every member of the imaging and clinical team.

🤖

Bring evidence-based automation into your adrenal imaging pathway

SATMED Health partners with radiology departments to evaluate and integrate validated AI tools without disrupting existing reporting workflows.

Explore AI Integration Solutions →

12. Further reading

  1. Multi-Phase Liver CT Protocol: 7 Critical Steps for HCC Detection
  2. Dual-Phase Pancreatic CT Protocol: 7 Critical Steps for Mass Detection
  3. Routine Abdomen Pelvis CT Protocol: 7 Proven Scanning Steps
  4. 2026 Worldwide Guidelines for Safe Contrast Media Administration: eGFR Thresholds and Society Recommendations
  5. The Price We Pay for Bubbles in CT and MRI: Understanding Venous Air Embolism in Contrast-Enhanced Imaging

13. Conclusion

The 3-phase adrenal washout CT protocol distils a complex diagnostic question — is this incidentally discovered adrenal mass dangerous? — into a structured, reproducible sequence of three precisely timed acquisitions. Its diagnostic power rests entirely on disciplined execution: a true unenhanced phase, a 60-second venous phase, and an uncompromised 15-minute delayed phase, each measured with a consistently placed region of interest.

Across the ten pathologies most commonly encountered — from the reassuringly common lipid-rich adenoma through to the rare but lethal adrenocortical carcinoma — the protocol’s value depends on recognising its limits as much as its strengths. Pheochromocytoma can defeat the washout calculation outright; hypervascular metastases can mimic benign kinetics; and the underlying threshold literature itself is under active re-evaluation by major endocrine societies.

The three-tier pitfall framework presented here — scanning execution for radiographers, interpretive nuance for radiologists, and clinical application for referring physicians — reflects the reality that no single specialty can deliver this protocol’s value alone. Consistent timing at the scanner, careful interpretive language in the report, and appropriate biochemical correlation by the treating clinician together determine whether a patient with an adrenal incidentaloma is reassured appropriately, investigated appropriately, or — in the rare but consequential cases — referred for definitive management without unnecessary delay.

As dual-energy and photon-counting platforms mature, and as radiomic and deep learning classifiers move from research validation toward genuine clinical deployment, the operational shape of this protocol will likely continue to evolve — potentially toward fewer acquired phases and more derived measurements. What will not change is the underlying clinical discipline this article has emphasised throughout: precise timing, transparent documentation of the underlying numbers, and a willingness to treat a borderline result as exactly that, rather than forcing it into a falsely reassuring binary outcome.

For radiology departments building or refining this protocol, the practical priorities are clear: protect the 15-minute delayed-phase interval in scheduling and workflow design, standardise ROI placement methodology across staff, document raw HU values alongside any calculated percentage, and maintain an active, two-way relationship with referring endocrinology and oncology teams so that indeterminate results are tracked through to resolution rather than left as an open loop in the patient’s record.

14. References

  1. Seow, J. H., Stella, D. L., Welman, C. J., Somasundaram, A. J., & Gerstenmaier, J. F. (2025). Washed up: the end of an era for adrenal incidentaloma CT. Insights into Imaging, 16(1), 136. https://doi.org/10.1186/s13244-025-02015-4
  2. Fassnacht, M., Tsagarakis, S., Terzolo, M., Tabarin, A., Sahdev, A., Newell-Price, J., Pelsma, I., Marina, L., Lorenz, K., Bancos, I., Arlt, W., & Dekkers, O. M. (2023). European Society of Endocrinology clinical practice guidelines on the management of adrenal incidentalomas, in collaboration with the European Network for the Study of Adrenal Tumors. European Journal of Endocrinology, 189(1), G1–G42. https://doi.org/10.1093/ejendo/lvad066
  3. Mayo-Smith, W. W., Song, J. H., Boland, G. L., Francis, I. R., Israel, G. M., Mazzaglia, P. J., Berland, L. L., & Pandharipande, P. V. (2017). Management of incidental adrenal masses: A white paper of the ACR Incidental Findings Committee. Journal of the American College of Radiology, 14(8), 1038–1044. https://doi.org/10.1016/j.jacr.2017.05.001
  4. Sherlock, M., Scarsbrook, A., Abbas, A., Fraser, S., Limumpornpetch, P., Dineen, R., & Stewart, P. M. (2020). Adrenal incidentaloma. Endocrine Reviews, 41(6), 775–820. https://doi.org/10.1210/endrev/bnaa008
  5. Lee, J. M., Kim, M. K., Ko, S. H., Koh, J. M., Kim, B. Y., Kim, S. W., Kim, S. Y., Kim, C. H., Park, H. S., Song, K. H., Shin, J. H., Oh, T. K., Yoon, J. H., Eun, C. R., Yoo, S. J., & Lee, S. J. (2017). Clinical guidelines for the management of adrenal incidentaloma. Endocrinology and Metabolism, 32(2), 200–218. https://doi.org/10.3803/EnM.2017.32.2.200
  6. Schloetelburg, W., Ebert, I., Petritsch, B., et al. (2022). Adrenal wash-out CT: moderate diagnostic value in distinguishing benign from malignant adrenal masses. European Journal of Endocrinology, 186(2), 183–193. https://doi.org/10.1530/EJE-21-0650
  7. van Aswegen, T., Trinh, B., Jacques, A., & Lo, G. (2024). Adrenal washout CT in patients with no history of cancer: a waste of time? Abdominal Radiology. https://doi.org/10.1007/s00261-024-04333-5
  8. Ngo, B., Liu, T., & Lau, E. (2025). Imaging of adrenal incidentalomas: what actually happens in everyday clinical practice? Journal of Medical Imaging and Radiation Oncology, 69, 328–334. https://doi.org/10.1111/1754-9485.13853
  9. Hu, Y., et al. (2026). Incidental adrenal nodules and growth rates: a single centre retrospective cohort study. Journal of Medical Imaging and Radiation Oncology. https://doi.org/10.1111/1754-9485.70058
  10. Teixeira, A. P., Haddad, W., Jr., Barreto, L. O., et al. (2023). Histogram analysis in the differentiation between adrenal adenomas and pheochromocytomas: the value of a single measurement. Radiologia Brasileira, 56(2), 59–66. https://doi.org/10.1590/0100-3984.2022.0067
  11. Klatzkow, H. R., Cai, Q., & Aday, A. W. (2024). Unveiling pheochromocytoma: a puzzling prelude of nausea, vomiting, and abdominal pain. American Journal of Case Reports, 25, e943875. https://doi.org/10.12659/AJCR.943875
  12. Kedra, A., Dohan, A., Gaujoux, S., Sibony, M., Jouinot, A., Assié, G., Groussin Rouiller, L., Libé, R., Bertherat, J., Soyer, P., & Barat, M. (2021). Preoperative detection of liver involvement by right-sided adrenocortical carcinoma using CT and MRI. Cancers, 13(7), 1603. https://doi.org/10.3390/cancers13071603
  13. Vañó, E., Miller, D. L., Martin, C. J., Rehani, M. M., Kang, K., Rosenstein, M., Ortiz-López, P., Mattsson, S., Padovani, R., & Rogers, A. (2017). ICRP Publication 135: Diagnostic reference levels in medical imaging. Annals of the ICRP, 46(1), 1–144. https://doi.org/10.1177/0146645317717209
  14. Paulo, G., Damilakis, J., Tsapaki, V., Schegerer, A. A., Repussard, J., Jaschke, W., & Frija, G. (2020). Diagnostic reference levels based on clinical indications in computed tomography: a literature review. Insights into Imaging, 11(1), 96. https://doi.org/10.1186/s13244-020-00899-y
  15. Elhassan, Y. S., Alahdab, F., Prete, A., et al. (2019). Natural history of adrenal incidentalomas with and without mild autonomous cortisol excess: a systematic review and meta-analysis. Annals of Internal Medicine, 171(2), 107–116.
  16. Hong, A. R., Kim, J. H., Park, K. S., et al. (2017). Optimal follow-up strategies for adrenal incidentalomas: reappraisal of the 2016 ESE-ENSAT guidelines in real clinical practice. European Journal of Endocrinology, 177(6), 475–483.
  17. Tiralongo, F., Mosconi, C., Foti, P. V., Calogero, A. E., La Vignera, S., Ini’, C., Castiglione, D. G., David, E., Tamburrino, S., Barbarino, S., Palmucci, S., & Basile, A. (2025). The role of dual-energy CT in differentiating adrenal adenomas from metastases: a comprehensive narrative review. Journal of Personalized Medicine, 15(4), 131. https://doi.org/10.3390/jpm15040131
  18. Bernard, P., Nelles, C., Fervers, P., et al. (2025). Adrenal lesion classification revisited: validation and adjustment of dual-energy CT derived virtual unenhanced attenuation thresholds. Abdominal Radiology, 50, 5283–5291. https://doi.org/10.1007/s00261-025-04939-3
  19. Nagayama, Y., Inoue, T., Oda, S., et al. (2020). Adrenal adenomas versus metastases: diagnostic performance of dual-energy spectral CT virtual noncontrast imaging and iodine maps. Radiology, 296(2), 324–332. https://doi.org/10.1148/radiol.2020192227
  20. Zhang, B., Zhang, H., Li, X., Jin, S., Yang, J., Pan, W., et al. (2022). Can radiomics provide additional diagnostic value for identifying adrenal lipid-poor adenomas from non-adenomas on unenhanced CT? Frontiers in Oncology, 12, 888778. https://doi.org/10.3389/fonc.2022.888778
  21. Feliciani, G., Serra, F., Menghi, E., Ferroni, F., Sarnelli, A., Feo, C., et al. (2024). Radiomics in the characterization of lipid-poor adrenal adenomas at unenhanced CT: time to look beyond usual density metrics. European Radiology, 34, 422–432. https://doi.org/10.1007/s00330-023-10090-8
  22. Zhang, H., Lei, H., & Pang, J. (2022). Diagnostic performance of radiomics in adrenal masses: a systematic review and meta-analysis. Frontiers in Oncology, 12, 975183. https://doi.org/10.3389/fonc.2022.975183
  23. Kim, T. M., Choi, S. J., Ko, J. Y., et al. (2023). Fully automatic volume measurement of the adrenal gland on CT using deep learning to classify adrenal hyperplasia. European Radiology, 33, 4292–4302. https://doi.org/10.1007/s00330-022-09347-5
  24. Kusunoki, M., Nakayama, T., Nishie, A., et al. (2022). A deep learning-based approach for the diagnosis of adrenal adenoma: a new trial using CT. British Journal of Radiology, 95(1135), 20211066.
  25. Moawad, A. W., Ahmed, A., Fuentes, D. T., Hazle, J. D., Habra, M. A., & Elsayes, K. M. (2021). Machine learning-based texture analysis for differentiation of radiologically indeterminate small adrenal tumors on adrenal protocol CT scans. Abdominal Radiology, 46(10), 4853–4863.
  26. Kim, H. Y., Chang, W., Lee, Y. J., et al. (2022). Adrenal nodules detected at staging CT in patients with resectable gastric cancers have a low incidence of malignancy. Radiology, 302(1), 129–137.
  27. Chung, R., Garratt, J., Remer, E. M., et al. (2023). Adrenal neoplasms: lessons from adrenal multidisciplinary tumor boards. RadioGraphics, 43(7), e220191.

Subscribe for Updates!