Training-Free Medical Image Segmentation vs Trained Networks

A multi-domain data-efficiency study — frozen-foundation-model assembly (an LLM polygon drawer in the deployed path on 1/6 domains, else SAM / op_sam / SegGPT) + a numpy genome, zero gradient training on the target task. See the post-rebuttal revised claims →

6 modalitiesmeasured, from scratch GT-free at inferenceLLM-agnostic skills revised post-rebuttal · 2026-07-07

Revised claims — post-rebuttal, 2026-07-07

After a hostile self-review (reviewer_attack.md) and 10 rebuttal experiments (docs/rebuttal/), this is the honest, defensible version. The detailed per-domain evidence below is all valid; the claims wrapping it are corrected here. The old headline — "training-free, within ≤0.005 of the best trained NN on 4/6 domains at N=100" — does not survive and is retracted.

Retracted — these do not survive scrutiny
Refuted attacks — these stay strengths
The surviving thesis — measured, CI-backed

Training-free frozen-model assembly wins the EXTREME scarce-label regime (N≤25) on GT-free-localizable targets — and its edge is distribution-robust localization, not memorization.

The core science — the real contribution
One-line thesis. Frozen-foundation-model assembly is the right tool below the GT-free-localization frontier (scarce labels, localizable targets); across it, you must train — and then you are the NN. We characterize that frontier and give a GT-free predictor for it.

Results — best trained NN across N vs the frozen-assembly pipeline

Strongest trained NN per cell — max of SegFormer (mit_b2), pretrained U-Net (resnet34), and nnU-Net, 2-seed means — at matched budgets N = 10 / 25 / 50 / 100, against the LLM pipeline (re-measured from scratch via eval_all_domains.py). The LLM's only label-fit module is a ~5–8-param genome; localization and SAM are GT-free/frozen — so the LLM number is ~flat in N while the NN climbs. Caveat (post-rebuttal): the N=100 column is a set of within-noise near-ties — best-NN@100 sits inside the LLM bootstrap 95% CI on 5/6 domains (stats.md), and 0/4 apparent N=100 leads survive as significant. The honest, CI-separated lead is at N≤25 (revised claims). Amber = within-CI near-tie; a green cell reflects the point estimate only, not significance.

Domainbest NN N=10N=25N=50N=100training-free LLMfew-shot decoder
N=100 (oracle)
ISIC 2018 (derm)0.8150.8290.8320.8680.8800.911
MSD Spleen (CT)0.6330.8020.8590.9070.9200.953
Kvasir-SEG (endo)0.7560.8240.8330.8890.86460.944
ChestXray (X-ray)0.9380.9480.9520.95460.9497
SegGPT in-context; fs-deploy 0.9488
0.9535
HC18 Fetal-Head (US) ·new0.9230.9580.9650.9700.9667
retrieval SegGPT; was 0.9328 fs / 0.9225 tf
0.9665
tuned-decoder oracle
MSD Prostate (MRI) ·new0.6790.7200.7720.8150.7877
SegGPT⊕op_sam ensemble; was 0.760
0.938
Two LLM columns: the training-free pipeline (zero gradient training — the study's headline) and the few-shot tuned decoder (generic-SAM init, encoder frozen, ~4M-param mask decoder tuned on N=100 labels, GT-box oracle). The few-shot decoder beats the from-scratch NN on four of six domains given a good box (ISIC/Spleen/Kvasir/Prostate) and ties the other two (CXR, HC18 — near-ceiling NNs at ~0.95–0.96) — the residual between it and the deployed training-free pipeline is mostly localization (the exception was CXR, where the frozen SAM decoder was the wall — now moved training-free by swapping in a different frozen decoder, the SegGPT in-context drawer, to 0.9497), detailed below.
CXR is now training-free again at 0.9497 — a swapped 4th frozen drawer backend (SegGPT in-context). The old CXR training-free headline (0.922, frozen box-SAM) is superseded by a different frozen decoder: SegGPT (BAAI/seggpt-vit-large, generic → leak-free, non-SAM) paints the whole lung mask in-context from K=8 spread-sampled train (image,mask) support pairs — no box, no SAM, no localizer, ZERO gradient training. Deployed 0.9497 (median 0.9616, n=107), within 0.005 of the from-scratch NN's 0.9546 — a near-tie, still not a win. This is the 4th backend at the model-coupled drawer seam (LLM polygon · frozen SAM · few-shot tuned decoder · in-context SegGPT): the seam is genuinely swappable, and CXR's gap was neither architectural nor requiring our labels — it was the particular frozen decoder (SAM). A separate, non-training-free few-shot lane remains documented: tuning only the ~4M-param SAM mask decoder on N=100 CXR labels (generic-vit_l init, encoders frozen, box-jittered, leak-free) + mask-bbox re-decode reaches 0.9488 (median 0.9608, 102/107 improve) — but the deployed CXR is now the training-free SegGPT 0.9497, which supersedes it. Frozen-decoder study (leak-free generic): among frozen alternatives the generic in-context SegGPT wins; SAM2 / SAM1-vit_h merely tie frozen SAM-HQ (no gain), and text-prompted CLIPSeg fails on grayscale X-ray (0.00) — the interesting frozen alternative is a generic in-context segmenter (few-shot at inference, zero gradient), not another SAM variant.
The pipeline wins the EXTREME scarce-label regime (N≤25) where the target is GT-free-localizable — ISIC and Spleen are CI-separated leads at N≤25 (fewshot_matched.md); at N=100 the numbers below (ISIC 0.880 vs 0.868, Spleen 0.920 vs 0.907) are within-CI near-ties, not significant leads (stats.md) — and on Kvasir polyp a frozen-DINOv2 dense-correspondence localizer (OP-SAM CPG + peak-CC box) lifts it 0.659→0.8646 — the gap was localization (frozen GT-box oracle 0.914 > NN), and this closes 89% of it; the median 0.9484 now beats the NN mean, though the mean stays just below best-NN 0.889. On Chest X-ray the deployed training-free path is now a swapped 4th frozen drawer — the SegGPT in-context drawer (K=8 support pairs, zero gradient) — reaching 0.9497 ≈ NN 0.9546 (−0.005, a near-tie), superseding the earlier box-SAM 0.922 and the separate few-shot-tuned decoder 0.9488 lane; the old "frozen-decoder cap ~0.93" was specific to SAM, not to architecture. On HC18 fetal-head the same story now plays out training-free: a swapped retrieval-prompted SegGPT drawer (K=8 query-retrieved DINOv2-similar in-context supports, zero gradient, SAM-free) reaches 0.9667 ≈ NN 0.9703 (−0.004, a near-tie), superseding the op_sam+SAM 0.9225 and the few-shot decoder 0.9328 — so FetalHead is no longer a few-shot lane. Honest headline (post-rebuttal): at N=100 these are within-CI near-ties — 0/4 apparent leads survive bootstrap 95% CIs (stats.md), and the Spleen "+0.019" is a seed-averaging artifact (best single U-Net seed 0.9323 > LLM 0.9262). The defensible lead is at N≤25 on localizable targets (ISIC / Kvasir / Spleen / Prostate), budget-matched and CI-separated. All 6 deployed paths are gradient-free frozen-model assembly, but the LLM drawer is out of the mask-producing path on 5/6 (llm_ablation.md) — Prostate, the last domain lifted off its floor, is a complementary 2nd frozen drawer (a SegGPT⊕op_sam edge-gated keep-best ensemble). SegFormer is the strongest NN in 10 of 12 sweep cells.

Data-efficiency

Matched data-efficiency: training-free LLM pipeline (flat, measured) vs best trained NN across N
Six domains. Each panel: the best trained NN (gray, climbing with N) vs the training-free LLM pipeline (colored flat dashed — a single measured Dice; ~N-independent, since only a ≤40-label genome is fit; dotted = LLM median where a localization tail matters). Shading marks where the LLM leads; the bold label is its point-estimate margin at N=100. Post-rebuttal caveat: the N=100 margins on ISIC (0.880, +0.012) and Spleen (0.920, +0.013) are within bootstrap 95% CIs — near-ties, not significant leads (Spleen's is a seed artifact); the CI-separated lead is at N≤25. The LLM leads the best NN at N=10 and ties it at N=25 on Kvasir (0.824 vs best-NN 0.756/0.824 at those support budgets; the full-budget deployed number is 0.8646 at N=30 supports, the dense-correspondence localizer), and near-ties on Chest X-ray (deployed training-free 0.9497 via a swapped frozen non-SAM SegGPT in-context drawer, −0.005 from NN 0.9546) and the two new localizer modalities — HC18 ultrasound (deployed training-free 0.9667 via a swapped retrieval-prompted SegGPT drawer, median 0.9712, −0.004 from NN 0.9703 — a near-tie) and prostate MRI (deployed training-free 0.7877 via a complementary SegGPT⊕op_sam edge-gated keep-best ensemble, median 0.8483, −0.028 from NN 0.815). Both new modalities were lifted by the recent agent research (HC18 to 0.9667 via K=8 query-retrieved DINOv2-similar in-context supports, superseding the op_sam+SAM 0.9225 and the few-shot decoder 0.9328; prostate 0.715→0.744→0.760→0.7877 — the op_sam box tightening + CLAHE prior-enhancement, then a per-image keep-best ensemble with a frozen SegGPT-retrieve drawer that rescues the slices op_sam misses, both drawers frozen/training-free).

Where is the wall — the decoder, or localization? A fair few-shot probe

Is the residual to the trained NN a decoder limit or a localization limit? MedSAM (SAM fine-tuned on ~1M medical masks) beats box-prompted SAM — but it is data-leaky (its training set likely includes these test distributions), so it is really "import a trained medical net." The fair, leak-free counterpart of the same operation: init from the generic SAM (no medical data), freeze the image + prompt encoders, and fine-tune only the ~4M-param mask decoder on our own N-label train split — GT never touches test. Given a good box (the GT-box oracle, which isolates the decoder), this few-shot-tuned decoder beats the from-scratch NN at every budget on 4 of 6 domains (ISIC/Spleen/Kvasir/Prostate — Prostate by +0.12) and ties on the other two (CXR, HC18 — both near-ceiling NNs at ~0.95–0.96), and it saturates at N=10 (pretrained features + a tiny adapted head), so its curve is flat-high while the NN climbs:

Domain (tuned decoder, oracle)N=10N=25N=50N=100best NN N=100
ISIC 2018 (derm)0.9050.9040.9070.9110.868
MSD Spleen (CT)0.9570.9600.9600.9530.907
Kvasir-SEG (endo)0.9360.9340.9370.9440.889
ChestXray (X-ray)0.9330.9460.9550.95350.9546
HC18 Fetal-Head (US) ·new0.9180.9540.9570.96650.970
MSD Prostate (MRI) ·new0.9060.9310.9320.9380.815
Few-shot tuned decoder (oracle) vs trained NN vs training-free LLM
Few-shot tuned decoder (GT-box oracle, ◆) vs best trained NN (gray, from scratch) vs the training-free LLM pipeline (dotted, flat). The tuned decoder saturates at N=10 and sits at/above the NN at every budget on ISIC/Spleen/Kvasir and Prostate (+0.12 over the NN); CXR ties by N=50, and Fetal-Head US ties (0.9665 vs a near-ceiling NN 0.970). ★ = the measured deployable number (tuned decoder + the domain's real GT-free localizer).
Mostly localization — with CXR the telling exception. The oracle hands the decoder a good box; on most domains the gap between it and the deployed pipeline is localization. Kvasir is the proof: tuned-decoder oracle 0.944 vs the original deployed 0.659 — 0.285 of pure localization headroom, zero decoder; the frozen dense-correspondence localizer has since realized most of it (0.659→0.8646), exactly as this predicted, leaving only ~0.05 to the oracle box. Where localization is already solved, the tuned decoder is a clean deployable win over both production and the NN: CXR few-shot decoder 0.9488 > the earlier box-SAM production 0.922 ≈ NN 0.9546 (though the deployed training-free CXR is now the SegGPT in-context drawer 0.9497, which supersedes both); Spleen (3D volume-prior box) 0.942 > production 0.920 > NN 0.907. This is few-shot (N=100 labels = the NN's budget), not training-free — an explicit, leak-free counterpart to MedSAM. CXR is the exception that sharpens the rule: its wall was the particular frozen decoder (SAM), not localization and not architecture — swapping in a different frozen decoder, the SegGPT in-context drawer, moves it training-free to 0.9497 (≈ NN, zero gradient), and a few-shot-tuned SAM decoder independently reaches 0.9488. So of the residual "structural / architectural ceilings," the polyp boundary was a localization gap in disguise, while the CXR "decoder wall" was a SAM-specific wall breachable by another frozen decoder with none of our labels.

Is the medical pretraining (MedSAM) worth it? — a leaky benchmark

MedSAM is SAM already fine-tuned on ~1M medical masks — a leaky upper reference (its training likely saw these test distributions). Arch-matched (both vit_b, GT-box oracle, N=100), few-shot tuning of the GENERIC SAM matches or beats the leaky MedSAM on 3 of 6 domains, and stays within 0.015 on the other 3 — its own pretraining distributions (derm/US/MRI). Medical pretraining buys no consistent edge once the decoder is adapted, and where generic SAM is already strong (Kvasir/Spleen) it starts above MedSAM even frozen. Bold = better of the two few-shot columns.

Domain (N=100 oracle, vit_b)from-scratch NNgeneric frozengeneric few-shot (fair)MedSAM frozen (leaky)MedSAM few-shot (leaky)
ISIC 2018 (derm)0.8680.8700.9150.9210.943
MSD Spleen (CT)0.9070.9410.9560.9090.946
Kvasir-SEG (endo)0.8890.9170.9360.8880.918
ChestXray (X-ray)0.95460.9250.9540.9350.952
HC18 Fetal-Head (US) ·new0.9700.7690.9650.9040.972
MSD Prostate (MRI) ·new0.8150.8950.9280.8070.941
Fair few-shot generic SAM vs leaky MedSAM benchmark, N=100 oracle
Fair few-shot tuning of generic SAM (dark blue) vs the leaky MedSAM (orange), each frozen + few-shot-tuned, vs the from-scratch NN (gray) — arch-matched vit_b, N=100 GT-box oracle. The fair generic few-shot ≥ leaky MedSAM few-shot on Spleen/Kvasir/ChestXray (3/6); MedSAM leads on its own pretraining distributions — derm (ISIC), US (HC18), MRI (prostate) — but by <0.015 once the generic decoder is tuned, and generic-frozen still beats MedSAM-frozen on prostate (0.895 vs 0.807). Medical pretraining helps most exactly where MedSAM saw the data, yet few-shot tuning of the generic decoder nearly erases it — decoder adaptation, not medical pretraining, is the lever.
The MedSAM attack inverts once it is prompted fairly and tested OOD (ood_medsam.md). The oracle-box column above is a leaky upper reference. Give MedSAM a fair box (learned from N GT, not the oracle) and it drops +0.16..+0.59 Dice below the deployed pipeline in-distribution; take it out-of-distribution (DRIVE retinal vessels — a distribution MedSAM never trained on) and the gap widens to +0.51 while MedSAM collapses to 0.220 even handed the ORACLE box (vs ~0.90 in-distribution). MedSAM's in-distribution edge was its decoder recognizing box-shaped targets it had trained on — memorization that does not transfer; the pipeline's few-shot-refit GT-free localization is distribution-robust.

Can it be ONE domain-agnostic pipeline? — few-shot skills + a router, SAM frozen

Each domain has a distinct setup — so can it be a single domain-agnostic pipeline that few-shot-fits per domain WITHOUT tuning SAM? We test the transferable skill — a frozen-SAM-feature localizer prototype fit from N labeled images — with identical code across all six domains, SAM never touched.

Domain-agnostic few-shot skill transfer: skills few-shot-fit, topology is routed not tuned
(A) One fixed pipeline (prototype-sim localizer): the skill few-shot-fits — saturates by ~N=10 on every domain — and scores high where the target is prototype-localizable (ISIC 0.71, CXR 0.62, HC18 US 0.72), mid where it is a central structure (Prostate MRI 0.51), low where it needs a specialized localizer (Kvasir 0.35, Spleen 0.12). (B) Routing the per-domain topology (genome / static-box / op_sam dense-correspondence / volume-prior / ellipse-snap / volume-trajectory) + the few-shot skill recovers most of the deployed number (Kvasir 0.35→0.77→0.86, HC18 0.69→0.92, Prostate 0.51→0.76, Spleen 0.14→0.66→0.83@N=50).
Yes — a domain-agnostic pipeline = frozen SAM + a GT-free router + few-shot skills. The learning (localizer prototype + gate weights + genome) is domain-agnostic, few-shot (~10 labels; ~50 for the isodense spleen), and SAM-frozen — it transfers with identical code. The per-domain "distinct setup" you'd notice is which localizer topology to route to — a GT-free routing choice (learned config, the project's route.py), not SAM tuning. So onboarding a new domain is ~10 labels + a routing decision, zero gradient training. Robust localizer skill: the deployed default is now the op_sam frozen-DINOv2 dense-correspondence localizer (kvasir/HC18/prostate) — it transfers 10-shot support masks through the full patch cross-correlation, and superseded the earlier SAM+DINOv2 AMG-ranker ensemble on Kvasir (0.655→0.8646). The lesson holds and is now stronger: the polyp/fold and faint-skull walls yield to the right frozen feature space — dense correspondence, plus feature-diverse supports — not to distractor-verification tricks. The AMG-ranker ensemble (at/near the best single feature space on all three, Kvasir 0.65 / Spleen 0.64 / ISIC 0.67, never catastrophic where SAM-alone fails the isodense spleen 0.40) remains the LLM-agnostic fallback where a support set is too small for correspondence.

Qualitative examples — 3 best / 3 worst per dataset

Green = ground truth, red = prediction. Top row = 3 highest-Dice cases, bottom row = 3 lowest.

ISIC 2018 — skin lesion (pigment cue, LLM's best domain)

ISIC best/worst

MSD Spleen — CT (localizer + cross-slice priors + SAM re-prompt polish)

Spleen best/worst
The worst cases are localizer failures (prediction lands on stomach/liver, Dice≈0). A GT-free cross-slice prior (centroid trajectory + sibling-mask seed), a selective multi-prototype re-decode, a SAM re-prompt boundary polish, and a final pyramid keep-best (crop→zoom→SAM-decode each tiny tip slice at higher resolution) recover them, lifting the spleen pipeline to 0.920 (0.786→0.840→0.868→0.875→0.903→0.920 this session) — a within-CI near-tie with the best trained NN at N=100 (0.920 vs 0.907; the "+0.019 lead" is a seed-averaging artifact — the single best U-Net seed 0.9323 edges the LLM's 0.9262, stats.md). The CI-separated lead is at N≤25. Pyramid is complementary to the within-volume prior: the prior re-decodes a tip slice from its siblings, pyramid re-decodes it at higher resolution.

Kvasir-SEG — polyp (dense-correspondence localizer; the gap was localization, 89% closed)

Kvasir best/worst
Polyps share colour/texture with mucosa, so a mean-prototype / AMG-candidate ranker mislocalizes (~43/100 to Dice≈0) — and four verification signals (SAM self-consistency, FG-BG margin, cycle-consistency) all failed to rank the right blob. The unlock, grounded in the polyp-SAM literature (OP-SAM, ICCV'25, frozen Dice 0.845 on this exact dataset), is frozen-DINOv2 dense-correspondence label transfer (CPG): transfer 10 few-shot support masks onto the query via the full patch cross-correlation matrix — not a mean prototype (which washes out on polyp≈mucosa). The prior peak lands in the polyp 94% of the time (vs the old LLM box's 0.46 box-IoU); a peak-connected-component box + prior-guided SAM mask selection then decodes it. Deployed 0.659 → 0.8646 (median 0.9484; note this is a median-vs-mean comparison — the LLM mean 0.8646 stays just below best-NN 0.889 at N=100, and the honest CI-separated lead is at N≤25), leak-free, frozen DINOv2+SAM, no tuning. A further lever closed the mislocalization tail: rebuilding the op_sam support set kvasir_supports.npz from the first-30 (was first-10) train images widens the dense-correspondence prior's appearance coverage (+0.032, two-split, leak-free, zero-code; one 0.000→0.834 recovery) — an N=30 support budget (30 train labels; still scarce, well under 100), a different quantity from the N=10 data-efficiency point above (0.824). Polyps want support coverage/count, not the FPS-diversity that wins on US/MRI (fps10 0.725 ≪ first10 0.826) — opposite knobs on the same support seam. The frozen GT-box oracle is 0.914 > NN, so Kvasir never had a decoder wall — its entire gap was localization, now 89% closed (was −0.230 to the NN, now −0.025); the residual is the known gate-bound polyp tail (no GT-free signal isolates the confidently-wrong mislocalizations). Gallery shows the earlier LLM-box path; the correspondence localizer replaces the bottom-row localization misses.

ChestXray — bilateral lungs (deployed: training-free SegGPT in-context drawer, 0.9497; gallery shows the earlier box-SAM path)

CXR best/worst
Five GT-free skills: (1) a fixed few-shot lung box (mean of N=10 train GT boxes; box-IoU 0.545→0.67) replaces the heuristic box → 0.825→0.898; (2) a mask-bbox self-reprompt (box-IoU 0.67→0.83) → 0.898→0.911; (3) a repair agent that trims SAM's bright "out of lung" over-seg into the mediastinum (a decoder error a redraw loop can't reach), fire-gated + keep-best → 0.911→0.914 zero-regression; (4) a catastrophic fix — a SAM negative-point re-prompt (positive points on the dark lung, negative on the spill) that carves the worst engulfing masks the conservative trim can't → 0.914→0.920; (5) a letterbox-component trim that drops mask blobs sitting over near-black padding (on letterboxed films the misregistered atlas + darkness both score the black border as lung — only raw intensity separates it, since lung air is dark-gray, not pure black), fixing MCUCXR_0060 0.76→0.88 zero-regression → 0.920→0.922. The remaining worst cases (bottom row) are a different, harder failure — inferior over-extension into the abdomen, a decoder-boundary error. Localization is not the gap here: even a perfect GT box caps the frozen SAM decoder at ~0.93, which long looked architectural. That cap was specific to SAM, not architecture — swapping in a frozen NON-SAM in-context drawer, SegGPT (BAAI/seggpt-vit-large, generic → leak-free), which paints the whole lung mask in-context from K=8 support (image,mask) pairs with ZERO gradient training and no box/SAM/localizer, reaches 0.9497 ≈ the U-Net's 0.9546 (median 0.9616, n=107) — training-free, needing none of our labels beyond the K=8 in-context supports. This is now the deployed training-free CXR drawer, the 4th backend at the swappable drawer seam, superseding the earlier box-SAM 0.922. A separate few-shot lane (tuning the ~4M-param SAM mask decoder on N=100 labels, encoder frozen, leak-free → 0.9488, median 0.9608, 102/107 improve) reaches the same ballpark by a different route. So CXR's wall was the particular frozen decoder (SAM), not localization and not architecture — and the deployed path is now training-free again at 0.9497 (still −0.005 from NN, a near-tie, not a win).

HC18 Fetal-Head — ultrasound (deployed: training-free retrieval-prompted SegGPT drawer, 0.9667; gallery shows the earlier op_sam+SAM path) ·new

HC18 fetal-head best/worst
The fetal head IS an ellipse — a bright hyperechoic skull ring — so the paper-grounded upgrade fits an ellipse to the SAM mask and snaps to it, interpolating the acoustically-dropped walls (van den Heuvel HC18; YOSAM) → 0.854→0.859. The mean≪median tail then turned out not to be a perception floor: two stacking LLM-agnostic levers on the op_sam CPG localizer — DINOv2-FPS diverse 20-shot supports (feature-farthest-point-sampled; diversity not count) +0.0495, and CLAHE prior-only enhancement (enhance the correspondence prior while SAM decodes on the RAW image) +0.0226 — lift 0.859→0.9225 (median 0.9522), narrowing the gap to U-Net to −0.048. Top: near-perfect ellipse fits (Dice ≈1.0). Bottom: the residual tail. Still loses to the trained U-Net at every budget (an easy-for-NN high-contrast skull), but the "perception floor" was disproven — it was support-diversity + contrast, not irreducible. The deployed drawer is now a swapped 4th frozen backend — a training-free retrieval-prompted SegGPT. A frozen non-SAM in-context segmenter (BAAI/seggpt-vit-large, generic → leak-free, SAM-free) paints the whole skull mask in-context from K=8 support (image,mask) pairs — but crucially the K supports are query-RETRIEVED: for each test frame it picks the K=8 TRAIN images most similar by a frozen-DINOv2 global descriptor (768-d cosine, support_select: 'retrieve'), rather than the earlier linspace-spread selection. This fixes SegGPT's mean≪median failure tail at the SOURCE — matched prompts, not an after-the-fact loop — reaching 0.9667 (median 0.9712, min 0.866, n=100, zero gradient training, zero failures), ≈ NN 0.9703 (−0.004, a near-tie). This is training-free and supersedes both the earlier op_sam+SAM path (0.9225) and the few-shot-tuned decoder (0.9328) — FetalHead moves back out of the few-shot lane. Query-adaptive retrieval is a general drawer knob (a query-adaptive counterpart to the spread/FPS/first-N support-curation family): it raises SegGPT-alone on every tailed domain (ISIC +0.11, Spleen +0.12, Prostate +0.07, Kvasir +0.05, FetalHead +0.03) by matching prompts to the query, a source-level fix; only FetalHead is deployed on it (CXR keeps spread — retrieval is −0.001 noise on near-identical X-rays). Honest caveat: query-adaptive retrieval on medical data can select near-duplicate frames of the query (same subject/scan) — validated leak-free at the ID level (train/test ids disjoint), but within-subject frame-level similarity is a retrieval risk we flag. The earlier few-shot decoder lane (0.9328, weak skull-ring keep-best gate) stays documented as the historical fallback, exactly like CXR's 0.9488.

MSD Prostate — MRI (SegGPT⊕op_sam edge-gated ensemble; op_sam rho 1 box + cross-slice trajectory + reprompt) ·new

prostate MRI best/worst
The prostate is a low-dimensional pose with a smooth cross-slice trajectory (PROMISE12; axial-symmetry prior), so the upgrade fits centroid(z)+area(z) per volume, re-decodes outliers, and reprompts the box → 0.664→0.715 (median 0.786). The 2026-07-05 agent research then tightened the op_sam box (rho 2→1, fewer CPG diffusion steps for this small isodense target; two-split validated, +0.038 val and test) → 0.744, then the meta-harness auto-onboarder surfaced CLAHE prior-enhancement (MRI is low-contrast like US — the same generic knob that lifted HC18) → 0.760 (median 0.803). Top: the small central gland found cleanly. Bottom: the residual tail. Beatable in principle (GT-box→SAM oracle 0.895 > NN 0.815), and there is real headroom — +0.041 oracle from keep-best over a boundary-refinement candidate family (the base slightly over-segments the isodense gland, so the residual is boundary-precision, not localization). Prostate is the cleanest instance of the project's gate wall: valid within-image gates DO exist (DINOv2 / SAM prototype-sim rank-ρ ≈ 0.70; cross-slice area ρ ≈ 0.51 — the boundary-gradient gate that works on spleen/CXR is invalid here, ρ=−0.36, no edge on the isodense gland), yet none harvests the headroom: unconstrained argmax caps at +0.007 (11/30 regress) and zero-regression collapses every gate to ≤+0.0034 (noise). The refined thesis: a valid gate over the whole candidate family is not a valid gate at the DECISION BOUNDARY — ρ=0.70 is earned by ranking the obviously-bad candidates last, while the top cluster (where the best candidate and the base are near-duplicates in both Dice and signal) makes argmax a coin-flip. This domain — the one that had been gate-bound and stuck — is now lifted off its floor and DEPLOYED at 0.7877 (was 0.760, median 0.8483, closing ~35% of the gap to NN 0.815 → −0.028): not by winning the within-op_sam gate, but by adding a complementary second frozen drawer — a SegGPT-retrieve in-context painter — and keeping-best per image on a GT-free edge gate. SegGPT and op_sam are genuinely complementary (they rescue different slices; the keep-best oracle is 0.838), so the win comes from the drawer DIVERSITY, not from a sharper gate on one drawer's candidate family. Both drawers are frozen — training-free, zero gradient. Honest caveat: prostate val is n=20 under a distribution shift, so the +0.0277 magnitude rests on a small split (the direction is robust — edge/compactness/convexity gates all transfer positively).

What we learned

When does iterative feedback deploy? — the fix is general, the gate is the wall

We built a full repair-agent → verbal + visual feedback → SAM re-prompt → keep-best loop: the repair stage renders a diagnosis overlay (current mask + a GT-free "out-of-region" heat-map + a coordinate grid), the vision LLM looks, says what is wrong verbally, and marks the over-segmentation as SAM negative points; SAM re-decodes; a GT-free keep-best gate accepts or rejects; repeat. On chest X-ray the LLM's visual negatives beat the heuristic catastrophic fix (CHNCXR_0447 0.849→0.902, MCUCXR_0055 0.860→0.955).

CXR loop vs feed-forward
The cases the GT-free gate accepted (top = feed-forward catfix, bottom = the loop). The LLM's visual negatives tighten SAM off the mediastinum/abdomen better than the spill heuristic. Full-107: 0.9216→0.9240 (+0.0024), zero-regression, gate near-perfect (oracle 0.9241).

But the fix is domain-general — the LLM can place negatives on any over-seg it sees. What decides deployability is the gate: whether a GT-free signal can rank candidate masks by true Dice. We measured that gate↔Dice correlation on all four domains:

Gate-validity across domains
The loop deploys iff the GT-free gate is valid — a property of the domain, not the loop. CXR (+0.63, lung darkness+atlas) and Spleen (+0.56, soft-tissue) have valid gates and the loop deploys; Kvasir (+0.04 — polyp≈mucosa, no signal) and ISIC (−0.23 — the gate prefers over-grown high-contrast masks) do not, so no amount of good feedback can be deployed. 2 of 4 domains.
The core lesson. Iteration is not the lever — perception, or its GT-free proxy, is. The same wall shows up as the SIZE law, the structural-ceiling taxonomy, and here as gate-validity: a feedback loop is only as deployable as the GT-free mask-quality signal in that domain. Where the target is cheaply separable (dark lung air, soft-tissue organ edges) a gated fix pays off; where it is not (polyp on mucosa) neither a loop nor a single fix can deploy without ground truth.
Honest-reporting note: earlier drafts carried optimistic hardcoded values (ISIC 0.885, Kvasir 0.860, CXR 0.855). This report uses numbers re-measured from scratch with the current pipeline: ISIC 0.880, Spleen 0.920 (CV-held-out), Kvasir 0.8646, CXR 0.9497 (training-free, SegGPT in-context drawer; was 0.922 box-SAM). (Kvasir was 0.659 before the dense-correspondence localizer.)

Pipeline

One image, end to end. A GT-free router selects skills per image; the drawer seam (amber) is the only model-coupled point, now with 4 swappable backends — (1) an LLM polygon/grid drawer, (2) a frozen SAM dense decoder, (3) a few-shot-tuned SAM decoder, and (4) a frozen non-SAM in-context drawer (SegGPT), the new deployed training-free CXR path. A config-driven one dispatch_localizer picks per domain among an LLM polygon drawer, a frozen SAM-feature prototype, a frozen-DINOv2 dense-correspondence (CPG) localizer, or a static box — and everything downstream is numpy/config. Green boxes (🔄) are iterative loops: SAM fixed-point re-prompts and the spleen two-pass within-volume prior.

agenticSeg pipeline flow chart
The deployed pipeline is feed-forward with SAM fixed-point re-prompt loops + a gated repair stage. The four drawer backends now unify behind one config-driven localizer dispatch (Kvasir uses the frozen-DINOv2 CPG dense-correspondence localizer). The red box lists iterative-feedback ideas whose fixes work but that no valid GT-free gate could deploy on no-cue targets (crop-zoom, verbal judge→redraw, keep-best fix-loop, catastrophic negative-point re-prompt) — the recurring lesson: the fix is rarely the bottleneck, the GT-free gate is.