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Main Authors: Zhang, Xinhe, Zhang, Yuyang, Jin, Pengfei, Marin-Llobet, Arnau, Li, Na, Li, Quanzheng
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.19060
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author Zhang, Xinhe
Zhang, Yuyang
Jin, Pengfei
Marin-Llobet, Arnau
Li, Na
Li, Quanzheng
author_facet Zhang, Xinhe
Zhang, Yuyang
Jin, Pengfei
Marin-Llobet, Arnau
Li, Na
Li, Quanzheng
contents High-resolution 3D medical image generation remains challenging because fully volumetric models are computationally expensive, while efficient 2D slice generators often fail to preserve anatomical consistency across the third dimension. We propose LiFT, a framework for Lifted inter-slice Feature Trajectories that factorizes 3D volume synthesis into per-slice image generation and inter-slice trajectory learning. Rather than modeling the volumetric distribution end-to-end, LiFT treats a volume as an ordered trajectory in feature space, capturing how anatomical structures appear, transform, and disappear across depth. A tri-planar drifting loss aligns the trajectory of generated slices with the trajectories of real volumes, enabling distributional learning over inter-slice progressions in unconditional generation; in paired translation, a bidirectional $z$-context mixer trained against the registered target supplies through-plane coherence while preserving per-slice fidelity. We evaluate LiFT on BraTS 2023 (unconditional and missing-modality MR) and SynthRAD2023 (MR-to-CT). Across these settings, LiFT preserves per-slice quality, approaches the reported cWDM missing-MR reconstruction quality at $\sim$$135\times$ lower inference cost (without formal equivalence testing), and improves through-plane coherence on MR-to-CT relative to a no-mapper ablation, demonstrating that lightweight inter-slice trajectory learning is a viable route to high-resolution 3D medical synthesis.
format Preprint
id arxiv_https___arxiv_org_abs_2605_19060
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle LiFT: Lifted Inter-slice Feature Trajectories for 3D Image Generation from 2D Generators
Zhang, Xinhe
Zhang, Yuyang
Jin, Pengfei
Marin-Llobet, Arnau
Li, Na
Li, Quanzheng
Computer Vision and Pattern Recognition
Artificial Intelligence
Image and Video Processing
High-resolution 3D medical image generation remains challenging because fully volumetric models are computationally expensive, while efficient 2D slice generators often fail to preserve anatomical consistency across the third dimension. We propose LiFT, a framework for Lifted inter-slice Feature Trajectories that factorizes 3D volume synthesis into per-slice image generation and inter-slice trajectory learning. Rather than modeling the volumetric distribution end-to-end, LiFT treats a volume as an ordered trajectory in feature space, capturing how anatomical structures appear, transform, and disappear across depth. A tri-planar drifting loss aligns the trajectory of generated slices with the trajectories of real volumes, enabling distributional learning over inter-slice progressions in unconditional generation; in paired translation, a bidirectional $z$-context mixer trained against the registered target supplies through-plane coherence while preserving per-slice fidelity. We evaluate LiFT on BraTS 2023 (unconditional and missing-modality MR) and SynthRAD2023 (MR-to-CT). Across these settings, LiFT preserves per-slice quality, approaches the reported cWDM missing-MR reconstruction quality at $\sim$$135\times$ lower inference cost (without formal equivalence testing), and improves through-plane coherence on MR-to-CT relative to a no-mapper ablation, demonstrating that lightweight inter-slice trajectory learning is a viable route to high-resolution 3D medical synthesis.
title LiFT: Lifted Inter-slice Feature Trajectories for 3D Image Generation from 2D Generators
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Image and Video Processing
url https://arxiv.org/abs/2605.19060