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arxiv_ml 95% Match Research Paper Medical Imaging Researchers,AI Researchers in Healthcare,Quantum ML Researchers,Data Scientists in Pharma 20 hours ago

MediQ-GAN: Quantum-Inspired GAN for High Resolution Medical Image Generation

generative-ai › gans
📄 Abstract

Abstract: Machine learning-assisted diagnosis shows promise, yet medical imaging datasets are often scarce, imbalanced, and constrained by privacy, making data augmentation essential. Classical generative models typically demand extensive computational and sample resources. Quantum computing offers a promising alternative, but existing quantum-based image generation methods remain limited in scale and often face barren plateaus. We present MediQ-GAN, a quantum-inspired GAN with prototype-guided skip connections and a dual-stream generator that fuses classical and quantum-inspired branches. Its variational quantum circuits inherently preserve full-rank mappings, avoid rank collapse, and are theory-guided to balance expressivity with trainability. Beyond generation quality, we provide the first latent-geometry and rank-based analysis of quantum-inspired GANs, offering theoretical insight into their performance. Across three medical imaging datasets, MediQ-GAN outperforms state-of-the-art GANs and diffusion models. While validated on IBM hardware for robustness, our contribution is hardware-agnostic, offering a scalable and data-efficient framework for medical image generation and augmentation.

Key Contributions

MediQ-GAN is a quantum-inspired GAN for high-resolution medical image generation that addresses limitations of classical and quantum GANs. It uses prototype-guided skip connections and a dual-stream generator with variational quantum circuits, offering theoretical insights into quantum-inspired GAN performance and outperforming state-of-the-art methods.

Business Value

Enables the creation of realistic synthetic medical images to augment scarce datasets, improving the training of diagnostic AI models, enhancing privacy, and potentially reducing the need for extensive data collection.

Paper Metadata

Innovation Type

Hybrid Model Architecture / Algorithmic

Deployment Feasibility

Moderate. Requires expertise in both quantum computing concepts and deep learning. Hardware acceleration for quantum circuits might be needed for practical deployment.

Limitations Addressed

Scarcity, imbalance, and privacy issues in medical imaging datasets; high computational and sample resource demands of classical GANs; scale and barren plateau issues in existing quantum GANs.

Performance Gains

Outperforms state-of-the-art methods across three medical imaging datasets.

Technical Tags

Quantum-Inspired GANHigh ResolutionMedical Image GenerationData AugmentationPrivacyVariational Quantum CircuitsPrototype-Guided Skip ConnectionsDual-Stream GeneratorLatent-Geometry AnalysisRank-Based AnalysisBarren Plateaus

Research Topics

Generative ModelsMedical ImagingQuantum ComputingDeep LearningData Augmentation

Methods & Architectures

Quantum-Inspired Generative Adversarial Network (GAN)Variational Quantum CircuitsPrototype-Guided Skip ConnectionsDual-Stream GeneratorLatent-Geometry AnalysisRank-Based Analysis Generative Adversarial Network (GAN)Variational Quantum Circuits

Applications & Tasks

Medical Imaging Healthcare Drug Discovery Scarcity of Medical DataImbalanced DatasetsPrivacy ConstraintsHigh Computational Cost of Classical GANsLimitations of Quantum GANs (Scale, Barren Plateaus) High-Resolution Medical Image GenerationData Augmentation

Related Fields

Quantum ComputingMachine LearningMedical InformaticsComputer VisionGenerative Models

Keywords

GANQuantum ComputingMedical ImagingImage GenerationData AugmentationPrivacy PreservationVariational Quantum CircuitsDeep LearningHigh ResolutionSynthetic DataHealthcare AIMediQ-GANBarren Plateaus

Academic Context

#Generative Models#Medical Imaging#Quantum Computing#Deep Learning#Data Augmentation

Commercial Potential

Potential Products
Synthetic medical image generation platformsData augmentation services for medical AITools for privacy-preserving medical data sharing
Target Industries
HealthcarePharmaceuticalsBiotechnologyMedical Device Manufacturing
Use Case Examples
Generating diverse examples of rare diseases for AI trainingAugmenting datasets for medical image segmentation tasksCreating realistic training data for radiologists
Competitive Edge
Combines the strengths of classical GANs and quantum computing principles to achieve high-quality image generation while mitigating known issues in both domains.
Market Opportunity
Large and growing market for AI in healthcare and medical imaging analysis.
Revenue Models
Licensing the technology to medical imaging companiesoffering synthetic data generation as a service.

Resource Requirements

Compute Needs
High, involving both classical GPU resources for the GAN and potentially quantum computing resources or simulators.
Data Requirements
Medical imaging datasets (e.g., MRI, CT scans).
Deployment Constraints
Requires specialized hardware or cloud access for quantum computation, and integration challenges between classical and quantum components.
Scalability
Scalability is a key focus, aiming to overcome limitations of previous quantum approaches.
Regulatory Considerations
HIPAAFDA regulations for medical devices and AI in healthcare.

Production Readiness

Maturity Level

Research

Time to Market

3-5 years, due to the nascent stage of practical quantum computing integration.

Patent Potential

High, for the novel MediQ-GAN architecture and quantum-inspired generation techniques.

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