CutisAI: Deep Learning Framework for Automated Dermatology and Cancer Screening
- URL: http://arxiv.org/abs/2601.02562v1
- Date: Mon, 05 Jan 2026 21:29:08 GMT
- Title: CutisAI: Deep Learning Framework for Automated Dermatology and Cancer Screening
- Authors: Rohit Kaushik, Eva Kaushik,
- Abstract summary: We present the Conformal Bayesian Dermatological (CBDC) framework that combines Statistical Learning Theory, Topological Data Analysis, and Bayesian Conformal Inference.<n>CBDC attains classification accuracy and generates calibrated predictions that are interpretable from a clinical perspective.<n>This research constitutes a theoretical and practical leap for deep dermatological diagnostics, thereby opening the machine learning theory clinical applicability interface.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The rapid growth of dermatological imaging and mobile diagnostic tools calls for systems that not only demonstrate empirical performance but also provide strong theoretical guarantees. Deep learning models have shown high predictive accuracy; however, they are often criticized for lacking well, calibrated uncertainty estimates without which these models are hardly deployable in a clinical setting. To this end, we present the Conformal Bayesian Dermatological Classifier (CBDC), a well, founded framework that combines Statistical Learning Theory, Topological Data Analysis (TDA), and Bayesian Conformal Inference. CBDC offers distribution, dependent generalization bounds that reflect dermatological variability, proves a topological stability theorem that guarantees the invariance of convolutional neural network embeddings under photometric and morphological perturbations and provides finite conformal coverage guarantees for trustworthy uncertainty quantification. Through exhaustive experiments on the HAM10000, PH2, and ISIC 2020 datasets, we show that CBDC not only attains classification accuracy but also generates calibrated predictions that are interpretable from a clinical perspective. This research constitutes a theoretical and practical leap for deep dermatological diagnostics, thereby opening the machine learning theory clinical applicability interface.
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