Active Contours Based Segmentation and Lesion Periphery Analysis For Characterization of Skin Lesions in Dermoscopy Images

This paper proposes a computer assisted diagnostic (CAD) system for the detection of melanoma in dermoscopy images. Clinical findings have concluded that in case of melanoma, the lesion borders exhibit differential structures such as pigment networks and streaks as opposed to normal skin spots, which have smoother borders. We aim to validate these findings by performing segmentation of the skin lesions followed by an extraction of the peripheral region of the lesion that is subjected to feature extraction and classification for detecting melanoma. For segmentation, we propose a novel active contours based method that takes an initial lesion contour followed by the usage of Kullback-Leibler divergence between the lesion and skin to fit a curve precisely to the lesion boundaries. After segmentation of the lesion, its periphery is extracted to detect melanoma using image features that are based on local binary patterns. For validation of our algorithms, we have used the publicly available PH $^{2}$ dermoscopy dataset. An extensive experimental analysis reveals two important findings: 1). The proposed segmentation method mimics the ground truth data accurately, outperforming the other methods that have been used for comparison purposes, and 2). The most significant melanoma characteristics in the lesion actually lie on the lesion periphery

Gaussian mixture model based probabilistic modeling of images for medical image segmentation

In this paper, we propose a novel image segmentation algorithm that is based on the probability distributions of the object and background. It uses the variational level sets formulation with a novel region based term in addition to the edge-based term giving a complementary functional, that can potentially result in a robust segmentation of the images. The main theme of the method is that in most of the medical imaging scenarios, the objects are characterized by some typical characteristics such a color, texture, etc. Consequently, an image can be modeled as a Gaussian mixture of distributions corresponding to the object and background. During the procedure of curve evolution, a novel term is incorporated in the segmentation framework which is based on the maximization of the distance between the GMM corresponding to the object and background. The maximization of this distance using differential calculus potentially leads to the desired segmentation results. The proposed method has been used for segmenting images from three distinct imaging modalities i.e. magnetic resonance imaging (MRI), dermoscopy and chromoendoscopy. Experiments show the effectiveness of the proposed method giving better qualitative and quantitative results when compared with the current state-of-the-art. INDEX TERMS Gaussian Mixture Model, Level Sets, Active Contours, Biomedical Engineerin

Knowledge-aware Deep Framework for Collaborative Skin Lesion Segmentation and Melanoma Recognition

Deep learning techniques have shown their superior performance in dermatologist clinical inspection. Nevertheless, melanoma diagnosis is still a challenging task due to the difficulty of incorporating the useful dermatologist clinical knowledge into the learning process. In this paper, we propose a novel knowledge-aware deep framework that incorporates some clinical knowledge into collaborative learning of two important melanoma diagnosis tasks, i.e., skin lesion segmentation and melanoma recognition. Specifically, to exploit the knowledge of morphological expressions of the lesion region and also the periphery region for melanoma identification, a lesion-based pooling and shape extraction (LPSE) scheme is designed, which transfers the structure information obtained from skin lesion segmentation into melanoma recognition. Meanwhile, to pass the skin lesion diagnosis knowledge from melanoma recognition to skin lesion segmentation, an effective diagnosis guided feature fusion (DGFF) strategy is designed. Moreover, we propose a recursive mutual learning mechanism that further promotes the inter-task cooperation, and thus iteratively improves the joint learning capability of the model for both skin lesion segmentation and melanoma recognition. Experimental results on two publicly available skin lesion datasets show the effectiveness of the proposed method for melanoma analysis.Comment: Pattern Recognitio

Transition region based approach for skin lesion segmentation

Skin melanoma is a skin disease that affects nearly 40% of people globally. Manual detection of the area is a time-consuming process and requires expert knowledge. The application of computer vision techniques can simplify this. In this article, a novel unsupervised transition region based approach for skin lesion segmentation for melanoma detection is proposed. The method starts with Gaussian blurring of the green channel dermoscopic image. Further, the transition region is extracted using local variance features and a global thresholding operation. It achieves the region of interest (binary mask) using various morphological operations. Finally, the melanoma regions are segregated from normal skin regions using the binary mask. The proposed method is tested using DermQuest dataset along with ISIC 2017 dataset and it achieves better results as compared to other state of art methods in effectively segmenting the melanoma regions from the normal skin regions

A Review on Skin Disease Classification and Detection Using Deep Learning Techniques

Skin cancer ranks among the most dangerous cancers. Skin cancers are commonly referred to as Melanoma. Melanoma is brought on by genetic faults or mutations on the skin, which are caused by Unrepaired Deoxyribonucleic Acid (DNA) in skin cells. It is essential to detect skin cancer in its infancy phase since it is more curable in its initial phases. Skin cancer typically progresses to other regions of the body. Owing to the disease's increased frequency, high mortality rate, and prohibitively high cost of medical treatments, early diagnosis of skin cancer signs is crucial. Due to the fact that how hazardous these disorders are, scholars have developed a number of early-detection techniques for melanoma. Lesion characteristics such as symmetry, colour, size, shape, and others are often utilised to detect skin cancer and distinguish benign skin cancer from melanoma. An in-depth investigation of deep learning techniques for melanoma's early detection is provided in this study. This study discusses the traditional feature extraction-based machine learning approaches for the segmentation and classification of skin lesions. Comparison-oriented research has been conducted to demonstrate the significance of various deep learning-based segmentation and classification approaches

A survey, review, and future trends of skin lesion segmentation and classification

The Computer-aided Diagnosis or Detection (CAD) approach for skin lesion analysis is an emerging field of research that has the potential to alleviate the burden and cost of skin cancer screening. Researchers have recently indicated increasing interest in developing such CAD systems, with the intention of providing a user-friendly tool to dermatologists to reduce the challenges encountered or associated with manual inspection. This article aims to provide a comprehensive literature survey and review of a total of 594 publications (356 for skin lesion segmentation and 238 for skin lesion classification) published between 2011 and 2022. These articles are analyzed and summarized in a number of different ways to contribute vital information regarding the methods for the development of CAD systems. These ways include: relevant and essential definitions and theories, input data (dataset utilization, preprocessing, augmentations, and fixing imbalance problems), method configuration (techniques, architectures, module frameworks, and losses), training tactics (hyperparameter settings), and evaluation criteria. We intend to investigate a variety of performance-enhancing approaches, including ensemble and post-processing. We also discuss these dimensions to reveal their current trends based on utilization frequencies. In addition, we highlight the primary difficulties associated with evaluating skin lesion segmentation and classification systems using minimal datasets, as well as the potential solutions to these difficulties. Findings, recommendations, and trends are disclosed to inform future research on developing an automated and robust CAD system for skin lesion analysis

Image analysis for diagnostic support in biomedicine: neuromuscular diseases and pigmented lesions

Tesis descargada desde TESEOEsta tesis presenta dos sistemas implementados mediante técnicas de procesamiento de imagen, para ayuda al diagnóstico de enfermedades neuromusculares a partir de imágenes de microscopía de fluorescencia y análisis de lesiones pigmentadas a partir de imágenes dermoscópicas. El diagnóstico de enfermedades neuromusculares se basa en la evaluación visual de las biopsias musculares por parte del patólogo especialista, lo que conlleva una carga subjetiva. El primer sistema propuesto en esta tesis analiza objetivamente las biopsias musculares y las clasifica en distrofias, atrofias neurógenas o control (sin enfermedad) a través de imágenes de microscopía de fluorescencia. Su implementación reúne los elementos propios de un sistema de ayuda al diagnóstico asistido por ordenador: segmentación, extracción de características, selección de características y clasificación. El procedimiento comienza con una segmentación precisa de las fibras musculares usando morfología matemática y una transformada Watershed. A continuación, se lleva a cabo un paso de extracción de características, en el cual reside la principal contribución del sistema, ya que no solo se extraen aquellas que los patólogos tienen en cuenta para diagnosticar sino características que se escapan de la visión humana. Estas nuevas características se extraen suponiendo que la estructura de la biopsia se comporta como un grafo, en el que los nodos se corresponden con las fibras musculares, y dos nodos están conectados si dos fibras son adyacentes. Para estudiar la efectividad que estos dos conjuntos presentan en la categorización de las biopsias, se realiza una selección de características y una clasi- ficación empleando una red neuronal Fuzzy ARTMAP. El procedimiento concluye con una estimación de la severidad de las biopsias con patrón distrófico. Esta caracterización se realiza mediante un análisis de componentes principales. Para la validación del sistema se ha empleado una base de datos compuesta por 91 imágenes de biopsias musculares, de las cuales 71 se consideran imágenes de entrenamiento y 20 imágenes de prueba. Se consigue una elevada tasa de aciertos de clasificacion y se llega a la importante conclusión de que las nuevas características estructurales que no pueden ser detectadas por inspección visual mejoran la identificación de biopsias afectadas por atrofia neurógena. La segunda parte de la tesis presenta un sistema de clasificación de lesiones pigmentadas. Primero se propone un algoritmo de segmentación de imágenes en color para ais lar la lesión de la piel circundante. Su desarrollo se centra en conseguir un algoritmo relacionado con las diferencias color percibidas por el ojo humano. Consiguiendo así, no solo un método de segmentación de lesiones pigmentadas sino un algoritmo de segmentación de propósito general. El método de segmentación propuesto se basa en un gradiente para imágenes en color integrado en una técnica de level set para detección de bordes. La elección del gradiente se derivada a partir de un análisis de tres gradientes de color implementados en el espacio de color uniforme CIE L∗a∗b∗ y basados en las ecuaciones de diferencia de color desarrolladas por la comisión internacional de iluminación (CIELAB, CIE94 y CIEDE2000). El principal objetivo de este análisis es estudiar cómo estas ecuaciones afectan en la estimación de los gradientes en términos de correlación con la percepción visual del color. Una técnica de level-set se aplica sobre estos gradientes consiguiendo así un detector de borde que permite evaluar el rendimiento de dichos gradientes. La validación se lleva a cabo sobre una base de datos compuesta por imágenes sintéticas diseñada para tal fin. Se realizaron tanto medidas cuantitativas como cualitativas. Finalmente, se concluye que el detector de bordes basado en la ecuación de diferencias de color CIE94 presenta la mayor correlación con la percepción visual del color. A partir de entonces, la tesis intenta emular el método de análisis de patrones, la técnica de diagnóstico de lesiones pigmentadas de la piel más empleada por los dermatólogos. Este método trata de identificar patrones específicos, pudiendo ser tanto globales como locales. En esta tesis se presenta una amplia revisión de los métodos algorítmicos, publicados en la literatura, que detectan automáticamente dichos patrones a partir de imágenes dermoscópicas de lesiones pigmentadas. Tras esta revisón se advierte que numerosos trabajos se centran en la detección de patrones locales, pero solo unos pocos abordan la detección de patrones globales. El siguiente paso de esta tesis, por tanto, es la propuesta de diferentes métodos de clasi- ficación de patrones globales. El objetivo es identificar tres patrones: reticular, globular y empedrado (considerado un solo patrón) y homogéneo. Los métodos propuestos se basan en un análisis de textura mediante técnicas de modelado. En primer lugar una imagen demoscópica se modela mediante campos aleatorios de Markov, los parámetros estimados de este modelo se consideran características. A su vez, se supone que la distribución de estas características a lo largo de la lesión sigue diferentes modelos: un modelo gaussiano, un modelo de mezcla de gaussianas o un modelo de bolsa de características. La clasificación se lleva a cabo mediante una recuperación de imágenes basada en diferentes métricas de distancia. Para validar los métodos se emplea un conjunto significativo de imágenes dermatológicas, concluyendo que el modelo basado en mezcla de gaussianas proporciona la mejor tasa de clasificación. Además, se incluye una evaluación adicional en la que se clasifican melanomas con patrón multicomponente obteniendo resultados prometedores. Finalmente, se presenta una discusión sobre los hallazgos y conclusiones más relevantes extraídas de esta tesis, así como las líneas futuras que se derivan de este trabajo.Premio Extraordinario de Doctorado U

Segmentation and lesion detection in dermoscopic images

This thesis was submitted for the award of Doctor of Philosophy and was awarded by Brunel University LondonMalignant melanoma is one of the most fatal forms of skin cancer. It has also become increasingly common, especially among white-skinned people exposed to the sun. Early detection of melanoma is essential to raise survival rates, since its detection at an early stage can be helpful and curable. Working out the dermoscopic clinical features (pigment network and lesion borders) of melanoma is a vital step for dermatologists, who require an accurate method of reaching the correct clinical diagnosis, and ensure the right area receives the correct treatment. These structures are considered one of the main keys that refer to melanoma or non-melanoma disease. However, determining these clinical features can be a time-consuming, subjective (even for trained clinicians) and challenging task for several reasons: lesions vary considerably in size and colour, low contrast between an affected area and the surrounding healthy skin, especially in early stages, and the presence of several elements such as hair, reflections, oils and air bubbles on almost all images. This thesis aims to provide an accurate, robust and reliable automated dermoscopy image analysis technique, to facilitate the early detection of malignant melanoma disease. In particular, four innovative methods are proposed for region segmentation and classification, including two for pigmented region segmentation, one for pigment network detection, and one for lesion classification. In terms of boundary delineation, four pre-processing operations, including Gabor filter, image sharpening, Sobel filter and image inpainting methods are integrated in the segmentation approach to delete unwanted objects (noise), and enhance the appearance of the lesion boundaries in the image. The lesion border segmentation is performed using two alternative approaches. The Fuzzy C-means and the Markov Random Field approaches detect the lesion boundary by repeating the labeling of pixels in all clusters, as a first method. Whereas, the Particle Swarm Optimization with the Markov Random Field method achieves greater accuracy for the same aim by combining them in the second method to perform a local search and reassign all image pixels to its cluster properly. With respect to the pigment network detection, the aforementioned pre-processing method is applied, in order to remove most of the hair while keeping the image information and increase the visibility of the pigment network structures. Therefore, a Gabor filter with connected component analysis are used to detect the pigment network lines, before several features are extracted and fed to the Artificial Neural Network as a classifier algorithm. In the lesion classification approach, the K-means is applied to the segmented lesion to separate it into homogeneous clusters, where important features are extracted; then, an Artificial Neural Network with Radial Basis Functions is trained by representative features to classify the given lesion as melanoma or not. The strong experimental results of the lesion border segmentation methods including Fuzzy C-means with Markov Random Field and the combination between the Particle Swarm Optimization and Markov Random Field, achieved an average accuracy of 94.00% , 94.74% respectively. Whereas, the lesion classification stage by using extracted features form pigment network structures and segmented lesions achieved an average accuracy of 90.1% , 95.97% respectively. The results for the entire experiment were obtained using a public database PH2 comprising 200 images. The results were then compared with existing methods in the literature, which have demonstrated that our proposed approach is accurate, robust, and efficient in the segmentation of the lesion boundary, in addition to its classification