Parallel Implementations Assessment of a Spatial-Spectral Classifier for Hyperspectral Clinical Applications

Lazcano, Raquel; Salvador, Rubén; Marrero-Martín, M.; Leporati, Francesco; Juárez, E.; Callicó, Gustavo M.; Sanz, C.; Madroñal, Daniel; Florimbi, Giordana; Sancho, Jaime; Sánchez, Sergio; Leon, Raquel; Fabelo, Himar; Ortega, Sebastián; Torti, Emanuele

doi:10.1109/access.2019.2938708

Cited by 11 publications

(4 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The state of the art relies on hybrid systems including multicore and many-core devices. The choice of hybrid systems is justified by the features of the processing chains that typically include algorithms with different levels of complexity [17][18][19][20]. The key idea is that each algorithm is managed by the device that best meets the processing constraints.…”

Section: Introductionmentioning

confidence: 99%

Parallel Classification Pipelines for Skin Cancer Detection Exploiting Hyperspectral Imaging on Hybrid Systems

et al. 2020

Self Cite

View full text Add to dashboard Cite

The early detection of skin cancer is of crucial importance to plan an effective therapy to treat the lesion. In routine medical practice, the diagnosis is based on the visual inspection of the lesion and it relies on the dermatologists’ expertise. After a first examination, the dermatologist may require a biopsy to confirm if the lesion is malignant or not. This methodology suffers from false positives and negatives issues, leading to unnecessary surgical procedures. Hyperspectral imaging is gaining relevance in this medical field since it is a non-invasive and non-ionizing technique, capable of providing higher accuracy than traditional imaging methods. Therefore, the development of an automatic classification system based on hyperspectral images could improve the medical practice to distinguish pigmented skin lesions from malignant, benign, and atypical lesions. Additionally, the system can assist general practitioners in first aid care to prevent noncritical lesions from reaching dermatologists, thereby alleviating the workload of medical specialists. In this paper is presented a parallel pipeline for skin cancer detection that exploits hyperspectral imaging. The computational times of the serial processing have been reduced by adopting multicore and many-core technologies, such as OpenMP and CUDA paradigms. Different parallel approaches have been combined, leading to the development of fifteen classification pipeline versions. Experimental results using in-vivo hyperspectral images show that a hybrid parallel approach is capable of classifying an image of 50 × 50 pixels with 125 bands in less than 1 s.

show abstract

Section: Introductionmentioning

confidence: 99%

Parallel Classification Pipelines for Skin Cancer Detection Exploiting Hyperspectral Imaging on Hybrid Systems

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…In-vitro, exvivo, and in-vivo investigations i.e., whether the scene is obtained from a resected sample (in-vitro, ex-vivo) or directly collected from the patient have all exploited the ability to identify the components inside a gathered image (in vivo). In particular, there is an increasing interest in doing In-Vivo HSI processing during operations to aid in the differentiation of malignant and healthy tissues [Lazcano et al (2019)].…”

Section: Introductionmentioning

confidence: 99%

Gradient Boosting Ensembled Method for in-Vivo Brain Tumour Classification Using Hyperspectral Images

Tejasree¹,

Agilandeeswari²

2022

INDJCSE

View full text Add to dashboard Cite

In the past few years, the use of hyperspectral imaging for medicinal purposes has increased. Hyperspectral imaging is a trending topic in the remote sensing field. It is used to collect the spectral information present in the scene. Additionally, the combination of spectral and spatial data offers valuable data for classifying brain tumours. When combined with Machine Learning (ML) algorithms, HSI (Hyperspectral Imaging) can be utilised as a non-intrusive medical diagnosis tool. By using hyperspectral images in the medical field, we can classify cancers, tissues, blood vessels etc. This paper offers a gradient boosting based ensembled classification (MCGC) scheme for In-Vivo brain cancer classification. And also, a multi-scale CNN method feature extraction and graph-based clustering method for feature selection are applied to get accurate classification results. The dataset used for brain cancer classification is the In-Vivo brain cancer dataset. These dataset images are captured when the real-time brain tumour surgery was going on. Finally, we performed the experiment results of gradient boosting ensembled classification methods. Support vector machine (SVM) and Random Forest (RF) classification methods were used to compare the outcomes of classification. And in comparison, with the other existing methods, we got good outcomes.

show abstract

“…In the particular case of brain cancer detection, addressed in this paper, several works benefited from using HS images in the operation room [13][14][15] to precisely detect the borders of a tumor and to help neurosurgeons during the resection process. All of these works aimed to improve both (i) the quality of the classification maps and the results of HS images, and (ii) the acceleration of the algorithms as much as possible, so the process can be executed in real time.…”

Section: Introductionmentioning

confidence: 99%

GoRG: Towards a GPU-Accelerated Multiview Hyperspectral Depth Estimation Tool for Medical Applications

Sancho

Sutradhar

Rosa

et al. 2021

Sensors

Self Cite

View full text Add to dashboard Cite

HyperSpectral (HS) images have been successfully used for brain tumor boundary detection during resection operations. Nowadays, these classification maps coexist with other technologies such as MRI or IOUS that improve a neurosurgeon’s action, with their incorporation being a neurosurgeon’s task. The project in which this work is framed generates an unified and more accurate 3D immersive model using HS, MRI, and IOUS information. To do so, the HS images need to include 3D information and it needs to be generated in real-time operating room conditions, around a few seconds. This work presents Graph cuts Reference depth estimation in GPU (GoRG), a GPU-accelerated multiview depth estimation tool for HS images also able to process YUV images in less than 5.5 s on average. Compared to a high-quality SoA algorithm, MPEG DERS, GoRG YUV obtain quality losses of −0.93 dB, −0.6 dB, and −1.96% for WS-PSNR, IV-PSNR, and VMAF, respectively, using a video synthesis processing chain. For HS test images, GoRG obtains an average RMSE of 7.5 cm, with most of its errors in the background, needing around 850 ms to process one frame and view. These results demonstrate the feasibility of using GoRG during a tumor resection operation.

show abstract

Parallel Implementations Assessment of a Spatial-Spectral Classifier for Hyperspectral Clinical Applications

Cited by 11 publications

References 34 publications

Parallel Classification Pipelines for Skin Cancer Detection Exploiting Hyperspectral Imaging on Hybrid Systems

Parallel Classification Pipelines for Skin Cancer Detection Exploiting Hyperspectral Imaging on Hybrid Systems

Gradient Boosting Ensembled Method for in-Vivo Brain Tumour Classification Using Hyperspectral Images

GoRG: Towards a GPU-Accelerated Multiview Hyperspectral Depth Estimation Tool for Medical Applications

Contact Info

Product

Resources

About