Your search keyword '"Francesc Zarzuela Serrat"' showing total 8 results

1. Development of a low-cost robotized 3D-prototype for automated optical microscopy diagnosis: An open-source system.

Author

Allisson Dantas de Oliveira, Carles Rubio Maturana, Francesc Zarzuela Serrat, Bruno Motta Carvalho, Elena Sulleiro, Clara Prats, Anna Veiga, Mercedes Bosch, Javier Zulueta, Alberto Abelló, Elisa Sayrol, Joan Joseph-Munné, and Daniel López-Codina

Subjects

Medicine, Science

Abstract

In a clinical context, conventional optical microscopy is commonly used for the visualization of biological samples for diagnosis. However, the availability of molecular techniques and rapid diagnostic tests are reducing the use of conventional microscopy, and consequently the number of experienced professionals starts to decrease. Moreover, the continuous visualization during long periods of time through an optical microscope could affect the final diagnosis results due to induced human errors and fatigue. Therefore, microscopy automation is a challenge to be achieved and address this problem. The aim of the study is to develop a low-cost automated system for the visualization of microbiological/parasitological samples by using a conventional optical microscope, and specially designed for its implementation in resource-poor settings laboratories. A 3D-prototype to automate the majority of conventional optical microscopes was designed. Pieces were built with 3D-printing technology and polylactic acid biodegradable material with Tinkercad/Ultimaker Cura 5.1 slicing softwares. The system's components were divided into three subgroups: microscope stage pieces, storage/autofocus-pieces, and smartphone pieces. The prototype is based on servo motors, controlled by Arduino open-source electronic platform, to emulate the X-Y and auto-focus (Z) movements of the microscope. An average time of 27.00 ± 2.58 seconds is required to auto-focus a single FoV. Auto-focus evaluation demonstrates a mean average maximum Laplacian value of 11.83 with tested images. The whole automation process is controlled by a smartphone device, which is responsible for acquiring images for further diagnosis via convolutional neural networks. The prototype is specially designed for resource-poor settings, where microscopy diagnosis is still a routine process. The coalescence between convolutional neural network predictive models and the automation of the movements of a conventional optical microscope confer the system a wide range of image-based diagnosis applications. The accessibility of the system could help improve diagnostics and provide new tools to laboratories worldwide.

Published

2024

2. iMAGING: a novel automated system for malaria diagnosis by using artificial intelligence tools and a universal low-cost robotized microscope

Author

Carles Rubio Maturana, Allisson Dantas de Oliveira, Sergi Nadal, Francesc Zarzuela Serrat, Elena Sulleiro, Edurne Ruiz, Besim Bilalli, Anna Veiga, Mateu Espasa, Alberto Abelló, Tomàs Pumarola Suñé, Marta Segú, Daniel López-Codina, Elisa Sayrol Clols, and Joan Joseph-Munné

Subjects

malaria, malaria diagnosis, convolutional neural networks, artificial intelligence, robotized microscope, smartphone application, Microbiology, QR1-502

Abstract

IntroductionMalaria is one of the most prevalent infectious diseases in sub-Saharan Africa, with 247 million cases reported worldwide in 2021 according to the World Health Organization. Optical microscopy remains the gold standard technique for malaria diagnosis, however, it requires expertise, is time-consuming and difficult to reproduce. Therefore, new diagnostic techniques based on digital image analysis using artificial intelligence tools can improve diagnosis and help automate it.MethodsIn this study, a dataset of 2571 labeled thick blood smear images were created. YOLOv5x, Faster R-CNN, SSD, and RetinaNet object detection neural networks were trained on the same dataset to evaluate their performance in Plasmodium parasite detection. Attention modules were applied and compared with YOLOv5x results. To automate the entire diagnostic process, a prototype of 3D-printed pieces was designed for the robotization of conventional optical microscopy, capable of auto-focusing the sample and tracking the entire slide.ResultsComparative analysis yielded a performance for YOLOv5x on a test set of 92.10% precision, 93.50% recall, 92.79% F-score, and 94.40% mAP0.5 for leukocyte, early and mature Plasmodium trophozoites overall detection. F-score values of each category were 99.0% for leukocytes, 88.6% for early trophozoites and 87.3% for mature trophozoites detection. Attention modules performance show non-significant statistical differences when compared to YOLOv5x original trained model. The predictive models were integrated into a smartphone-computer application for the purpose of image-based diagnostics in the laboratory. The system can perform a fully automated diagnosis by the auto-focus and X-Y movements of the robotized microscope, the CNN models trained for digital image analysis, and the smartphone device. The new prototype would determine whether a Giemsa-stained thick blood smear sample is positive/negative for Plasmodium infection and its parasite levels. The whole system was integrated into the iMAGING smartphone application.ConclusionThe coalescence of the fully-automated system via auto-focus and slide movements and the autonomous detection of Plasmodium parasites in digital images with a smartphone software and AI algorithms confers the prototype the optimal features to join the global effort against malaria, neglected tropical diseases and other infectious diseases.

Published

2023

3. COVID-19: an opportunity of systematic integration for Chagas disease. Example of a community-based approach within the Bolivian population in Barcelona

Author

Jordi Gómez i Prat, Hakima Ouaarab Essadek, Juliana Esperalba, Francesc Zarzuela Serrat, Isabel Claveria Guiu, Lidia Goterris, Ricardo Zules-Oña, Estefa Choque, Conxita Pastoret, Natàlia Casamitjana Ponces, Juan José de los Santos, Jordi Serrano Pons, Aurore Dehousse, Pedro Albajar-Viñas, Tomàs Pumarola, Magda Campins, and Elena Sulleiro

Subjects

Chagas disease, COVID-19, Community-based approach, Opportunity of systematic integration, Bolivia, Barcelona, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background As a Neglected Tropical Disease associated with Latin America, Chagas Disease (CD) is little known in non-endemic territories of the Americas, Europe and Western Pacific, making its control challenging, with limited detection rates, healthcare access and consequent epidemiological silence. This is reinforced by its biomedical characteristics—it is usually asymptomatic—and the fact that it mostly affects people with low social and financial resources. Because CD is mainly a chronic infection, which principally causes a cardiomyopathy and can also cause a prothrombotic status, it increases the risk of contracting severe COVID-19. Methods In order to get an accurate picture of CD and COVID-19 overlapping and co-infection, this operational research draws on community-based experience and participative-action-research components. It was conducted during the Bolivian elections in Barcelona on a representative sample of that community. Results The results show that 55% of the people interviewed had already undergone a previous T. cruzi infection screening—among which 81% were diagnosed in Catalonia and 19% in Bolivia. The prevalence of T. cruzi infection was 18.3% (with 3.3% of discordant results), the SARS-CoV-2 22.3% and the coinfection rate, 6%. The benefits of an integrated approach for COVID-19 and CD were shown, since it only took an average of 25% of additional time per patient and undoubtedly empowered the patients about the co-infection, its detection and care. Finally, the rapid diagnostic test used for COVID-19 showed a sensitivity of 89.5%. Conclusions This research addresses CD and its co-infection, through an innovative way, an opportunity of systematic integration, during the COVID-19 pandemic.

Published

2022

4. Advances and challenges in automated malaria diagnosis using digital microscopy imaging with artificial intelligence tools: A review

Author

Carles Rubio Maturana, Allisson Dantas de Oliveira, Sergi Nadal, Besim Bilalli, Francesc Zarzuela Serrat, Mateu Espasa Soley, Elena Sulleiro Igual, Mercedes Bosch, Anna Veiga Lluch, Alberto Abelló, Daniel López-Codina, Tomàs Pumarola Suñé, Elisa Sayrol Clols, and Joan Joseph-Munné

Subjects

malaria diagnosis, digital imaging techniques, deep learning, artificial intelligence, microscopic examination, smartphone application, Microbiology, QR1-502

Abstract

Malaria is an infectious disease caused by parasites of the genus Plasmodium spp. It is transmitted to humans by the bite of an infected female Anopheles mosquito. It is the most common disease in resource-poor settings, with 241 million malaria cases reported in 2020 according to the World Health Organization. Optical microscopy examination of blood smears is the gold standard technique for malaria diagnosis; however, it is a time-consuming method and a well-trained microscopist is needed to perform the microbiological diagnosis. New techniques based on digital imaging analysis by deep learning and artificial intelligence methods are a challenging alternative tool for the diagnosis of infectious diseases. In particular, systems based on Convolutional Neural Networks for image detection of the malaria parasites emulate the microscopy visualization of an expert. Microscope automation provides a fast and low-cost diagnosis, requiring less supervision. Smartphones are a suitable option for microscopic diagnosis, allowing image capture and software identification of parasites. In addition, image analysis techniques could be a fast and optimal solution for the diagnosis of malaria, tuberculosis, or Neglected Tropical Diseases in endemic areas with low resources. The implementation of automated diagnosis by using smartphone applications and new digital imaging technologies in low-income areas is a challenge to achieve. Moreover, automating the movement of the microscope slide and image autofocusing of the samples by hardware implementation would systemize the procedure. These new diagnostic tools would join the global effort to fight against pandemic malaria and other infectious and poverty-related diseases.

Published

2022

5. Unexpected false-negative result in a traveller's malaria diagnosis

Author

Arantxa Perez-Ugarte, Carles Rubio Maturana, Aroa Silgado, Francesc Zarzuela Serrat, Lidia Goterris, Fernando Paredes-Carmona, Elena Sulleiro, and Universitat Politècnica de Catalunya. Departament de Física

Subjects

Malaria--Diagnosis--Evaluation, Prozone effect, Ciències de la salut::Medicina [Àrees temàtiques de la UPC], Malària--Diagnòstic, Rapid diagnostic tests, HRP-2, General Medicine, Microscopic examination, Malaria

Abstract

A 4-year-old male presented at the emergency room for a 4-day-history of fever, diarrhoea and vomiting. The family had returned from Senegal 1 day before presenting to our clinic. None of the family had taken malaria prophylaxis. Because of a recent travel history, investigations to rule out malaria were initiated. These included a rapid antigen detection test (RDT; BinaxNow® Malaria, Abbott, USA) and microscopy examination.

Published

2022

6. COVID-19: an opportunity of systematic integration for Chagas disease. Example of a community-based approach within the Bolivian population in Barcelona

Author

Estefa Choque, Hakima Ouaarab Essadek, Juliana Esperalba, Francesc Zarzuela Serrat, Jordi Serrano Pons, Aurore Dehousse, Pedro Albajar-Viñas, Magda Campins, Tomás Pumarola, Lidia Goterris, Jordi Gómez i Prat, Conxita Pastoret, Juan José de los Santos, Elena Sulleiro, Natàlia Casamitjana Ponce, Isabel Claveria Guiu, Ricardo Zules-Oña, Institut Català de la Salut, [Gómez Prat J, Ouaarab Essadek H, Claveria Guiu I, Choque E] Unitat de Medicina Tropical i Salut Internacional, Drassanes- Vall d’Hebron Hospital Universitari, Barcelona, Spain. PROSICS, Barcelona, Spain. Servei de Medicina Preventiva, Vall d’Hebron Hospital Universitari, Barcelona, Spain. Asociación de Amigos de las Personas con la Enfermedad de Chagas (ASAPECHA), Barcelona, Spain. [Esperalba J, Zarzuela Serrat F, Goterris L, Pumarola T, Sulleiro E] Servei de Microbiologia, Vall d’Hebron Hospital Universitari, Barcelona, Spain. [Zules-Oña R, Campins M] Servei de Medicina Preventiva i Epidemiologia, Vall d’Hebron Hospital Universitari, Barcelona, Spain, and Vall d'Hebron Barcelona Hospital Campus

Subjects

Chagas disease, Community based, education.field_of_study, Bolivia, Coronavirus disease 2019 (COVID-19), SARS-CoV-2, Chagas, Malaltia de - Diagnòstic, Population, Otros calificadores::/diagnóstico [Otros calificadores], COVID-19, Virus Diseases::RNA Virus Infections::Nidovirales Infections::Coronaviridae Infections::Coronavirus Infections [DISEASES], medicine.disease, COVID-19 (Malaltia), enfermedades parasitarias::infecciones por protozoos::infecciones por Euglenozoa::tripanosomiasis::enfermedad de Chagas [ENFERMEDADES], Geography, Infectious Diseases, Environmental health, Other subheadings::/diagnosis [Other subheadings], virosis::infecciones por virus ARN::infecciones por Nidovirales::infecciones por Coronaviridae::infecciones por Coronavirus [ENFERMEDADES], medicine, Humans, Chagas Disease, education, Pandemics, Parasitic Diseases::Protozoan Infections::Euglenozoa Infections::Trypanosomiasis::Chagas Disease [DISEASES]

Abstract

Background As a Neglected Tropical Disease associated with Latin America, Chagas Disease (CD) is little known in non-endemic territories of the Americas, Europe and Western Pacific, making its control challenging, with limited detection rates, healthcare access and consequent epidemiological silence. This is reinforced by its biomedical characteristics—it is usually asymptomatic—and the fact that it mostly affects people with low social and financial resources. Because CD is mainly a chronic infection, which principally causes a cardiomyopathy and can also cause a prothrombotic status, it increases the risk of contracting severe COVID-19. Methods In order to get an accurate picture of CD and COVID-19 overlapping and co-infection, this operational research draws on community-based experience and participative-action-research components. It was conducted during the Bolivian elections in Barcelona on a representative sample of that community. Results The results show that 55% of the people interviewed had already undergone a previous T. cruzi infection screening—among which 81% were diagnosed in Catalonia and 19% in Bolivia. The prevalence of T. cruzi infection was 18.3% (with 3.3% of discordant results), the SARS-CoV-2 22.3% and the coinfection rate, 6%. The benefits of an integrated approach for COVID-19 and CD were shown, since it only took an average of 25% of additional time per patient and undoubtedly empowered the patients about the co-infection, its detection and care. Finally, the rapid diagnostic test used for COVID-19 showed a sensitivity of 89.5%. Conclusions This research addresses CD and its co-infection, through an innovative way, an opportunity of systematic integration, during the COVID-19 pandemic.

Published

2022

7. A proposal for automatic diagnosis of malaria: extended abstract.

Author

Allisson Dantas Oliveira, Giordano Cabral 0001, Daniel López, Caetano Firmo, Francesc Zarzuela Serrat, and Jones Oliveira de Albuquerque

Published

2013

8. The malaria system microApp: A new, mobile device-based tool for malaria diagnosis

Author

Cristina Montañola Sales, Aroa Silgado, Clara Prats, Mércia Eliane de Arruda, Francesc Zarzuela Serrat, Mateu Espasa, Allisson Dantas Oliveira, Daniel López Codina, Jordi Gómez i Prat, Jones Albuquerque, Universitat Politècnica de Catalunya. Departament de Física, Universitat Politècnica de Catalunya. BIOCOM-SC - Grup de Biologia Computacional i Sistemes Complexos, and Universitat Politècnica de Catalunya. MPI - Modelització i Processament de la Informació

Subjects

Informàtica::Aplicacions de la informàtica::Bioinformàtica [Àrees temàtiques de la UPC], Boosting (machine learning), automated diagnosis, applied computing, Computer science, malaria, Malària, Image processing, 0603 philosophy, ethics and religion, computer.software_genre, 03 medical and health sciences, mobile devices, 0302 clinical medicine, parasitic diseases, medicine, Preprocessor, 030212 general & internal medicine, Face detection, Original Paper, 06 humanities and the arts, General Medicine, medicine.disease, artificial intelligence, Tractament del senyal, Diagnosis of malaria, Proof of concept, Ciències de la salut::Medicina::Medicina comunitària i salut pública [Àrees temàtiques de la UPC], Imatgeria mèdica, 060301 applied ethics, Data mining, Mobile device, computer, Malaria, Ciències de la salut [Àrees temàtiques de la UPC]

Abstract

Background: Malaria is a public health problem that affects remote areas worldwide. Climate change has contributed to the problem by allowing for the survival of Anopheles in previously uninhabited areas. As such, several groups have made developing news systems for the automated diagnosis of malaria a priority. Objective: The objective of this study was to develop a new, automated, mobile device-based diagnostic system for malaria. The system uses Giemsa-stained peripheral blood samples combined with light microscopy to identify the Plasmodium falciparum species in the ring stage of development. Methods: The system uses image processing and artificial intelligence techniques as well as a known face detection algorithm to identify Plasmodium parasites. The algorithm is based on integral image and haar-like features concepts, and makes use of weak classifiers with adaptive boosting learning. The search scope of the learning algorithm is reduced in the preprocessing step by removing the background around blood cells. Results: As a proof of concept experiment, the tool was used on 555 malaria-positive and 777 malaria-negative previously-made slides. The accuracy of the system was, on average, 91%, meaning that for every 100 parasite-infected samples, 91 were identified correctly. Conclusions: Accessibility barriers of low-resource countries can be addressed with low-cost diagnostic tools. Our system, developed for mobile devices (mobile phones and tablets), addresses this by enabling access to health centers in remote communities, and importantly, not depending on extensive malaria expertise or expensive diagnostic detection equipment.