Artificial intelligence algorithm for predicting mortality of patients with acute heart failure

Kwon, Joon; Kim, Kyung Hee; Jeon, Ki‐Hyun; Lee, Sang Eun; Lee, Hae Young; Cho, Hyun Jai; Choi, Jin Oh; Jeon, Eun Seok; Kim, Min Seok; Kim, Jae Joong; Hwang, Kyung Kuk; Chae, Shung Chull; Baek, Sang Hong; Kang, Seok Min; Choi, Dong Ju; Yoo, Byung Su; Kim, Kye Hun; Park, Hyun-Young; Cho, Myeong Chan; Oh, Byung Hee

doi:10.1371/journal.pone.0219302

Cited by 100 publications

(74 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Large-scale data (big data) in our case when referring to a rare disease have been adapted to the number of cases available; this kind of analysis is a new tool that has recently been incorporated into biomedical activity; machine learning is the study of computer algorithms that improve automatically through experience and it involves a wide series of algorithms, classification and regression models such as decision trees being some of them [ 26 – 29 ]. This methodology is especially useful for obtaining pooled information on the diversity of outcomes and identifying prognostic factors potentially related to disease complications [ 35 ]. In rare disease research, this is of particular interest due to the scarcity and the spread of the data among the different centers [ 36 ].…”

Section: Discussionmentioning

confidence: 99%

Identification of risk features for complication in Gaucher’s disease patients: a machine learning analysis of the Spanish registry of Gaucher disease

Andrade‐Campos

Frutos

Cebolla

et al. 2020

Orphanet J Rare Dis

View full text Add to dashboard Cite

Background Since enzyme replacement therapy for Gaucher disease (MIM#230800) has become available, both awareness of and the natural history of the disease have changed. However, there remain unmet needs such as the identification of patients at risk of developing bone crisis during therapy and late complications such as cancer or parkinsonism. The Spanish Gaucher Disease Registry has worked since 1993 to compile demographic, clinical, genetic, analytical, imaging and follow-up data from more than 400 patients. The aims of this study were to discover correlations between patients’ characteristics at diagnosis and to identify risk features for the development of late complications; for this a machine learning approach involving correlation networks and decision trees analyses was applied. Results A total of 358 patients, 340 type 1 Gaucher disease and 18 type 3 cases were selected. 18% were splenectomyzed and 39% had advanced bone disease. 81% of cases carried heterozygous genotype. 47% of them were diagnosed before the year 2000. Mean age at diagnosis and therapy were 28 and 31.5 years old (y.o.) respectively. 4% developed monoclonal gammopathy undetermined significance or Parkinson Disease, 6% cancer, and 10% died before this study. Previous splenectomy correlates with the development of skeletal complications and severe bone disease (p = 0.005); serum levels of IgA, delayed age at start therapy (> 9.5 y.o. since diagnosis) also correlates with severe bone disease at diagnosis and with the incidence of bone crisis during therapy. High IgG (> 1750 mg/dL) levels and age over 60 y.o. at diagnosis were found to be related with the development of cancer. When modelling the decision tree, patients with a delayed diagnosis and therapy were the most severe and with higher risk of complications. Conclusions Our work confirms previous observations, highlights the importance of early diagnosis and therapy and identifies new risk features such as high IgA and IgG levels for long-term complications.

show abstract

Section: Discussionmentioning

confidence: 99%

Identification of risk features for complication in Gaucher’s disease patients: a machine learning analysis of the Spanish registry of Gaucher disease

Andrade‐Campos

Frutos

Cebolla

et al. 2020

Orphanet J Rare Dis

View full text Add to dashboard Cite

show abstract

“…Today, AI is already used in healthcare [26] for example to decrease false-positive results in screening for breast cancer [27], [28], reduce medical transcription costs [29], improve physician workflow while relieving and helping to prevent burnout [30], robotic surgery resulting in shorter length of hospitalization and loss of blood [31] and predicting mortality rates of patients with acute heart failure [32].…”

Section: Ai In Healthcarementioning

confidence: 99%

Short Keynote Paper: Mainstreaming Personalized Healthcare-Transforming Healthcare through new era of Artificial Intelligence

Paranjape

Schinkel

Nanayakkara

2020

IEEE J. Biomed. Health Inform.

View full text Add to dashboard Cite

Medicine has entered the digital era, driven by data from new modalities, especially genomics and imaging, as well as new sources such as wearables and Internet of Things. As we gain a deeper understanding of the disease biology and how diseases affect an individual, we are developing targeted therapies to personalize treatments. There is a need for technologies like Artificial Intelligence (AI) to be able to support predictions for personalized treatments. In order to mainstream AI in healthcare we will need to address issues such as explainability, liability and privacy. Developing explainable algorithms and including AI training in medical education are many of the solutions that can help alleviate these concerns.

show abstract

“…Поэтому, в своей работе мы использовали относительно неглубокую сеть. Указанное обстоятельство несколько снижает чувствительность созданной прогностической модели [9].…”

Section: Aimunclassified

“…Дальнейшее увеличение обучаемой выборки позволит выявить наиболее значимые признаки, исследовать признаки на наличие выбросов. С помощью искусственного увеличения тренировочного корпуса, путем различных аугментаций можно нарастить мощность нейронной сети за счёт добавления свёрточных и рекуррентных слоев, что позволит анализировать выявленные закономерности во времени [9][10][11].…”

unclassified

Neural network analysis of mortality risk predictors in patients after acute coronary syndrome

et al. 2020

View full text Add to dashboard Cite

Цель. Изучить возможности применения нейросетевого анализа клиникоинструментальных данных для прогнозирования риска летальных исходов у больных после перенесенного острого коронарного синдрома (ОКС). Материал и методы. Четыреста пациентов после перенесенного ОКС наблюдались в течение 62 мес. Критерий осложнённого течения ишемической болезни сердца (ИБС) -летальный исход кардиогенной причины. Группу 1 наблюдения составили 310 больных с неосложненным течением и 2 группу 90 больных с осложненным течением ИБС. Для прогнозирования летального риска использовали метод машинного обучения и нейросетевого анализа. Машинное обучение проводилось с включением клинических, лабораторных и инструментальных (электрокардиография, эхокардиография) признаков (всего 49). Для решения задач классификации использованы два вида архитектур нейросетей: многослойный персептрон (Multilayer Perceptron (MLP)) и свёрточная нейронная сеть (Convolutional Neural Networks (CNN)). Соотношение в примерах на обучение и валидацию составило 340/60. Использовался метод обучения с учителем на имеющихся данных, в которых были известны исходы, а параметры нейронной сети подстраивались так, чтобы минимизировать ошибку. Результаты. Наибольший вклад в риск летального исхода после ОКС вносят возраст больных, перенесенный ранее ИМ и острое нарушение мозгового кровообращения, наличие фибрилляции предсердий, 2 стадия и 3 функциональный класс хронической недостаточности кровообращения, отсутствие чрескожного коронарного вмешательства, 3 стадия хронической болезни почек, сниженная фракция выброса левого желудочка. Большая часть летальных случаев приходилась на 2 и 4 годы наблюдения больных, что, возможно, связано с низкой эффективностью вторичной профилактики ИБС. Исследуемая архитектура свёрточной нейронной сети оказалась более точной моделью диагностики. Чувствительность 68% и специфичность 84%, при хорошем качестве модели (area under curve (AUC) =0,74). К преимуществам CNN относится возможность анализировать закономерности во времени, используя рекуррентные нейронные сети. Заключение. Нейросетевой анализ подготовленных клинических, лабораторных и инструментальных данных позволяет настроить параметры сети для последующего прогнозирования летального риска. Использование свёрточной нейронной сети с чувствительностью 68% и специфичностью 84% прогнозирует риск летального исхода на протяжении 5 лет после ОКС.Ключевые слова: нейронная сеть, машинное обучение, острый коронарный синдром, летальность. Отношения и деятельность: нет.

show abstract

Artificial intelligence algorithm for predicting mortality of patients with acute heart failure

Cited by 100 publications

References 30 publications

Identification of risk features for complication in Gaucher’s disease patients: a machine learning analysis of the Spanish registry of Gaucher disease

Identification of risk features for complication in Gaucher’s disease patients: a machine learning analysis of the Spanish registry of Gaucher disease

Short Keynote Paper: Mainstreaming Personalized Healthcare-Transforming Healthcare through new era of Artificial Intelligence

Neural network analysis of mortality risk predictors in patients after acute coronary syndrome

Contact Info

Product

Resources

About