38 research outputs found

    Assessment of Dispersion and Bubble Entropy Measures for Enhancing Preterm Birth Prediction Based on Electrohysterographic Signals

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    [EN] One of the remaining challenges for the scientific-technical community is predicting preterm births, for which electrohysterography (EHG) has emerged as a highly sensitive prediction technique. Sample and fuzzy entropy have been used to characterize EHG signals, although they require optimizing many internal parameters. Both bubble entropy, which only requires one internal parameter, and dispersion entropy, which can detect any changes in frequency and amplitude, have been proposed to characterize biomedical signals. In this work, we attempted to determine the clinical value of these entropy measures for predicting preterm birth by analyzing their discriminatory capacity as an individual feature and their complementarity to other EHG characteristics by developing six prediction models using obstetrical data, linear and non-linear EHG features, and linear discriminant analysis using a genetic algorithm to select the features. Both dispersion and bubble entropy better discriminated between the preterm and term groups than sample, spectral, and fuzzy entropy. Entropy metrics provided complementary information to linear features, and indeed, the improvement in model performance by including other non-linear features was negligible. The best model performance obtained an F1-score of 90.1 ± 2% for testing the dataset. This model can easily be adapted to real-time applications, thereby contributing to the transferability of the EHG technique to clinical practice.This work was supported by the Spanish Ministry of Economy and Competitiveness, the European Regional Development Fund (MCIU/AEI/FEDER, UE RTI2018-094449-A-I00-AR), and by the Generalitat Valenciana (AICO/2019/220)Nieto Del-Amor, F.; Beskhani, R.; Ye Lin, Y.; Garcia-Casado, J.; Díaz-Martínez, MDA.; Monfort-Ortiz, R.; Diago-Almela, VJ.... (2021). Assessment of Dispersion and Bubble Entropy Measures for Enhancing Preterm Birth Prediction Based on Electrohysterographic Signals. Sensors. 21(18):1-17. https://doi.org/10.3390/s21186071S117211

    Optimization of Imminent Labor Prediction Systems in Women with Threatened Preterm Labor Based on Electrohysterography

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    [EN] Preterm birth is the leading cause of death in newborns and the survivors are prone to health complications. Threatened preterm labor (TPL) is the most common cause of hospitalization in the second half of pregnancy. The current methods used in clinical practice to diagnose preterm labor, the Bishop score or cervical length, have high negative predictive values but not positive ones. In this work we analyzed the performance of computationally efficient classification algorithms, based on electrohysterographic recordings (EHG), such as random forest (RF), extreme learning machine (ELM) and K-nearest neighbors (KNN) for imminent labor (<7 days) prediction in women with TPL, using the 50th or 10th-90th percentiles of temporal, spectral and nonlinear EHG parameters with and without obstetric data inputs. Two criteria were assessed for the classifier design: F1-score and sensitivity. RFF1_2 and ELMF1_2 provided the highest F1-score values in the validation dataset, (88.17 +/- 8.34% and 90.2 +/- 4.43%) with the 50th percentile of EHG and obstetric inputs. ELMF1_2 outperformed RFF1_2 in sensitivity, being similar to those of ELMSens (sensitivity optimization). The 10th-90th percentiles did not provide a significant improvement over the 50th percentile. KNN performance was highly sensitive to the input dataset, with a high generalization capability.This work was supported by the Spanish Ministry of Economy and Competitiveness, the European Regional Development Fund (MCIU/AEI/FEDER, UE RTI2018-094449-A-I00-AR); by the Generalitat Valenciana (AICO/2019/220).Prats-Boluda, G.; Pastor-Tronch, J.; Garcia-Casado, J.; Monfort-Ortiz, R.; Perales Marín, A.; Diago, V.; Roca Prats, A.... (2021). Optimization of Imminent Labor Prediction Systems in Women with Threatened Preterm Labor Based on Electrohysterography. Sensors. 21(7):1-18. https://doi.org/10.3390/s21072496S11821

    Optimized Feature Subset Selection Using Genetic Algorithm for Preterm Labor Prediction Based on Electrohysterography

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    [EN] Electrohysterography (EHG) has emerged as an alternative technique to predict preterm labor, which still remains a challenge for the scientific-technical community. Based on EHG parameters, complex classification algorithms involving non-linear transformation of the input features, which clinicians found difficult to interpret, were generally used to predict preterm labor. We proposed to use genetic algorithm to identify the optimum feature subset to predict preterm labor using simple classification algorithms. A total of 203 parameters from 326 multichannel EHG recordings and obstetric data were used as input features. We designed and validated 3 base classifiers based on k-nearest neighbors, linear discriminant analysis and logistic regression, achieving F1-score of 84.63 ± 2.76%, 89.34 ± 3.5% and 86.87 ± 4.53%, respectively, for incoming new data. The results reveal that temporal, spectral and non-linear EHG parameters computed in different bandwidths from multichannel recordings provide complementary information on preterm labor prediction. We also developed an ensemble classifier that not only outperformed base classifiers but also reduced their variability, achieving an F1-score of 92.04 ± 2.97%, which is comparable with those obtained using complex classifiers. Our results suggest the feasibility of developing a preterm labor prediction system with high generalization capacity using simple easy-to-interpret classification algorithms to assist in transferring the EHG technique to clinical practice.This work was supported by the Spanish Ministry of Economy and Competitiveness, the European Regional Development Fund (MCIU/AEI/FEDER, UE RTI2018-094449-A-I00-AR) and by the Generalitat Valenciana (AICO/2019/220).Nieto-Del-Amor, F.; Prats-Boluda, G.; Martínez-De-Juan, JL.; Díaz-Martínez, MDA.; Monfort-Ortiz, R.; Diago-Almela, VJ.; Ye Lin, Y. (2021). Optimized Feature Subset Selection Using Genetic Algorithm for Preterm Labor Prediction Based on Electrohysterography. Sensors. 21(10):1-15. https://doi.org/10.3390/s21103350S115211

    Electrohysterogram for ANN-Based Prediction of Imminent Labor in Women with Threatened Preterm Labor Undergoing Tocolytic Therapy

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    [EN] Threatened preterm labor (TPL) is the most common cause of hospitalization in the second half of pregnancy and entails high costs for health systems. Currently, no reliable labor proximity prediction techniques are available for clinical use. Regular checks by uterine electrohysterogram (EHG) for predicting preterm labor have been widely studied. The aim of the present study was to assess the feasibility of predicting labor with a 7- and 14-day time horizon in TPL women, who may be under tocolytic treatment, using EHG and/or obstetric data. Based on 140 EHG recordings, artificial neural networks were used to develop prediction models. Non-linear EHG parameters were found to be more reliable than linear for differentiating labor in under and over 7/14 days. Using EHG and obstetric data, the <7- and <14-day labor prediction models achieved an AUC in the test group of 87.1 +/- 4.3% and 76.2 +/- 5.8%, respectively. These results suggest that EHG can be reliable for predicting imminent labor in TPL women, regardless of the tocolytic therapy stage. This paves the way for the development of diagnostic tools to help obstetricians make better decisions on treatments, hospital stays and admitting TPL women, and can therefore reduce costs and improve maternal and fetal wellbeing.This work was supported by the Spanish Ministry of Economy and Competitiveness, the European Regional Development Fund (MCIU/AEI/FEDER, UE RTI2018-094449-A-I00-AR) and by the Generalitat Valenciana (AICO/2019/220).Mas-Cabo, J.; Prats-Boluda, G.; Garcia-Casado, J.; Alberola Rubio, J.; Monfort-Ortiz, R.; Martinez-Saez, C.; Perales, A.... (2020). Electrohysterogram for ANN-Based Prediction of Imminent Labor in Women with Threatened Preterm Labor Undergoing Tocolytic Therapy. 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    Prediction of labor onset type: Spontaneous vs induced; role of electrohysterography?

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    Background and objective Induction of labor (IOL) is a medical procedure used to initiate uterine contractions to achieve delivery. IOL entails medical risks and has a significant impact on both the mother's and newborn's well-being. The assistance provided by an automatic system to help distinguish patients that will achieve labor spontaneously from those that will need late-term IOL would help clinicians and mothers to take an informed decision about prolonging pregnancy. With this aim, we developed and evaluated predictive models using not only traditional obstetrical data but also electrophysiological parameters derived from the electrohysterogram (EHG). Methods EHG recordings were made on singleton term pregnancies. A set of 10 temporal and spectral parameters was calculated to characterize EHG bursts and a further set of 6 common obstetrical parameters was also considered in the predictive models design. Different models were implemented based on single layer Support Vector Machines (SVM) and with aggregation of majority voting of SVM (double layer), to distinguish between the two groups: term spontaneous labor (&#8804;41 weeks of gestation) and IOL late-term labor. The areas under the curve (AUC) of the models were compared. Results The obstetrical and EHG parameters of the two groups did not show statistically significant differences. The best results of non-contextualized single input parameter SVM models were achieved by the Bishop Score (AUC =&#8201;0.65) and GA at recording time (AUC =&#8201;0.68) obstetrical parameters. The EHG parameter median frequency, when contextualized with the two obstetrical parameters improved these results, reaching AUC =&#8201;0.76. Multiple input SVM obtained AUC =&#8201;0.70 for all EHG parameters. Aggregation of majority voting of SVM models using contextualized EHG parameters achieved the best result AUC =&#8201;0.93. Conclusions Measuring the electrophysiological uterine condition by means of electrohysterographic recordings yielded a promising clinical decision support system for distinguishing patients that will spontaneously achieve active labor before the end of full term from those who will require late term IOL. The importance of considering these EHG measurements in the patient's individual context was also shown by combining EHG parameters with obstetrical parameters. Clinicians considering elective labor induction would benefit from this technique.General Electric HealthcareAlberola Rubio, J.; Garcia Casado, FJ.; Prats-Boluda, G.; Ye Lin, Y.; Desantes, D.; Valero, J.; Perales Marin, AJ. (2017). Prediction of labor onset type: Spontaneous vs induced; role of electrohysterography?. Computer Methods and Programs in Biomedicine. 144:127-133. https://doi.org/10.1016/j.cmpb.2017.03.018S12713314

    Prediction of Labor Induction Success from the Uterine Electrohysterogram

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    [EN] Pharmacological agents are often used to induce labor. Failed inductions are associated with unnecessarily long waits and greater maternal-fetal risks, as well as higher costs. No reliable models are currently able to predict the induction outcome from common obstetric data (area under the ROC curve (AUC) between 0.6 and 0.7). The aim of this study was to design an early success-predictor system by extracting temporal, spectral, and complexity parameters from the uterine electromyogram (electrohysterogram (EHG)). Different types of feature sets were used to design and train artificial neural networks: Set_1: obstetrical features, Set_2: EHG features, and Set_3: EHG+obstetrical features. Predictor systems were built to classify three scenarios: (1) induced women who reached active phase of labor (APL) vs. women who did not achieve APL (non-APL), (2) APL and vaginal delivery vs. APL and cesarean section delivery, and (3) vaginal vs. cesarean delivery. For Scenario 3, we also proposed 2-step predictor systems consisting of the cascading predictor systems from Scenarios 1 and 2. EHG features outperformed traditional obstetrical features in all the scenarios. Little improvement was obtained by combining them (Set_3). The results show that the EHG can potentially be used to predict successful labor induction and outperforms the traditional obstetric features. Clinical use of this prediction system would help to improve maternal-fetal well-being and optimize hospital resources.This work received financial support from the Spanish Ministry of Economy and Competitiveness, the European Regional Development Fund (DPI2015-68397-R and RTI2018-094449-A-I00), Universitat Politècnica de València VLC/Campus (UPV-FE-2018-B02), Generalitat Valenciana (GV/2018/104), and Bial S.A.Benalcazar-Parra, C.; Ye Lin, Y.; Garcia-Casado, J.; Monfort-Ortiz, R.; Alberola Rubio, J.; Perales Marin, AJ.; Prats-Boluda, G. (2019). 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    Uterine contractions clustering based on surface electromyography: an input for pregnancy monitoring

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    Tese de mestrado em Bioestatística, apresentada à Universidade de Lisboa, através da Faculdade de Ciências, em 2018Inicialmente a investigação da contratilidade uterina recorria à utilização de dois métodos: o tocograma externo e o cateter de pressão intrauterino. Ambos os métodos apresentam limitações ao nível da avaliação do risco de parto prematuro e na monitorização da gravidez. O EHG (Electrohisterograma) é um método alternativo ao tocograma externo e ao cateter de pressão intrauterino. Este método pode ser aplicado de forma invasiva no músculo uterino, ou de forma não invasiva através de elétrodos colocados no abdómen. O EHG tem sido considerado uma ferramenta adequada para a monitorização da gravidez e do parto. O índice de massa corporal tem um impacto quase impercetível no EHG, sendo esta uma das principais características deste método. O EHG pode também ser utilizado para identificar as mulheres que vão entrar em trabalho de parto e ainda auxiliar na tomada de decisão médica quanto à utilização da terapia tocolítica (antagonista da oxitocina), evitando deste modo a ingestão de medicação desnecessária e os consequentes efeitos secundários. Na literatura existem apenas cinco casos publicados em que foi realizada uma separação dos principais eventos do sinal EHG: contrações, movimentos fetais, ondas Alvarez e ondas LDBF (Longue Durée Basse Fréquence). Em três das publicações a separação dos eventos foi feita manualmente e nos restantes casos algoritmos, como redes neuronais, foram aplicados ao EHG. As ondas Alvarez e as Braxton-Hicks são as mais reconhecidas. As ondas Alvarez foram descritas pela primeira vez nos anos cinquenta e as Braxton-Hicks foram descritas pela primeira vez em 1872 sendo detetadas através de palpação. As ondas Alvarez são ocasionalmente sentidas pela mulher. Estas ondas estão localizadas numa pequena área do tecido uterino sem propagação e podem levar a contrações com maior intensidade e, consequentemente, ao parto pré-termo. As Braxton-Hicks são contrações ineficientes registadas a partir da 20ª semana de gravidez que se tornam mais frequentes e intensas com o decorrer da gravidez. Estas contrações são menos localizadas que as ondas Alvarez e, durante o parto, propagam-se por todo o tecido uterino num curto período de tempo. As Braxton-Hicks estão associadas a uma diminuição do ritmo cardíaco fetal. As ondas LDBF são contrações de longa duração associadas a hipertonia uterina, quando há contração do tecido uterino sem retorno ao relaxamento muscular, o que representa um risco na gravidez. Neste trabalho foram utilizadas duas bases de dados. Na base de dados da Islândia existem 122 registos de 45 mulheres, dos quais apenas 4 correspondem a partos pré-termo. Na base de dados TPEHG (Term-Preterm EHG) existem 300 registos, dos quais 38 correspondem a partos pré-termo. Neste trabalho foram escolhidos canais bipolares, visto que estes reduzem o ruído idêntico, como o ECG (Eletrocardiograma) materno ou movimentos respiratórios. Para ambas as bases de dados os sinais originais de EHG foram processados e filtrados. Na estimação espetral foram considerados dois métodos: paramétricos e não paramétricos. O método Welch foi escolhido pois representa um bom compromisso entre ambos. Este método foi utilizado para calcular o espectro de cada evento detetado no sinal EHG. Para detetar os eventos no sinal EHG foram considerados cinco métodos baseados na energia ou amplitude. O método Wavelet foi o escolhido pois após uma inspeção visual, este era o método que delineava melhor as contrações. Na base de dados da Islândia foram identificadas 3136 contrações e na TPEHG foram encontradas 4622 contrações. O objetivo principal desta tese é obter clusters de contrações detetadas no sinal EHG. No entanto, as contrações são séries temporais não estacionárias, e a sua classificação visual é inviável a longo termo e também difícil de aplicar na prática clínica. Existem vários parâmetros que podem ser extraídos do sinal EHG, mas o espectro das contrações foi o método escolhido visto que este representa o sinal EHG e tem sempre a mesma dimensão, independentemente da duração da contração. As distâncias espetrais têm sido utilizadas com sucesso no reconhecimento áudio. Neste trabalho foi realizada uma aplicação desse método ao processamento do EHG, no qual foram realizados os ajustes necessários. Para comparar os espectros foram estudadas 8 distâncias diferentes: Itakura-Saito, COSH, Itakura, Itakura simétrica, Kullback-Leibler, Jeffrey, Rényi e Jensen-Rényi. Apenas as distâncias simétricas foram selecionadas para um estudo mais detalhado visto que estas são, segundo a literatura, as distâncias mais adequadas aquando do clustering. Após comparação das distâncias simétricas, a divergência de Jeffrey foi a selecionada para a comparação dos espectros. Nesta tese foram avaliados três métodos diferentes de clustering: o linkage, o K-means e o K-medoids. O linkage é um método hierárquico. Os clusters que resultam do agrupamento hierárquico estão organizados numa estrutura chamada dendrograma. No agrupamento hierárquico, não é necessário predeterminar o número de clusters, o que torna este um método ideal na exploração dos dados. O K-means e o K-medoids são métodos de partição, nos quais os dados são separados em k clusters decididos previamente. Os clusters são definidos de forma a otimizar a função da distância. No algoritmo K-means, os clusters baseiam-se na proximidade entre si de acordo com uma distância predeterminada. A diferença entre o K-medoids e o K-means é que o K-medoids escolhe pontos de dados como centros, chamados de medoides, enquanto K-means usa centróides. Após uma comparação dos diferentes métodos de clustering foi escolhido neste trabalho foi o average linkage, visto que este apresentava melhores resultados quer na separação dos espectros quer na silhueta. É então apresentado um método inovador no qual se utiliza todo o espectro das contrações detetadas automaticamente no EHG para o clustering não supervisionado. Esta técnica é uma contribuição para a classificação automática das diferentes contrações, especialmente aquelas mais reconhecidas na literatura: Alvarez e Braxton-Hicks. Era expectável encontrar um cluster isolado com as ondas LDBF, visto que estas representam um risco para o feto. O principal objetivo era juntar num cluster os espectros semelhantes das contrações, e relacioná-lo com o respetivo tipo de contração. Essa tarefa foi concluída através da identificação positiva de Alvarez e Braxton-Hicks. O clustering forneceu ainda algumas pistas sobre ondas Alvarez que não foram encontradas com o algoritmo de deteção de contrações, situação para a qual um método alternativo é apresentado. É sugerido que as ondas Alvarez sejam detetadas com métodos baseados na frequência, como, por exemplo, a frequência instantânea, no entanto este método não foi desenvolvido neste trabalho. Em relação às ondas LDBF, estas foram encontradas no cluster das Braxton-Hicks. É sugerido que a deteção das ondas LDBF seja baseada na sua caraterística mais distinta: a longa duração. Verificou-se que os casos pré-termo e os registos pré-parto não ficaram isolados num cluster, não se tendo encontrado uma relação entre a idade gestacional e o tipo de contração. Conclui-se que as contrações mais curtas apresentam maior amplitude do que as contrações com maior duração. Baseado em estudos anteriores sobre a eletrofisiologia do útero, supõem-se que o início do trabalho de parto pré-termo e termo esteja associado a sequências específicas de diferentes tipos de contrações, nas quais as ondas Alvares desempenham um papel importante. As contrações identificadas como Alvarez e Braxton-Hicks não são usadas como tal na prática clínica apesar de a maioria das contrações detetadas pelo tocograma serem Braxton-Hicks. O interesse pelas ondas Alvarez diminuiu rapidamente visto que estas ondas são praticamente indetetáveis pelo método de referência de deteção de contrações: o tocograma. As capacidades e a resolução do EHG levaram à renovação do estudo das contrações mais subtis, incluindo as Alvarez. Este trabalho é uma contribuição para a investigação nesta área.An innovative technique is introduced wherein where an unsupervised clustering method using as feature the whole spectrum of automatically detected contractions on the EHG (Electrohysterogram) is presented as a contribution to the automatic classification of the different uterine contractions, at least those that have been most recognized in the literature: Alvarez and Braxton-Hicks. It was expected to also be able to cluster the LDBF (Longue Durée Basse Fréquence) components, as these pose a fetal risk. The main task was to have the spectral contractions descriptions clustered and linked to the respective contraction type. That task was completed with positive identification of the Alvarez and Braxton-Hicks. The clustering process also provided clues regarding the missed Alvarez waves in the contraction detection algorithm, for which an alternative technique is suggested but not developed in this work. Regarding the LDBF they were found in the Braxton-Hicks cluster. It is suggested the LDBF´s to be detected based in their most prominent feature: the long duration. It is presented the rationale behind the selection of a cost function to be used in the spectral distance’s algorithm. Spectral distances have been successfully used in audio recognition and this works represents an application to the EHG processing, for which the necessary adjustments have to be implemented. It was found that no single cluster pointed to the preterm cases, or indeed to the pre-labor subject recordings. It is hypothesized, based on previous studies in uterine electrophysiology, that the initiation of pre-term or term labor should be associated with triggering contraction sequences of different types, where the Alvarez waves play a major role. Alvarez and Braxton-Hicks, labeled as such, are not typically used in the clinical environment despite most of the Tocogram detected contractions being the latter. Alvarez waves are not usually detectable by the Tocogram. Alvarez were firstly detected invasively in the early fifties, and Braxton-Hicks in 1872 using routine palpation techniques. The interest in Alvarez components declined rapidly since being practically undetectable by the de facto reference in the contraction detection: the Tocogram. The EHG capabilities and resolution made it possible to revive the research on the most subtle uterine contractions, Alvarez included and this work is a contribution in this research area

    Electrohysterography in the diagnosis of preterm birth: a review

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    This is an author-created, un-copyedited versíon of an article published in Physiological Measurement. IOP Publishing Ltd is not responsíble for any errors or omissíons in this versíon of the manuscript or any versíon derived from it. The Versíon of Record is available online at http://doi.org/10.1088/1361-6579/aaad56.[EN] Preterm birth (PTB) is one of the most common and serious complications in pregnancy. About 15 million preterm neonates are born every year, with ratios of 10-15% of total births. In industrialized countries, preterm delivery is responsible for 70% of mortality and 75% of morbidity in the neonatal period. Diagnostic means for its timely risk assessment are lacking and the underlying physiological mechanisms are unclear. Surface recording of the uterine myoelectrical activity (electrohysterogram, EHG) has emerged as a better uterine dynamics monitoring technique than traditional surface pressure recordings and provides information on the condition of uterine muscle in different obstetrical scenarios with emphasis on predicting preterm deliveries. Objective: A comprehensive review of the literature was performed on studies related to the use of the electrohysterogram in the PTB context. Approach: This review presents and discusses the results according to the different types of parameter (temporal and spectral, non-linear and bivariate) used for EHG characterization. Main results: Electrohysterogram analysis reveals that the uterine electrophysiological changes that precede spontaneous preterm labor are associated with contractions of more intensity, higher frequency content, faster and more organized propagated activity and stronger coupling of different uterine areas. Temporal, spectral, non-linear and bivariate EHG analyses therefore provide useful and complementary information. Classificatory techniques of different types and varying complexity have been developed to diagnose PTB. The information derived from these different types of EHG parameters, either individually or in combination, is able to provide more accurate predictions of PTB than current clinical methods. However, in order to extend EHG to clinical applications, the recording set-up should be simplified, be less intrusive and more robust-and signal analysis should be automated without requiring much supervision and yield physiologically interpretable results. Significance: This review provides a general background to PTB and describes how EHG can be used to better understand its underlying physiological mechanisms and improve its prediction. The findings will help future research workers to decide the most appropriate EHG features to be used in their analyses and facilitate future clinical EHG applications in order to improve PTB prediction.This work was supported by the Spanish Ministry of Economy and Competitiveness and the European Regional Development Fund under grant DPI2015-68397-R.Garcia-Casado, J.; Ye Lin, Y.; Prats-Boluda, G.; Mas-Cabo, J.; Alberola Rubio, J.; Perales Marin, AJ. (2018). Electrohysterography in the diagnosis of preterm birth: a review. Physiological Measurement. 39(2). https://doi.org/10.1088/1361-6579/aaad56S39
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