Your search keyword '"Tolsgaard, Martin Grønnebæk"' showing total 3 results

1. Generalisability of fetal ultrasound deep learning models to low-resource imaging settings in five African countries.

Author

Sendra-Balcells, Carla, Campello, Víctor M., Torrents-Barrena, Jordina, Ahmed, Yahya Ali, Elattar, Mustafa, Ohene-Botwe, Benard, Nyangulu, Pempho, Stones, William, Ammar, Mohammed, Benamer, Lamya Nawal, Kisembo, Harriet Nalubega, Sereke, Senai Goitom, Wanyonyi, Sikolia Z., Temmerman, Marleen, Gratacós, Eduard, Bonet, Elisenda, Eixarch, Elisenda, Mikolaj, Kamil, Tolsgaard, Martin Grønnebæk, and Lekadir, Karim

Subjects

DEEP learning, FETAL ultrasonic imaging, ARTIFICIAL intelligence, COMPUTER-assisted image analysis (Medicine), HIGH-income countries, FETAL abnormalities

Abstract

Most artificial intelligence (AI) research and innovations have concentrated in high-income countries, where imaging data, IT infrastructures and clinical expertise are plentiful. However, slower progress has been made in limited-resource environments where medical imaging is needed. For example, in Sub-Saharan Africa, the rate of perinatal mortality is very high due to limited access to antenatal screening. In these countries, AI models could be implemented to help clinicians acquire fetal ultrasound planes for the diagnosis of fetal abnormalities. So far, deep learning models have been proposed to identify standard fetal planes, but there is no evidence of their ability to generalise in centres with low resources, i.e. with limited access to high-end ultrasound equipment and ultrasound data. This work investigates for the first time different strategies to reduce the domain-shift effect arising from a fetal plane classification model trained on one clinical centre with high-resource settings and transferred to a new centre with low-resource settings. To that end, a classifier trained with 1792 patients from Spain is first evaluated on a new centre in Denmark in optimal conditions with 1008 patients and is later optimised to reach the same performance in five African centres (Egypt, Algeria, Uganda, Ghana and Malawi) with 25 patients each. The results show that a transfer learning approach for domain adaptation can be a solution to integrate small-size African samples with existing large-scale databases in developed countries. In particular, the model can be re-aligned and optimised to boost the performance on African populations by increasing the recall to 0.92 ± 0.04 and at the same time maintaining a high precision across centres. This framework shows promise for building new AI models generalisable across clinical centres with limited data acquired in challenging and heterogeneous conditions and calls for further research to develop new solutions for the usability of AI in countries with fewer resources and, consequently, in higher need of clinical support. [ABSTRACT FROM AUTHOR]

Published

2023

2. Multi-centre deep learning for placenta segmentation in obstetric ultrasound with multi-observer and cross-country generalization.

Author

Andreasen, Lisbeth Anita, Feragen, Aasa, Christensen, Anders Nymark, Thybo, Jonathan Kistrup, Svendsen, Morten Bo S., Zepf, Kilian, Lekadir, Karim, and Tolsgaard, Martin Grønnebæk

Subjects

DEEP learning, FETAL ultrasonic imaging, PLACENTA, PLACENTA praevia, CONVOLUTIONAL neural networks, ULTRASONIC imaging, COMPUTER-assisted image analysis (Medicine)

Abstract

The placenta is crucial to fetal well-being and it plays a significant role in the pathogenesis of hypertensive pregnancy disorders. Moreover, a timely diagnosis of placenta previa may save lives. Ultrasound is the primary imaging modality in pregnancy, but high-quality imaging depends on the access to equipment and staff, which is not possible in all settings. Convolutional neural networks may help standardize the acquisition of images for fetal diagnostics. Our aim was to develop a deep learning based model for classification and segmentation of the placenta in ultrasound images. We trained a model based on manual annotations of 7,500 ultrasound images to identify and segment the placenta. The model's performance was compared to annotations made by 25 clinicians (experts, trainees, midwives). The overall image classification accuracy was 81%. The average intersection over union score (IoU) reached 0.78. The model's accuracy was lower than experts' and trainees', but it outperformed all clinicians at delineating the placenta, IoU = 0.75 vs 0.69, 0.66, 0.59. The model was cross validated on 100 2nd trimester images from Barcelona, yielding an accuracy of 76%, IoU 0.68. In conclusion, we developed a model for automatic classification and segmentation of the placenta with consistent performance across different patient populations. It may be used for automated detection of placenta previa and enable future deep learning research in placental dysfunction. [ABSTRACT FROM AUTHOR]

Published

2023

3. Author Correction: Generalisability of fetal ultrasound deep learning models to low-resource imaging settings in five African countries.

Author

Sendra-Balcells, Carla, Campello, Víctor M., Torrents-Barrena, Jordina, Ahmed, Yahya Ali, Elattar, Mustafa, Ohene-Botwe, Benard, Nyangulu, Pempho, Stones, William, Ammar, Mohammed, Benamer, Lamya Nawal, Kisembo, Harriet Nalubega, Sereke, Senai Goitom, Wanyonyi, Sikolia Z., Temmerman, Marleen, Gratacós, Eduard, Bonet, Elisenda, Eixarch, Elisenda, Mikolaj, Kamil, Tolsgaard, Martin Grønnebæk, and Lekadir, Karim

Subjects

DEEP learning, FETAL ultrasonic imaging

Abstract

Additionally, the research leading to these results has received funding from Cerebra Foundation for the Brain Injured Child (Carmarthen, Wales, UK)." now reads: "This work received funding from the European Union's 2020 research and innovation programme under Grant Agreement No. 825903 (euCanSHare project), as well as from the Spanish Ministry of Science, Innovation and Universities under grant agreement RTI2018-099898-B-I00. This research was partly funded by a grant from the European Research Council (ERC) under the European Union's Horizon Europe research and innovation programme (AIMIX project - grant agreement No. 101044779)." "This work received funding from the European Union's 2020 research and innovation programme under Grant Agreement No. 825903 (euCanSHare project), as well as from the Spanish Ministry of Science, Innovation and Universities under grant agreement RTI2018-099898-B-I00. [Extracted from the article]

Published

2023