Intelligent robotic sonographer: Mutual information-based disentangled reward learning from few demonstrations

Jiang, Zhongliang; Bi, Yuan; Zhou, Mingchuan; Hu, Ying; Burke, Michael; Navab, Nassir

doi:10.1177/02783649231223547

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2024

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Cited by 7 publications

References 66 publications

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Industry and artificial intelligence: industrial robot localization based on improved monte carlo algorithm

Zhang,

Zhang

2024

Int J Interact Des Manuf

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Industry and artificial intelligence: industrial robot localization based on improved monte carlo algorithm

Zhang,

Zhang

2024

Int J Interact Des Manuf

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A Method For Mimicking Tumour Tissue In Brain Ex-Vivo Ultrasound For Research Application And Clinical Training

Weld,

Dixon,

Anichini

et al. 2024

Preprint

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Introduction: Intraoperative ultrasound is becoming a common tool in neurosurgery. However, effective simulation methods are limited. Current, commercial, and homemade phantoms lack replication of anatomical correctness and texture complexity of brain and tumour tissue in ultrasound images. Materials and Methods: We utilise ex-vivo brain tissue, as opposed to synthetic materials, to achieve realistic echogenic complexity and anatomical correctness. Agar, at 10-20\% concentrate, is injected into the brain tissue to simulate the tumour mass. A commercially available phantom was purchased for benchmarking. Results: Qualitative analysis is performed by experienced professionals, measuring the impact of the addition of agar and comparing it to the commercial phantom. Overall, the use of ex vivo tissue was deemed more accurate and representative, compared to the synthetic materials-based phantom, as it provided good visualisation of real brain anatomy and good contrast within tissue. The agar tumour correctly produced a region of higher echogenicity with slight diffusion along the margin and expected interaction with the neighbouring anatomy. Discussion: Using human samples for training is limited due to high logistical and ethical challenges. Sparsity of online neurosurgical US data further compounds this. The proposed method successfully produced a better simulation of tumours in brain tissue than the phantom which suffers from surface texture dissimilarity, ultrasound echogenic homogeneity, and lack of anatomical correctness. Conclusion: The proposed method for creating tumour-mimicking tissue in brain tissue is inexpensive, accurate, and simple. Beneficial for both the trainee clinician and the researcher. A total of 576 annotated images are made publicly available upon request. Word count ≈ 3400.

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Colon Lumen Center Detection Enables Autonomous Navigation of an Electromagnetically Actuated Soft-Tethered Colonoscope

Li,

Ng,

Sun

et al. 2024

IEEE Trans. Instrum. Meas.

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Intelligent robotic sonographer: Mutual information-based disentangled reward learning from few demonstrations

Cited by 7 publications

References 66 publications

Industry and artificial intelligence: industrial robot localization based on improved monte carlo algorithm

Industry and artificial intelligence: industrial robot localization based on improved monte carlo algorithm

A Method For Mimicking Tumour Tissue In Brain Ex-Vivo Ultrasound For Research Application And Clinical Training

Colon Lumen Center Detection Enables Autonomous Navigation of an Electromagnetically Actuated Soft-Tethered Colonoscope

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