MRI-based dynamic tracking of an untethered ferromagnetic microcapsule navigating in liquid

Dahmen, Christian; Belharet, Karim; Folio, David; Ferreira, Antoine; Fatikow, Sergej

doi:10.1080/15599612.2016.1166305

Cited by 24 publications

(47 citation statements)

References 29 publications

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“…The most correlated slice gives the out‐of‐plane distance of the robot to the slice of the image. Later, Dahmen et al demonstrated that the template stack matching method can be performed faster by k ‐space reduction …”

Section: Localization and Tracking With Mrimentioning

confidence: 99%

“…Tracking and localization data acquired by MRI systems can be around 100 Hz when simultaneous imaging and actuation sequences are used; however, it lacks the true position information since these frequencies can be achieved when only single 1D line scans are used. Typically, the feedback rates are at around 10–30 Hz for sequential actuation and tracking sequences . Unlike standard robotic approaches, where high‐speed cameras or high‐performance computers provide very accurate estimation at much higher frequencies, the limited feedback data could be one of the challenges for medical applications under highly dynamic environments.…”

Section: Future Outlook and Conclusionmentioning

confidence: 99%

“…Answering when and which one of this information is required is crucial for the appropriate choice of imaging strategy. Currently, most studies are using standard imaging procedures such as FLASH for feedback and localization . However, for this innovative use of MRI devices, the typical imaging sequences that are optimized for diagnostic imaging may not be the best choice.…”

Section: Future Outlook and Conclusionmentioning

confidence: 99%

“…Later, Dahmen et al demonstrated that the template stack matching method can be performed faster by k-space reduction. [32]…”

Section: Mr Image-based Localization and Tracking Of Mri-driven Robotsmentioning

confidence: 99%

“…Typically, the feedback rates are at around 10-30 Hz for sequential actuation and tracking sequences. [9,13,20,32] Unlike standard robotic approaches, where high-speed cameras or high-performance computers provide very accurate estimation at much higher frequencies, the limited feedback data could be one of the challenges for medical applications under highly dynamic environments. Combining MRI devices with complementary imaging modalities, such as PET and ultrasound, could be a potential solution to the low feedback rate of MRI systems.…”

Section: Future Outlook and Conclusionmentioning

confidence: 99%

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Magnetic Resonance Imaging System–Driven Medical Robotics

Erin

Boyvat

Tiryaki

et al. 2020

Advanced Intelligent Systems

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Magnetic resonance imaging (MRI) system–driven medical robotics is an emerging field that aims to use clinical MRI systems not only for medical imaging but also for actuation, localization, and control of medical robots. Submillimeter scale resolution of MR images for soft tissues combined with the electromagnetic gradient coil–based magnetic actuation available inside MR scanners can enable theranostic applications of medical robots for precise image‐guided minimally invasive interventions. MRI‐driven robotics typically does not introduce new MRI instrumentation for actuation but instead focuses on converting already available instrumentation for robotic purposes. To use the advantages of this technology, various medical devices such as untethered mobile magnetic robots and tethered active catheters have been designed to be powered magnetically inside MRI systems. Herein, the state‐of‐the‐art progress, challenges, and future directions of MRI‐driven medical robotic systems are reviewed.

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Section: Localization and Tracking With Mrimentioning

confidence: 99%

Section: Future Outlook and Conclusionmentioning

confidence: 99%

Section: Future Outlook and Conclusionmentioning

confidence: 99%

“…Later, Dahmen et al demonstrated that the template stack matching method can be performed faster by k-space reduction. [32]…”

Section: Mr Image-based Localization and Tracking Of Mri-driven Robotsmentioning

confidence: 99%

Section: Future Outlook and Conclusionmentioning

confidence: 99%

See 3 more Smart Citations

Magnetic Resonance Imaging System–Driven Medical Robotics

Erin

Boyvat

Tiryaki

et al. 2020

Advanced Intelligent Systems

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Intelligent Micro‐/Nanorobots for Cancer Theragnostic

Wang

Dong

et al. 2022

Advanced Materials

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Cancer is one of the most intractable diseases owing to its high mortality rate and lack of effective diagnostic and treatment tools. Advancements in micro‐/nanorobot (MNR)‐assisted sensing, imaging, and therapeutics offer unprecedented opportunities to develop MNR‐based cancer theragnostic platforms. Unlike ordinary nanoparticles, which exhibit Brownian motion in biofluids, MNRs overcome viscous resistance in an ultralow Reynolds number (Re << 1) environment by effective self‐propulsion. This unique locomotion property has motivated the advanced design and functionalization of MNRs as a basis for next‐generation cancer‐therapy platforms, which offer the potential for precise distribution and improved permeation of therapeutic agents. Enhanced barrier penetration, imaging‐guided operation, and biosensing are additionally studied to enable the promising cancer‐related applications of MNRs. Herein, the recent advances in MNR‐based cancer therapy are comprehensively addresses, including actuation engines, diagnostics, medical imaging, and targeted drug delivery; promising research opportunities that can have a profound impact on cancer therapy over the next decade is highlighted.

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Radio Frequency Sensing‐Based In Situ Temperature Measurements during Magnetic Resonance Imaging Interventional Procedures

Bilgin

Tiryaki

Lazović

et al. 2022

Adv Materials Technologies

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attention in the medical robotics as a potential alternative to traditional 2D fluoroscopic imaging methods with the MRI's ionizing-radiation-free nature and 3D high-resolution soft tissue imaging capabilities. [1][2][3][4][5][6] By developing different MRI-based medical robot or device designs, such as MRI-compatible guide wires, [7,8] soft pneumatic actuators, [9,10] piezo actuators, [11,12] focused ultrasound (FUS) systems, [5,13,14] active catheters, [15,16] needle insertion systems, [4,17,18] and magnetic microrobots [19][20][21][22][23][24][25] and millirobots, [26][27][28][29] researchers have demonstrated promising interventional procedures, such as laser ablation, [30][31][32][33][34] local hyperthermia, [14,35,36] and FUS ablation. [13,34,37] The usage of MRI is mainly limited to the position tracking and the steering control of such medical robots or devices with fiducial markers based on radiofrequency (RF) markers, [3,[38][39][40][41][42] magnetic markers, [43][44][45] and contrast agents. [46][47][48] One of the key challenges during many interventional MRI procedures is the risks associated with overheating, which threatens the safety of the patients. Numerous reports have been published concerning the heating of metallic components during the MR imaging; [49][50][51][52][53][54][55][56][57][58][59][60][61][62][63][64][65] therefore, a continuous in situ temperature monitoring is required for safe interventional MRI applications. MRI thermometry has been developed as an in situ temperature monitoring method. [66][67][68][69] Researchers have used MRI thermometry-based temperature feedback to control FUS hyperthermia operations [35,36,70] or to evaluate MRI-guided laser ablation therapies [6,31,71] and MRIguided active catheters. [72,73] While MRI thermometry methods can provide accurate in situ temperature mapping in 3D, they decrease the overall MRI-based visual feedback rate by adding an extra sequence, hindering the real-time MRI feedback. In a different approach, some researchers have proposed RFbased telemetric devices for measuring the in situ temperature remotely. [74][75][76][77][78] However, such methods have included sophisticated circuitries and metallic components that may distort MR images. [79][80][81] Therefore, a safe method for in situ temperature monitoring without decreasing the MRI feedback rate is highly desirable inside the interventional MR scanners.Previously, various RF marker designs have been reported; however, their main focus has been on device 3D tracking inside MRI. [3,[38][39][40][41][42] Recent studies explored new designs for ensuring functionality independent of the marker orientation. [82][83][84] Beyond tracking, a recent study used an RF marker design Magnetic resonance imaging (MRI)-tuned radio-frequency (RF) sensors are used as a radiation-free alternative for tracking minimally invasive medical tool positions. However, in situ temperature sensing capabilities of the MRI-tuned RF sensors have not been thoroughly investigated yet. A self-resonating RF sensor c...

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MRI-based dynamic tracking of an untethered ferromagnetic microcapsule navigating in liquid

Cited by 24 publications

References 29 publications

Magnetic Resonance Imaging System–Driven Medical Robotics

Magnetic Resonance Imaging System–Driven Medical Robotics

Intelligent Micro‐/Nanorobots for Cancer Theragnostic

Radio Frequency Sensing‐Based In Situ Temperature Measurements during Magnetic Resonance Imaging Interventional Procedures

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