Advanced Soft Robotic System for In Situ 3D Bioprinting and Endoscopic Surgery

Thai, Mai Thanh; Phan, Phuoc Thien; Tran, Hien A.; Nguyễn, Chí Công; Hoang, Trung Thien; Davies, James; Rnjak‐Kovacina, Jelena; Phan, Hoang‐Phuong; Lovell, Nigel H.; Nho, Thanh

doi:10.1002/advs.202205656

Cited by 32 publications

(17 citation statements)

References 68 publications

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“…Using a neural network (NN) model, the soft 3D sensor can precisely detect interaction forces ( F = ( F x , F y , F z )) based on the change of the hydraulic pressures and the 3‐DoF fingertip cutaneous immediately reproduces these sensed 3D force with a mapping to the index fingertip through a tactor. In addition, each FBA is controlled by a motor housing [ 38 ] based on the signal change in three SFSs in the index finger, the middle finger, and the ring finger resulting in the position and direction change of the slave robotic arm (Figure 1a). A typical operating process of the proposed system is shown in Video S1, (Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…Similarly, a linear translational motion is accomplished along the long axis when all three bellows are concurrently subjected to a combination of three hydraulic pressure values as shown. [ 38,42 ] In most existing surgical robots, when external translation motion is necessary, the proposed robot structure implies that the soft robotic arm can expand its length without moving the flexible body. When the bellows are activated, the soft robotic arm can move in a variety of motions, as shown in Figure 4b and Video S4 (Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

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Soft Wearable Haptic Display and Flexible 3D Force Sensor for Teleoperated Surgical Systems

Thai,

Davies,

Nguyen

et al. 2023

Advanced Sensor Research

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Haptic (touch) is important for effective interaction with the surroundings. In teleoperated surgical systems, its absence leads to reduced perception, making delicate tasks difficult and resulting in unexpected damage to surrounding tissues. To enhance safety, a force‐feedback system and haptic device are needed. However, existing haptic prototypes are associated with rigid, bulky, and heavy components, making effective communication with the skin problematic. This paper presents a teleoperated endoscopic surgical system with an integrated 3D force sensor and real‐time haptic feedback. A surgical robotic arm is remotely controlled by a soft haptic glove incorporated 3‐axis cutaneous device and a finger kinesthetic module. The 3D force sensor is constructed from hydraulic filament soft sensors that can induce pressure change under strain. To enable precise motion, the haptic glove is operated by a feedforward controller and a master‐slave architecture. Experiments with human subjects (n = 15) show that cutaneous and kinesthetic feedback significantly improves the user's performance (9.4 out of 10) compared to no haptic feedback (2.27 out of 10). Finally, subjects rank the new system as highly wearable, comfortable, and effective, which is expected to bridge a gap in the surgical field and support the future development of advanced teleoperated systems.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Soft Wearable Haptic Display and Flexible 3D Force Sensor for Teleoperated Surgical Systems

Thai,

Davies,

Nguyen

et al. 2023

Advanced Sensor Research

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“…However, further optimisation of the system is needed regarding a more versatile magnetic field and the miniaturization of the system body [143,151]. Additionally, Thai et al [144] have demonstrated a miniaturized high DoF extrusion-based soft robotic arm printhead fixed onto a flexible snake-like structure (figure 6(b)). This system enables bioprinting through MIS or using natural orifices to reach confined anatomical locations.…”

Section: Minimally Invasive and Non-invasive Bioprintingmentioning

confidence: 99%

“…The aim should be to maintain the minimally invasive approach to surgery and ensure stable printing through arthroscopy portals, even though additional portals could be considered. Therefore, the development of soft snakelike systems and miniaturization or combination of bioprinting with surgical tools to enable precise minimally invasive manipulation within a complex or small area of cartilage tissue, although technically challenging and in the early stages of technological development, is highly desirable [24,143,144,[195][196][197][198][199][200][201]. Alternatively, and a more long-term prospect, the design and fabrication of small untethered soft-bodied robots for clinical use are appealing for MIS and cartilage repair [153,154,198,202].…”

Section: Integrating In Situ Bioprinting and Surgerymentioning

confidence: 99%

Robotic in situ bioprinting for cartilage tissue engineering

Wang

Pereira

Peach

et al. 2023

Int. J. Extrem. Manuf.

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Articular cartilage damage caused by trauma or degenerative pathologies such as osteoarthritis can result in significant pain, mobility issues, and disability. Current surgical treatments have a limited capacity for efficacious cartilage repair, and long-term patient outcomes are not satisfying. Three-dimensional (3D) bioprinting has been used to fabricate biochemical and biophysical environments that aim to recapitulate the native microenvironment and promote tissue regeneration. However, conventional in vitro bioprinting has limitations due to the challenges associated with the fabrication and implantation of printed constructs and integration with the native cartilage tissue. In situ bioprinting is a novel strategy to directly deliver bioinks to the desired anatomical site and has the potential to overcome major shortcomings associated with conventional bioprinting. In this review, we focus on the new frontier of robotic-assisted in situ bioprinting surgical systems for cartilage regeneration. We outline existing clinical approaches and the utilisation of robotic-assisted surgical systems. Handheld and robotic-assisted in situ bioprinting techniques including minimally invasive and non-invasive approaches are defined and presented. Finally, we discuss the challenges and potential future perspectives of in situ bioprinting for cartilage applications.

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“…The AMF is responsive, high speed (up to 20 Hz as reported in our previous study), and durable as well as has high contraction force and high energy efficiency. [65][66][67][68][69][70] In particular, it has a high elongation, meaning that the RCCD can be expanded to adapt to different heart sizes.…”

Section: Design and Fabricationmentioning

confidence: 99%

Robotic Cardiac Compression Device Using Artificial Muscle Filaments for the Treatment of Heart Failure

Phan,

Davies,

Hoang

et al. 2023

Advanced Intelligent Systems

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Heart failure occurs when the heart cannot pump adequate blood to the body, which afflicts over 60 million people worldwide. Its treatment options include physiotherapy, medication, mechanical heart support, heart surgery, or heart transplantation. Ventricular assist devices have direct blood contact while passive ventricular constraint devices have only modest therapeutic efficacy. Current direct cardiac compression devices are either bulky, require noisy driving pneumatic sources, or are unable to mimic the natural heart motion. This study introduces a robotic cardiac compression device made of soft artificial muscle filaments that can simultaneously produce radial, axial, and torsional movements, potentially augmenting the pumping function of a failing heart. An empirical model is developed to describe the device motion and an artificial pericardium is employed to enable uniform force distribution to the heart and real‐time pressure sensing. The proposed device could deliver a stroke volume of 70 mL at 15 beats per minute, or a cardiac output of 1.05 L min−1, and achieve a peak instantaneous flow rate of 2.8 L min−1 and an output pressure of 50 mmHg. The new devices are highly customizable and experimentally validated with fresh porcine heart. They are expected to inspire future development of nonblood‐contacting cardiac assist devices.

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Advanced Soft Robotic System for In Situ 3D Bioprinting and Endoscopic Surgery

Cited by 32 publications

References 68 publications

Soft Wearable Haptic Display and Flexible 3D Force Sensor for Teleoperated Surgical Systems

Soft Wearable Haptic Display and Flexible 3D Force Sensor for Teleoperated Surgical Systems

Robotic in situ bioprinting for cartilage tissue engineering

Robotic Cardiac Compression Device Using Artificial Muscle Filaments for the Treatment of Heart Failure

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