Dual-Continuum Design Approach for Intuitive and Low-Cost Upper Gastrointestinal Endoscopy

Garbin, Nicolo; Wang, Long; Chandler, James H.; Obstein, Keith L.; Simaan, Nabil; Valdastri, Pietro

doi:10.1109/tbme.2018.2881717

Cited by 31 publications

(27 citation statements)

References 48 publications

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“…The Bellowscope is another promising device not included in the table since it is not strictly a robotic platform but is a low-cost disposable endoscope. Its working principle is based on pistons and bellow actuators which are controlled by multi-DOF handheld controller ( Garbin et al, 2018a ; Garbin et al, 2018b ; Garbin et al, 2019 ; Chandler et al, 2020 ).…”

Section: Robotic Flexible Gi Endoscopymentioning

confidence: 99%

Guidelines for Robotic Flexible Endoscopy at the Time of COVID-19

et al. 2021

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Flexible endoscopy involves the insertion of a long narrow flexible tube into the body for diagnostic and therapeutic procedures. In the gastrointestinal (GI) tract, flexible endoscopy plays a major role in cancer screening, surveillance, and treatment programs. As a result of gas insufflation during the procedure, both upper and lower GI endoscopy procedures have been classified as aerosol generating by the guidelines issued by the respective societies during the COVID-19 pandemic—although no quantifiable data on aerosol generation currently exists. Due to the risk of COVID-19 transmission to healthcare workers, most societies halted non-emergency and diagnostic procedures during the lockdown. The long-term implications of stoppage in cancer diagnoses and treatment is predicted to lead to a large increase in preventable deaths. Robotics may play a major role in this field by allowing healthcare operators to control the flexible endoscope from a safe distance and pave a path for protecting healthcare workers through minimizing the risk of virus transmission without reducing diagnostic and therapeutic capacities. This review focuses on the needs and challenges associated with the design of robotic flexible endoscopes for use during a pandemic. The authors propose that a few minor changes to existing platforms or considerations for platforms in development could lead to significant benefits for use during infection control scenarios.

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Section: Robotic Flexible Gi Endoscopymentioning

confidence: 99%

Guidelines for Robotic Flexible Endoscopy at the Time of COVID-19

et al. 2021

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“…A number of approaches to low‐cost endoscope design have been proposed; including cable driven, 9 tethered capsules 10,11 and pneumatically driven 12,13 devices. In addition to these, water‐jet driven endoscopes represent a prevalent approach, with the advantage of low‐cost and disposable features and water‐jet based orientation control 14–17 .…”

Section: Introductionmentioning

confidence: 99%

A dual‐bending endoscope with shape‐lockable hydraulic actuation and water‐jet propulsion for gastrointestinal tract screening

Liu

Yin

Chandler

et al. 2020

Robotics Computer Surgery

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Background Traditional flexible endoscopes are sophisticated medical devices that require frequent and expensive maintenance. Therefore, their implementation within low‐income and rural regions is challenging due to their high cost, complex sterilization process and poor portability. Aims This paper aims to develop an endoscopic platform that is low‐cost, disposable and portable, with the primary goal of reducing gastric cancer‐related mortality among low‐ and middle‐income communities through wider access to regular screening programs. Materials and Methods The endoscope employs a custom microvalve to switch between hydraulic actuation of a spatial bending fluidic actuator and water‐jet actuation. Three alloy wires with buckle attachments are connected to a pneumatic balloon which facilitates reversible shape‐locking of the actuator, and thus supports stable scanning by water‐jet actuation. Distal tip of the device has an internal charge‐coupled device camera for inspection. Results Experiments demonstrated a 58% increase in the workspace after introduction of the water‐jet and more than three times the load‐locking ability variation. Phantom experiment was also conducted for performance comparison with a traditional endoscope. Conclusion By controlling the pressure of supplied water and the inflation of locking balloon, the endoscope achieves a satisfactory workspace and a remarkable shape‐locking ability, demonstrating its potential clinical value in improving the prospects for upper gastrointestinal tract disease screening, especially gastric cancer.

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“…Unfortunately, this adds significant procedural complexity that is amplified as the device scale is reduced. Generally, multi-chamber actuators employ three chambers distributed with their centers 120° apart (Suzumori et al, 1991a , b ; Benjamin et al, 2012 ; Cianchetti et al, 2013 ; Martinez et al, 2013 ; Yahya et al, 2014 ; Sun et al, 2016 ; Yan et al, 2016 ; Drotman et al, 2017 ; Nguyen et al, 2017 ; Robertson and Paik, 2017 ) and may be fabricated in a number of ways; for example: (i) molding with constant axial cross-sectional cores (Suzumori et al, 1997 ; Martinez et al, 2013 ; Yahya et al, 2014 ; Fu et al, 2020 ); (ii) assembly of pre-formed individual chambers (Cianchetti et al, 2013 ; Matteo et al, 2014 ; Ranzani et al, 2015 ; Nguyen et al, 2017 ; Garbin et al, 2018 , 2019 ; Peng et al, 2019 ); and (iii) 3D-printing of integrated designs (Peele et al, 2015 ; Wallin et al, 2018 ; Yirmibesoglu et al, 2018 ; Drotman et al, 2019 ). Although promising, these methods carry trade-offs between achievable internal chamber geometry, complexity, resilience of assembly, material selection, and practicable actuator scale and feature resolution (Schmitt et al, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

“…Specific benefits associated with PHAs are (1) integrated multi-chamber designs scalable to small size (<1 cm diameter for three-chamber design); (2) the potential for single-step, single-material molding, reducing reliance on sealing and layer bonding, and avoiding the need for assembly; (3) simple “unscrewing” of mold cores to reduce the risk of damage to the internal features of the actuator during demolding; (4) design flexibility allowing adjustment to PHA geometry and scale for application specific optimization; and (5) 3D motion description through kinematic models based on the constant-curvature assumption. We envisage PHAs having utility in medical robotics for example in minimally invasive surgery (Abidi et al, 2018 ) or endoscopy (Garbin et al, 2019 ); or providing a generic actuator platform for soft robotic applications.…”

Section: Introductionmentioning

confidence: 99%

Parallel Helix Actuators for Soft Robotic Applications

et al. 2020

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Fabrication of soft pneumatic bending actuators typically involves multiple steps to accommodate the formation of complex internal geometry and the alignment and bonding between soft and inextensible materials. The complexity of these processes intensifies when applied to multi-chamber and small-scale (∼10 mm diameter) designs, resulting in poor repeatability. Designs regularly rely on combining multiple prefabricated single chamber actuators or are limited to simple (fixed cross-section) internal chamber geometry, which can result in excessive ballooning and reduced bending efficiency, compelling the addition of constraining materials. In this work, we address existing limitations by presenting a single material molding technique that uses parallel cores with helical features. We demonstrate that through specific orientation and alignment of these internal structures, small diameter actuators may be fabricated with complex internal geometry in a single material-without-additional design-critical steps. The helix design produces wall profiles that restrict radial expansion while allowing compact designs through chamber interlocking, and simplified demolding. We present and evaluate three-chambered designs with varied helical features, demonstrating appreciable bending angles (>180 •), three-dimensional workspace coverage, and three-times bodyweight carrying capability. Through application and validation of the constant curvature assumption, forward kinematic models are presented for the actuator and calibrated to account for chamber-specific bending characteristics, resulting in a mean model tip error of 4.1 mm. This simple and inexpensive fabrication technique has potential to be scaled in size and chamber numbers, allowing for application-specific designs for soft, high-mobility actuators especially for surgical, or locomotion applications.

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Dual-Continuum Design Approach for Intuitive and Low-Cost Upper Gastrointestinal Endoscopy

Cited by 31 publications

References 48 publications

Guidelines for Robotic Flexible Endoscopy at the Time of COVID-19

Guidelines for Robotic Flexible Endoscopy at the Time of COVID-19

A dual‐bending endoscope with shape‐lockable hydraulic actuation and water‐jet propulsion for gastrointestinal tract screening

Parallel Helix Actuators for Soft Robotic Applications

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