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1. Modulating Wrist-Hand Kinematics in Motorized-Assisted Grasping With C5-6 Spinal Cord Injury

   https://doi.org/10.1109/TMRB.2023.3328639  

   Chang, Erin Y; McPherson, Andrew IW; Adolf, Ryan C; Gloumakov, Yuri; Stuart, Hannah S (October 2023, IEEE Transactions on Medical Robotics and Bionics)

   Loss of hand function severely impacts the independence of people with spinal cord injuries (SCI) between C5 and C7. To achieve limited grasps or strengthen grip around small objects, these individuals commonly employ a compensatory technique to passively induce finger flexion by extending their wrist. Passive body-powered devices using wrist-driven actuation have been developed to assist this function, in addition to advancements in active robotic devices aimed at finger articulation for dexterous manipulation. Nevertheless, neither passive nor active devices see wide adoption and retention in the long-term. Here we present an unconventional system for combining aspects of both passive and active actuation and show that actively modulating the relationship between passive wrist and finger movement can impact both performance and kinematic metrics of upper body compensation. This study comprises six unique case studies of individuals with C5-6 SCI because morphology and response can vary widely across this population. While only some individuals’ performance improved with the shared system over passive-only operation, all six participants stated that they preferred the shared system, regarding added motorization with a sense of trust and embodiment. This outcome motivates the ongoing study of how motors can alter body kinematics to augment body-power without replacing it. 

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2. Stress Detection via Sensor Translation

   https://doi.org/10.1109/DCOSS49796.2020.00017  

   Samyoun, S.; Mondol, A; Stankovic, J. (June 2020, International Conference on Distributed Computing in Sensor Systems and workshops)

   Stress increases the risk of several mental and physical health problems like anxiety, hypertension, and cardiovascular diseases. Better guidance and interventions towards mitigating the impact of stress can be provided if stress can be monitored continuously. The recent proliferation of wearable devices and their capability in measuring several physiological signals related to stress have created the opportunity to measure stress continuously in the wild. Wearable devices used to measure physiological signals are mostly placed on the wrist and the chest. Though currently chest sensors, with/without wrist sensors, provide better results in detecting stress than using wrist sensors only, chest devices are not as convenient and prevalent as wrist devices, particularly in the free-living context. In this paper, we present a solution to detect stress using wrist sensors that emulate the gold standard chest sensors. Data from wrist sensors are translated into the data from chest sensors, and the translated data is used for stress detection without requiring the users to wear any device on the chest. We evaluated our solution using a public dataset, and results show that our solution detects stress with accuracy comparable to the gold standard chest devices which are impractical for daily use 

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3. Design of Wearable Lower Leg Orthotic Based on Six-Bar Linkage

   https://doi.org/10.1115/DETC2017-67837  

   Ghosh, Shramana; Robson, Nina; McCarthy, J. M. (August 2017, International Design Engineering Technical Conferences and Computers and Information in Engineering Conference)

   The paper presents the design of a lower leg orthotic device based on dimensional synthesis of multi-loop six-bar linkages. The wearable device is comprised of a 2R serial chain, termed the backbone, sized according to the wearer’s limb anthropometric dimensions. The paper is a result of our current efforts in proposing a systematic process for the development of 3D printed customized assistive devices for patients with reduced limb mobility, based on anthropometric data and physiological task. To design the wearable device, the physiological task of the limb is obtained using an optical motion capture system and its dimensions are set such that it matched the lower leg kinematics as closely as possible. As a next step a six-bar linkage is synthesized and ensured that its motion is as close as possible to the physiological task. Next, the 2R backbone is replaced by the wearer’s limb to provide the skeletal structure for the multiloop wearable device. During the final stage of the process the 2R backbone is relocated to parallel the human’s limb on one side, providing support and stability. The designed device can be secured to the thigh of the user to guide the lower leg without causing any discomfort and to ensure a natural physiological gait trajectory. This results in orthotic device for assisting people with lower leg injuries with compact size and better wearability. 

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4. Self‐Powered Multifunctional Human–Machine Interfaces for Respiratory Monitoring and Smart System Control

   https://doi.org/10.1002/admi.202201202  

   Pang, Yaokun; Chen, Shoue; Cao, Yunteng; Huang, Zhida; Xu, Xianchen; Fang, Yuhui; Chase) Cao, Changyong (July 2022, Advanced Materials Interfaces)

   Abstract Innovative human–machine interfaces (HMIs) have attracted increasing attention in the field of system control and assistive devices for disabled people. Conventional HMIs that are designed based on the interaction of physical movements or language communication are not effective or appliable to severely disabled users. Here, a breath‐driven triboelectric sensor is reported consisting of a soft fixator and two circular‐shaped triboelectric nanogenerators (TENGs) for self‐powered respiratory monitoring and smart system control. The sensor device is capable of effectively detecting the breath variation and generates responsive electrical signals based on different breath patterns without affecting the normal respiration. A breathing‐driven HMI system is demonstrated for severely disabled people to control electrical household appliances and shows an intelligent respiration monitoring system for emergence alarm. The new system provides the advantages of high sensitivity, good stability, low cost, and ease of use. This work will not only expand the development of the TENGs in self‐powered sensors, but also opens a new avenue to develop assistive devices for disabled people through innovation of advanced HMIs. 

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5. A Deep Learning-Based Autonomous Robot Manipulator for Sorting Application

   https://doi.org/10.1109/IRC.2020.00055  

   Bui, Hoang-Dung; Nguyen, Hai; La, Hung Manh; Li, Shuai (November 2020, 2020 Fourth IEEE International Conference on Robotic Computing (IRC))

   null (Ed.)

   Robot manipulation and grasping mechanisms have received considerable attention in the recent past, leading to development of wide-range of industrial applications. This paper proposes the development of an autonomous robotic grasping system for object sorting application. RGB-D data is used by the robot for performing object detection, pose estimation, trajectory generation and object sorting tasks. The proposed approach can also handle grasping on certain objects chosen by users. Trained convolutional neural networks are used to perform object detection and determine the corresponding point cloud cluster of the object to be grasped. From the selected point cloud data, a grasp generator algorithm outputs potential grasps. A grasp filter then scores these potential grasps, and the highest-scored grasp will be chosen to execute on a real robot. A motion planner will generate collision-free trajectories to execute the chosen grasp. The experiments on AUBO robotic manipulator show the potentials of the proposed approach in the context of autonomous object sorting with robust and fast sorting performance. 

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