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Poland
11-50 Employees
2018
With Zeus, we are combining the best of what technology has to offer today - additive manufacturing, IoT, and machine learning. As an organization, we are driven by our vision of providing custom solutions for upper limb amputees to help them restore their freedom and independence. Our mission at Aether Biomedical is to offer a bionic hand for all. Four years later and our team has created a product that has fulfilled our founders’ goals from long ago - a multi-articulating bionic hand, available for all: the Zeus. To achieve this goal, we develop cutting-edge prosthetic and rehabilitation devices through innovation in bio-signal processing. While this technology may not be entirely new to the biomedical industry, we are looking to develop it further, shaking up the world of medical devices by engineering products that can exceed the current global standards of prosthetics. Aether Biomedical is based out of Poznan, Poland and was founded on the premise of creating healthcare technology and robotics based on human-centered design. We founded Aether Biomedical to solve the critical problems plaguing the rehabilitation and assistive devices industry, namely low adoption, meager retention, and a profound lack of data-efficiency.
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Featured
Robotic Prosthetic Arm | Bionic Arm | Prosthetic Hand - Aether Biomedical
... Robotic Prosthetic Arm | Bionic Arm | Prosthetic Hand - Aether ...
Buckingham, United Kingdom
11-50 Employees
All the services we provide are in-house, which enables a smooth process from design to delivery. The company was founded and is still run by creative director Jez Gibson-Harris, who has over 30 years’ experience in the Film, TV, Advertising and Model Making Industry. We also have a reliable and trusted pool of specialist sub-contractors that we can call on when required. Our workshop is a modern, light building, designed to meet the needs of our company with designated spaces for moulding, sculpting, machining, electronics design, engineering and art working. As a company we always aim to provide the best quality and we are guided by a quality management system registered to ISO 9001:2015 that ensures our customers always receive the best possible service. Crawley Creatures aim has always been to provide our customers with the best – best quality, best solution and best value.
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Featured
Crawley Creatures | SFX, Animatronics, Prosthetics, Robotics
... Crawley Creatures offer a full range of services, including animatronics, prosthetics, creature FX, robotics, engineering, costumes, puppets and model making. ...
Columbus, United States
11-50 Employees
1970
American Orthopedics has the only BioSculptor, computer-aided design, and manufacturing system in Central Ohio along with the newly introduced handheld Polhemus BioScanner. BioSculptor is a state-of-the-art design and manufacturing system for prosthetics and orthotics, utilizing laser imaging, fast computer modeling, and a high speed, 4.5 axis CNC mill. Every day at American Orthopedics we provide early, cost-saving prosthetic intervention. Our commitment to quality care, coupled with 21st-century technology allows us to provide fast, cost-effective service to the Central Ohio community. Our partnership with OPGA / POINT Health Care provides cooperative interaction with the finest practitioners in the country. American Orthopedics has positioned itself as the technology leader in prosthetics & orthotics over its long and successful history of providing outstanding care to the citizens of Central Ohio. Our commitment to quality care, coupled with 21st century technology allows us to provide fast, cost-effective service to the Central Ohio area.
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Featured
Bilateral Amputee Learns To Walk With Robotic Prosthetics
... Bilateral Amputee Learns To Walk With Robotic Prosthetics ‹ News - American Orthopedics | Prosthetics & Orthotics | Columbus, Lima, Springfield, ...
Pittsburgh, United States
1-10 Employees
2015
Humotech exists to reduce startup time, improve efficiency, and help realize more successes in the research and development of wearable machines with its unique platform of tools and services to clear long-standing bottlenecks to innovation. We are building a world as exciting as science fiction leads us to imagine by applying rigorous evidence-based methodologies to tough problems for which we know simple solutions must exist. Humotech seeks to uplift innovators of all kinds, with the tools and the support necessary to unlock the next generation of wearable machines. We believe that the field of wearable machines possesses enormous unrealized potential, and are confident that we will unlock it together through collaboration, commitment to the individual user, and platform technologies that align all stakeholders to work smarter, together. As an advanced and innovative society, we have both a moral and an economic imperative to leverage technology to enhance quality of life, increase productivity, and protect people from harm. For too long, innovators have had to endlessly prototype towards mass-marketable products, only to realize the disconnect between biomechanical feasibility and the market’s appetite for the solution.
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Featured
Open Source Leg | Humotech
... The Open Source Leg (OSL) is an untethered robotic prosthetic leg designed by the Open-Source Bionic Leg Project, based out of the University of Michigan. ...
San Francisco, United States
1-10 Employees
2019
Download official Atom Limbs logos, product media, and executive team photos. Atom Touch is Atom Limbs' initial arm launching in 2024.
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Featured
Atom - The first artificial human arm, coming 2024
... The Atom Touch from Atom Limbs is an artificial arm capable of full human range of motion, restores a basic sense of touch, and is non-invasively mind-controlled, and widely seen as far superior to existing robotic and prosthetic options on the market. Coming in 2024. ...
Town of Rhinebeck, United States
11-50 Employees
2014
Maxon motors are incorporated into every TrueLimb we produce. HP helps Unlimited Tomorrow create personalized prosthetics through its innovative materials and 3D printing technology.
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Featured
TrueLimb® Prosthetic Arm Manufacturer | Unlimited Tomorrow
... Unlimited Tomorrow is a manufacturer that supplies individuals & clinicians with our TrueLimb® robotic prosthetic arm. Learn how to get started with TrueLimb® today! ...
Bedminster, United States
1-10 Employees
2010
Ben is a serial entrepreneur and has been involved in over 18 startups in the capacity of a co-founder/founder, executive, strategist, investor, and mentor. Chime is a financial technology company founded on the premise that basic banking services should be helpful, easy and free. They partner with regional banks to design member first financial products. Founded in 2013, Patreon is a developer of a patronage platform designed to monetize the creator’s work through a direct relationship with their fans. Airbnb offers an alternative to traditional hotels and hospitality by providing house owners the opportunity to rent out their property. Mission Control X is creating the next generation of great entrepreneurs through a number of initiatives to promote youth entrepreneurship including educational programming, economic empowerment, and hands-on entrepreneurial experiences. Mission Control X is currently in developmental phases and is planning on launching programs in 2021. Ben Jen is the Managing Director & Principal Investor for Ben Jen Holdings.
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Featured
SynTouch - Ben Jen Holdings SLLC
... Biomimetic touch technology that enables robots to feel the world: Machine Touch® is impacting the fields of robotics, VR haptics, prosthetics, and e-commerce. ...
San Antonio, United States
1-10 Employees
2018
Every dollar supports our mission to report on San Antonio's startup community. Startups San Antonio reports on the emerging capabilities, companies, and people developing innovative solutions in technology, bioscience, engineering, and cybersecurity in San Antonio, Texas. San Antonio has a significant military presence, possessing the nation’s second-largest concentration of cybersecurity experts and home to several leading military medical research missions. Aerospace and aviation, new energy, and advanced robotics in manufacturing are major industry sectors in San Antonio, too. Iris Gonzalez founded Startups San Antonio in 2018 out of a passion for San Antonio’s stories of innovation.
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Featured
Startups San Antonio Home | Startups San Antonio
... Robotic Prosthetics Startup Alt-Bionics Wins New Innovation ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Robotic Prosthetics
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 2 |
| Amount of suitable service providers | 2 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1970 |
| Youngest suiting company | 2019 |
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Robotic prosthetics are advanced, biomechanical devices designed to replace or enhance the function of missing or impaired limbs through the integration of robotics technology. These sophisticated prostheses incorporate sensors, actuators, and control systems that mimic the natural movement of human limbs, enabling users to perform a wide range of activities with improved precision and ease. The actuators serve as muscles, generating the necessary forces, while sensors detect environmental inputs (such as pressure or position), and advanced algorithms process these inputs to facilitate smooth, coordinated movements that closely replicate those of biological limbs. This integration of engineering, biomechanics, and neuroscience has significantly propelled the capabilities of prosthetic devices beyond passive, cosmetic replacements to dynamic systems that offer sensory feedback, adaptability, and a degree of autonomy. Within the field of rehabilitative and assistive technology, robotic prosthetics represent a transformative leap forward, offering individuals with limb loss or impairments enhanced mobility, independence, and quality of life. Their development not only pushes the boundaries of medical engineering but also offers profound insights into human-machine interfaces, contributing to broader applications in robotics, artificial intelligence, and even the understanding of human motor control. As such, robotic prosthetics stand at the forefront of innovation, embodying the convergence of technology and human resilience.
1. Enhanced Functionality:
Robotic prosthetics offer users a level of dexterity and control that closely mimics human limbs. This includes the ability to perform complex tasks that require fine motor skills, significantly improving the quality of life for amputees.
2. Customizable and Adaptive:
These prosthetics can be tailored to fit the specific needs and preferences of each user, including size, shape, and level of control. Moreover, advanced sensors and software allow these devices to learn and adapt to the user’s movement patterns, enhancing the natural feel of the limb.
3. Increased Strength and Endurance:
Robotic limbs can provide greater strength than what the user's natural limb might have offered, without the fatigue common in human muscles. This is particularly beneficial for tasks that require heavy lifting or repetitive movements.
4. Psychological and Social Benefits:
The use of robotic prosthetics can significantly boost the self-esteem and confidence of users, helping them to lead more active and fulfilling lives. The modern and high-tech appearance of these devices also helps in reducing the stigma often associated with traditional prosthetics, promoting a more positive social perception.
While evaluating the different suppliers make sure to check the following criteria:
1. Technological Advancement
Ensure the supplier employs the latest technology in both the design and manufacturing of robotic prosthetics. This includes advanced materials, sensors, and AI integration for improved functionality and user experience.
2. Customization Capabilities
The supplier should offer customization options to meet the specific needs and preferences of each user, including size, shape, and control mechanisms.
3. Regulatory Compliance
Check that the supplier complies with all relevant medical device regulations and standards to ensure the safety and efficacy of the prosthetics.
4. After-Sales Support
Evaluate the level of after-sales support, including warranty, maintenance, and repair services, to ensure long-term usability and satisfaction.
5. User Training and Rehabilitation Support
The supplier should provide comprehensive training for users on how to effectively operate the prosthetic, as well as offer rehabilitation support to aid in their adaptation period.
6. Research and Development Focus
Consider suppliers with a strong focus on R&D to ensure continuous improvement in prosthetic technology and better outcomes for users.
7. Cost-Effectiveness
While not compromising on quality, assess the cost-effectiveness of the prosthetics, taking into account initial purchase price, ongoing maintenance costs, and available financing options.
8. User Reviews and Testimonials
Look for feedback from current and past users to gauge satisfaction levels and identify any common issues or complaints with the supplier's products or services.
Robotic prosthetics, with their advanced technology, have transcended beyond individual use to serve broader business-to-business (B2B) applications across various industries. One notable use case is in the healthcare sector, where hospitals and rehabilitation centers procure these high-tech devices to offer cutting-edge treatment options to patients. These establishments benefit from providing top-tier prosthetic solutions that enhance their service quality, leading to improved patient outcomes and satisfaction. In the manufacturing and construction industries, companies integrate robotic prosthetics to support and enhance the capabilities of their workforce. Workers equipped with these prosthetics can perform tasks with increased strength, precision, and efficiency, leading to higher productivity and reduced risk of workplace injuries. This application not only improves operational efficiency but also demonstrates a commitment to employee well-being and accessibility. Another burgeoning area is in the research and development (R&D) sector, where firms specializing in biomedical and robotic technologies collaborate on the advancement of prosthetic devices. These partnerships focus on innovating more intuitive, durable, and functional prosthetics, pushing the boundaries of what's possible in bionic integration and human-machine interfaces. Lastly, the defense and veterans' affairs sectors present a significant use case, where robotic prosthetics are procured to assist and rehabilitate soldiers who have sustained injuries in the line of duty. This not only aids in their physical recovery but also plays a crucial role in their psychological adjustment and reintegration into civilian life or return to active duty. These B2B use cases underscore the versatile applications of robotic prosthetics beyond individual users, highlighting their impact on enhancing workforce capabilities, advancing medical treatments, and fostering innovation in technology and healthcare.
As of the latest assessments, robotic prosthetics are generally considered to be at Technology Readiness Level (TRL) 7 or 8, indicating that such technologies have been demonstrated in relevant environments (TRL 7) or have reached actual system completion and are proven through successful mission operations (TRL 8). This placement is due to the significant advancements in materials science, robotics, and biointerface technologies that have enabled the development of sophisticated prosthetic limbs capable of closely mimicking the functionality of natural limbs. The inclusion of sensors, actuators, and advanced control systems, integrated through machine learning algorithms, allows these prosthetics to interpret the user's muscle movements and intentions with high accuracy, thereby providing more natural and intuitive control. Moreover, the successful deployment and testing of these prosthetics in real-life scenarios, including their use by amputees in day-to-day activities and in various occupational environments, underscore their operational viability. However, despite these advancements, the field is still addressing challenges related to improving the long-term comfort, reducing the overall cost, and enhancing the sensory feedback (haptic feedback) of these systems, which prevents the technology from reaching the final TRL 9. This ongoing development underscores a dynamic field where technical improvements continue to push the boundaries of what is possible with robotic prosthetics.
In the Short-Term, advancements in robotic prosthetics will predominantly focus on enhancing sensory feedback and integration. Immediate efforts will be channeled towards creating prosthetics that offer users a more natural sense of touch and proprioception. This phase will witness the integration of advanced materials and sensors that mimic the tactile feedback of human skin, alongside improvements in the seamless connection between the device and the user's nervous system. These enhancements aim to provide users with a more intuitive control over their prosthetic limbs, significantly improving their day-to-day functionality and comfort. Mid-Term developments will concentrate on the autonomy of robotic prosthetics, leveraging AI and machine learning to enable these devices to predict and adapt to users’ movements in real-time. This period will see the introduction of prosthetics capable of executing complex tasks autonomously, such as adjusting grip strength and dexterity without explicit user commands. Additionally, battery life and energy efficiency will see substantial improvements, allowing for longer use periods without the need for recharging. This phase marks a shift towards more adaptable and user-friendly prosthetics, bridging the gap between artificial and natural limb functionality. In the Long-Term, the focus will shift towards the full integration of robotic prosthetics with the human body, utilizing advancements in bioengineering and nanotechnology. This era will witness the development of prosthetics that can self-repair and adapt their structure and functionality over time, closely mirroring the biological growth and healing processes of human tissues. Furthermore, efforts will be made to achieve complete neural integration, allowing for prosthetics that can be controlled with thought alone, offering an unprecedented level of precision and user experience. This phase represents the pinnacle of prosthetic technology, blurring the lines between biological and mechanical, and offering individuals unparalleled abilities and autonomy.
Some interesting questions that has been asked about the results you have just received for Robotic Prosthetics
What are related technologies to Robotic Prosthetics?
Based on our calculations related technologies to Robotic Prosthetics are Biomedical (Red), Bioinformatics (Gold), Environmental Biotechnology (Grey), Agricultural Biotechnology (Green), Food Related Biotechnology (Yellow)
Which industries are mostly working on Robotic Prosthetics?
The most represented industries which are working in Robotic Prosthetics are Hardware, Science and Engineering, Software, Health Care, Artificial Intelligence
How does ensun find these Robotic Prosthetics Companies?
ensun uses an advanced search and ranking system capable of sifting through millions of companies and hundreds of millions of products and services to identify suitable matches. This is achieved by leveraging cutting-edge technologies, including Artificial Intelligence.
