#Based on world Leading Robotic rehabilitation technology
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Understanding Oncologists in Singapore: Your Guide to Expert Cancer Care
Cancer is one of the leading health concerns worldwide, and Singapore is no exception. However, with its world-class healthcare system and highly trained specialists, the country has become a hub for advanced cancer treatment. In this blog, we’ll explore what Oncologists in Singapore do, the types of treatments available, and why patients from across the region seek care in this city-state.
What Does an Oncologist Do?
Oncologists are doctors who specialize in diagnosing and treating cancer. There are three main types of oncologists:
Medical Oncologists: These specialists focus on cancer treatment using chemotherapy, immunotherapy, and targeted therapies.
Radiation Oncologists: They specialize in treating cancer with radiation therapy, using precise techniques to target cancer cells.
Surgical Oncologists: These experts perform surgeries to remove tumors and cancerous tissues.
In Singapore, oncologists work closely with multi-disciplinary teams to provide patients with comprehensive care tailored to their specific needs.
Why Choose Singapore for Cancer Treatment?
Singapore has a reputation for offering cutting-edge cancer treatments and technologies, making it a popular destination for medical tourism. Some reasons patients choose Singapore include:
Access to World-Class Facilities: Singapore’s healthcare institutions, like the National Cancer Centre Singapore (NCCS) and private hospitals, are equipped with advanced technologies such as proton therapy, robotic surgery, and personalized medicine.
Highly Trained Specialists: Oncologists in Singapore are not only highly trained but often have international experience, ensuring they’re well-versed in the latest cancer treatments and research. Many participate in clinical trials, offering patients access to innovative therapies.
Personalized Treatment Plans: Oncologists in Singapore prioritize patient-centered care. This means creating treatment plans based on the patient’s medical history, type and stage of cancer, and personal preferences.
Types of Cancer Treatment in Singapore
Chemotherapy: A common cancer treatment that uses powerful drugs to kill fast-growing cancer cells. Singapore’s oncologists ensure that treatments are as comfortable as possible, with modern facilities designed for patient convenience.
Immunotherapy: This cutting-edge treatment boosts the body’s immune system to fight cancer. Immunotherapy is available in top hospitals across Singapore and is especially effective for cancers like melanoma and lung cancer.
Radiation Therapy: Singapore’s hospitals offer both external beam radiation and internal radiation (brachytherapy). With advanced imaging technology, oncologists can accurately target tumors while minimizing damage to surrounding tissues.
Surgery: Many cancers require surgical intervention. Singaporean surgical oncologists are skilled in minimally invasive techniques, such as laparoscopic and robotic surgeries, which allow for quicker recovery times.
Targeted Therapy: This treatment focuses on the specific genes or proteins that contribute to cancer growth. Singapore’s access to advanced genetic testing allows oncologists to prescribe targeted therapies that improve outcomes for patients with specific cancer types.
Support Services for Cancer Patients
Cancer care doesn’t stop at treatment. In Singapore, patients benefit from a holistic approach that includes:
Support Groups and Counseling: Emotional and mental health is crucial during cancer treatment. Many hospitals offer counseling services and connect patients with support groups to share their experiences.
Palliative Care: For patients with advanced cancers, palliative care specialists work to improve the quality of life by managing symptoms and providing emotional support to patients and their families.
Rehabilitation Services: After cancer treatment, rehabilitation programs help patients regain strength and improve their overall well-being.
Finding an Oncologist in Singapore
Whether you’re seeking a second opinion, considering treatment, or just looking for more information, finding the right oncologist is crucial. Some of the top cancer centers and hospitals in Singapore include:
National Cancer Centre Singapore (NCCS)
Singapore General Hospital
Mount Elizabeth Hospital
Raffles Hospital
Gleneagles Hospital
These institutions offer a wide range of oncologists, each specializing in different cancer types and treatment modalities.
Conclusion
Singapore’s healthcare system is renowned for its excellent cancer care, and its oncologists are among the best in the world. With access to cutting-edge treatments, experienced specialists, and a holistic approach to patient care, Singapore is a top destination for individuals seeking advanced cancer treatment.
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Top 10 Innovations in Mechanical Engineering 2024
Mechanical engineering is an ever-evolving field, continuously pushing the boundaries of what’s possible with technology and design. As we move through 2024, several groundbreaking innovations are transforming the landscape of mechanical engineering, making it an exciting time for both seasoned professionals and newcomers. In this blog post, we’ll explore the top 10 innovations in mechanical engineering this year and discuss how these advancements are shaping the future of the field.
Mechanical engineering plays a crucial role in the development of technology and infrastructure that drives our modern world. Innovations in this field not only enhance efficiency but also address some of the most pressing challenges we face, from energy consumption to sustainability. This year, we’ve witnessed remarkable strides in various areas, each offering unique solutions and opportunities.
In this post, we’ll delve into the top 10 innovations that are making waves in mechanical engineering. Whether you’re a student exploring a career in mechanical engineering or a professional seeking to stay ahead of industry trends, these advancements are sure to inspire and inform.
1. Advanced Robotics and Automation
Current Trends
Robotics and automation have been central to mechanical engineering for decades, but recent advancements are taking these technologies to new heights. The integration of artificial intelligence (AI) into robotics has revolutionized how machines interact with their environment and with humans. Modern robots are no longer just tools; they’re becoming collaborative partners in various industries.
Key Innovations
Collaborative Robots (Cobots): Unlike traditional robots, cobots are designed to work alongside humans in shared workspaces. These robots are equipped with advanced sensors and AI, allowing them to perform complex tasks safely and efficiently while interacting with human operators.
Enhanced Robotic Dexterity: New developments in robotic limbs and grippers are increasing robots’ ability to handle delicate and complex tasks. This includes everything from assembling intricate electronic components to performing precise surgical procedures.
Impact and Applications
The impact of these innovations is profound. In manufacturing, cobots are improving productivity and flexibility on the production line. In the medical field, robots with enhanced dexterity are assisting in surgeries and rehabilitation, offering precision and reliability that were previously unattainable.
2. Smart Materials and Adaptive Systems
Introduction to Smart Materials
Smart materials are engineered to respond to changes in their environment, such as temperature, pressure, or electrical fields. These materials can change their properties or behavior in response to external stimuli, making them incredibly versatile and useful in a variety of applications.
Recent Developments
Self-Healing Materials: One of the most exciting advancements in smart materials is the development of self-healing materials. These materials can repair themselves when damaged, extending their lifespan and reducing maintenance costs. For example, self-healing concrete can automatically seal cracks, improving the durability of structures.
Responsive Materials: Innovations in responsive materials are leading to the creation of materials that adapt to environmental conditions. These include materials that can change their shape or properties based on temperature or pressure, making them ideal for applications such as adaptive building facades and wearable technology.
Applications and Benefits
Smart materials are making a significant impact in fields such as aerospace, automotive, and civil engineering. For instance, self-healing materials are being used in infrastructure to reduce repair costs and enhance longevity. Responsive materials are also being integrated into next-generation consumer products, offering greater functionality and user experience.
3. 3D Printing and Additive Manufacturing
Evolution of 3D Printing
3D printing, or additive manufacturing, has come a long way since its inception. This technology builds objects layer by layer from digital models, allowing for complex designs and rapid prototyping. Over the years, 3D printing has evolved to accommodate a wider range of materials and applications.
Innovations in 2024
New Materials: The range of materials used in 3D printing has expanded significantly. In 2024, we’re seeing advancements in metal and composite materials, which are enabling the production of stronger and more durable parts. This includes everything from aerospace components to custom medical implants.
Increased Speed and Precision: Recent improvements in 3D printing technology have made it faster and more precise. High-resolution printers are now capable of producing intricate designs with minimal waste, making 3D printing a more viable option for mass production.
Practical Applications
3D printing is transforming various industries. In healthcare, it’s used to create custom prosthetics and implants tailored to individual patients. In manufacturing, it enables rapid prototyping and the production of low-volume, high-complexity parts, reducing lead times and costs.
4. Sustainable Energy Solutions
Importance of Sustainability
Sustainability is a critical focus in engineering, given the global emphasis on reducing carbon emissions and conserving resources. Innovations in sustainable energy solutions are crucial for addressing climate change and promoting environmental stewardship.
Recent Innovations
Efficient Solar Panels: Advances in solar technology are leading to the development of more efficient and affordable solar panels. This includes the use of new materials and designs that increase energy conversion rates and reduce production costs.
Enhanced Wind Turbines: Wind turbine technology is also advancing, with new designs improving efficiency and durability. Innovations include larger turbine blades and more robust materials that can withstand harsh environmental conditions.
Impact on Mechanical Engineering
These sustainable energy solutions are driving significant changes in mechanical engineering. Engineers are now focusing on integrating these technologies into new designs and optimizing existing systems for better energy efficiency. This shift is essential for supporting global efforts toward cleaner energy and reduced environmental impact.
5. Enhanced Computational Fluid Dynamics (CFD)
Introduction to CFD
Computational Fluid Dynamics (CFD) involves using computer simulations to analyze fluid flows and interactions. This technology is vital for understanding and optimizing the behavior of fluids in various engineering applications, from aerodynamics to hydrodynamics.
Recent Innovations
Improved Algorithms: Advances in algorithms and computational power are enhancing the accuracy and speed of CFD simulations. This includes more sophisticated models that can handle complex flow scenarios and provide more precise results.
High-Performance Computing: The use of high-performance computing (HPC) is enabling engineers to run more detailed simulations in shorter times. This allows for more extensive testing and optimization of designs before physical prototypes are made.
Applications
Enhanced CFD technology is impacting multiple fields. In aerospace, it’s used to design more efficient aircraft and spacecraft. In automotive engineering, CFD helps optimize vehicle aerodynamics for better fuel efficiency and performance.
6. Next-Generation Energy Storage Systems
Current Energy Storage Technologies
Energy storage is crucial for managing the supply and demand of energy, particularly with the increasing reliance on renewable sources. Traditional energy storage solutions include batteries and capacitors, each with its own set of advantages and limitations.
Innovations in 2024
Solid-State Batteries: Solid-state batteries represent a significant advancement over traditional lithium-ion batteries. They offer higher energy densities, greater safety, and longer lifespans. This technology is poised to revolutionize electric vehicles and portable electronics.
Supercapacitors and Hydrogen Storage: Advances in supercapacitors are improving energy storage for applications requiring rapid discharge and recharge cycles. Meanwhile, developments in hydrogen storage are making it a more viable option for clean energy solutions and fuel cell vehicles.
Implications for Mechanical Engineering
These next-generation energy storage systems are driving innovations in mechanical engineering. Engineers are integrating these technologies into new designs and exploring their potential in various applications, from transportation to renewable energy systems.
7. Biomechanical Engineering Advances
Scope of Biomechanical Engineering
Biomechanical engineering combines principles from biology and mechanical engineering to create solutions for medical and health-related applications. This field focuses on understanding and improving human movement and function through engineered systems and devices.
Recent Innovations
Advanced Prosthetics: Recent advancements in prosthetics include more intuitive and functional designs that integrate with the user’s nervous system. This allows for more natural movement and greater control over prosthetic limbs.
Exoskeletons: The development of wearable exoskeletons is helping individuals with mobility impairments regain movement and strength. These devices are also being used in rehabilitation and physical therapy to enhance recovery and performance.
Applications and Benefits
Biomechanical engineering innovations are improving the quality of life for individuals with disabilities and injuries. These technologies are also aiding in rehabilitation and enhancing overall health and well-being through advanced assistive devices.
8. Autonomous Systems and AI Integration
Introduction to Autonomous Systems
Autonomous systems use AI and robotics to perform tasks without human intervention. These systems are becoming increasingly sophisticated, with applications ranging from autonomous vehicles to drones and robotic assistants.
Innovations in 2024
AI Algorithms: Advances in AI algorithms are enabling more accurate and reliable decision-making in autonomous systems. This includes improvements in machine learning and neural networks that enhance the capabilities of these systems.
Integration with Mechanical Systems: The integration of AI with mechanical systems is leading to more autonomous and intelligent devices. This includes everything from self-driving cars to autonomous drones capable of performing complex tasks.
Applications
Autonomous systems are transforming industries such as transportation, logistics, and surveillance. These technologies are improving efficiency, safety, and productivity by automating routine tasks and enabling new capabilities.
9. Advanced Manufacturing Techniques
Current Manufacturing Challenges
Traditional manufacturing techniques face several challenges, including inefficiencies, high costs, and limited flexibility. The industry is continually seeking ways to overcome these challenges and improve manufacturing processes.
Innovations in 2024
Smart Factories: The concept of smart factories involves using IoT, AI, and advanced sensors to create more efficient and flexible manufacturing environments. Smart factories enable real-time monitoring, predictive maintenance, and optimized production processes.
Machine Learning for Predictive Maintenance: Machine learning algorithms are being used to predict equipment failures before they occur. This proactive approach reduces downtime and maintenance costs, leading to more reliable and efficient manufacturing operations.
Impact on Mechanical Engineering
Advanced manufacturing techniques are reshaping the field of mechanical engineering. Engineers are now focusing on designing systems that integrate these innovations, improving production efficiency and quality control while reducing waste and resource consumption.
10. Enhanced Thermal Management Systems
Importance of Thermal Management
Thermal management is crucial for ensuring the reliability and performance of mechanical systems. Effective thermal management prevents overheating and ensures that components operate within their optimal temperature range.
Recent Innovations
Advanced Heat Sinks: New designs and materials are enhancing the efficiency of heat sinks, which dissipate heat from electronic components. Innovations include improved thermal interfaces and designs that increase heat dissipation capabilities.
New Materials for Thermal Conductivity: Advances in materials science are leading to the development of materials with superior thermal conductivity. These materials are used in various applications, from electronics cooling to industrial processes.
Applications and Benefits
Enhanced thermal management systems are essential for maintaining the performance and longevity of electronic devices, vehicles, and industrial equipment. By improving heat dissipation and thermal regulation, these innovations contribute to more reliable and efficient mechanical systems.
In 2024, the field of mechanical engineering is witnessing extraordinary innovations that are pushing the boundaries of what’s possible. From advanced robotics and smart materials to sustainable energy solutions and enhanced manufacturing techniques, these developments are transforming industries and improving our daily lives.
As we continue to explore and embrace these innovations, it’s an exciting time to consider a career in mechanical engineering. The advancements we’ve discussed not only offer opportunities for professional growth but also contribute to solving some of the most pressing challenges of our time.
If you’re passionate about technology and problem-solving, a career in mechanical engineering might be the perfect path for you. By staying informed about the latest trends and developments, you can position yourself at the forefront of this dynamic field and contribute to shaping the future.
Feel free to share your thoughts and experiences with these innovations in the comments below. We’d love to hear how these advancements are impacting your work or studies. Here’s to a future filled with exciting possibilities and groundbreaking achievements in mechanical engineering!
FAQs
1. What is mechanical engineering?
Mechanical engineering is a branch of engineering that focuses on designing, analyzing, manufacturing, and maintaining mechanical systems. It combines principles from physics and mathematics to solve problems related to machinery and mechanical processes.
2. Why is innovation important in mechanical engineering?
Innovation drives progress and improvement in mechanical engineering, leading to more efficient, sustainable, and advanced technologies. It helps address challenges and create new opportunities in various industries.
3. What are cobots and how are they used?
Collaborative robots (cobots) are designed to work alongside humans in shared workspaces. They enhance productivity and safety by performing tasks that complement human work, such as assembling components or assisting in complex processes.
4. How do self-healing materials work?
Self-healing materials contain mechanisms that enable them to repair themselves when damaged. This can include embedded microcapsules that release healing agents or materials that respond to stress by sealing cracks automatically.
5. What are solid-state batteries and their advantages?
Solid-state batteries use a solid electrolyte instead of a liquid or gel. They offer higher energy density, improved safety, and longer lifespans compared to traditional lithium-ion batteries, making them ideal for electric vehicles and portable devices.
6. What role does CFD play in engineering?
Computational Fluid Dynamics (CFD) is used to simulate and analyze fluid flows and interactions. It helps engineers optimize designs, predict performance, and solve complex fluid-related problems in applications such as aerodynamics and hydrodynamics.
7. How are advanced prosthetics improving quality of life?
Advanced prosthetics integrate with the user’s nervous system to provide more natural and intuitive movement. This enhances the functionality and comfort of prosthetic limbs, improving the overall quality of life for individuals with limb loss.
8. What are smart materials and how are they used?
Smart materials respond to environmental changes, such as temperature or pressure, by altering their properties or behavior. They are used in various applications, including adaptive building systems, responsive clothing, and advanced medical devices.
9. How do smart factories benefit manufacturing?
Smart factories use IoT, AI, and advanced sensors to create more efficient and flexible manufacturing environments. They enable real-time monitoring, predictive maintenance, and optimized production processes, leading to improved efficiency and reduced costs.
10. What are some applications of autonomous systems?
Autonomous systems are used in various applications, including self-driving cars, drones for surveillance and delivery, and robotic assistants in industrial and healthcare settings. They enhance efficiency, safety, and capability by performing tasks without human intervention.
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Best Oncologist Surgeon in Mumbai: Expertise of Dr. Ganesh Nagarajan
When it comes to cancer treatment, choosing the best oncologist surgeon in Mumbai can be a life-changing decision. Dr. Ganesh Nagarajan, with his vast expertise and comprehensive care, has become a trusted name in the field of oncology. As a leading oncologist, Dr. Nagarajan's dedication to providing individualized treatment has made Cancer Surgery Clinic a top destination for patients across Mumbai and beyond.
Why Choose Dr. Ganesh Nagarajan?
Dr. Ganesh Nagarajan is widely recognized as the best oncologist surgeon in Mumbai for his advanced surgical techniques and patient-centric approach. With decades of experience in the field, Dr. Nagarajan specializes in a wide range of cancers, offering effective surgical treatments that are both minimally invasive and tailored to the specific needs of each patient.
Expert in advanced cancer surgeries
Pioneer in minimally invasive and robotic surgeries
Dr. Nagarajan's vast experience covers many types of cancers, including gastrointestinal, hepatobiliary, and colorectal cancers. His use of state-of-the-art technology ensures that every patient receives the most precise and effective treatment possible, helping to improve survival rates and reduce recovery times.
Cutting-Edge Treatment at Cancer Surgery Clinic
Cancer Surgery Clinic, led by Dr. Ganesh Nagarajan, is a state-of-the-art facility designed to offer world-class cancer treatment. The clinic is equipped with advanced surgical technology, ensuring that each patient receives the best care possible.
Advanced surgical tools for precision care
Comprehensive cancer care, from diagnosis to treatment
At Cancer Surgery Clinic, the focus is not only on the treatment but also on the overall well-being of the patient. This holistic approach has made Dr. Ganesh Nagarajan one of the most sought-after oncologist surgeons in Mumbai, offering hope and healing to countless patients.
Comprehensive Cancer Care for All
As the best oncologist surgeon in Mumbai, Dr. Ganesh Nagarajan believes in offering comprehensive cancer care. From diagnosis and treatment planning to post-surgery care and rehabilitation, every stage of the patient’s journey is carefully monitored and managed. This ensures the best possible outcomes for patients and their families.
Dr. Nagarajan is committed to staying at the forefront of cancer treatment advancements. His dedication to continuous learning and applying the latest techniques ensures that his patients receive the most effective treatments available.
Patient-Centered Approach
What sets Dr. Ganesh Nagarajan apart as the best oncologist surgeon in Mumbai is his personalized approach to cancer care. He understands that every cancer case is unique, and so is every patient. By developing individualized treatment plans, Dr. Nagarajan ensures that each patient receives the right treatment based on their specific cancer type, stage, and overall health.
Tailored treatment plans for every patient
Focus on minimizing side effects and enhancing recovery
This patient-centered approach has earned Dr. Nagarajan immense trust and respect among his patients and peers alike. He believes in not only treating cancer but also improving the quality of life for his patients.
A Legacy of Excellence in Cancer Surgery
Over the years, Dr. Ganesh Nagarajan has successfully treated numerous complex cancer cases, becoming one of the top oncologist surgeons in Mumbai. His commitment to offering the highest standards of care, combined with his compassionate approach, makes him the best choice for patients seeking advanced cancer treatment.
Successfully treated thousands of patients
Recognized as a leader in oncological surgeries in Mumbai
Contact the Best Oncologist Surgeon in Mumbai Today
If you or a loved one is facing a cancer diagnosis, don’t wait. Schedule a consultation with Dr. Ganesh Nagarajan, the best oncologist surgeon in Mumbai, and take the first step towards expert care and a better quality of life.
Cancer Surgery ClinicSanskruti by Sugee, 202, 2nd Floor, Lady Jamshedji Rd, opp. Kohinoor Tower, Dadar West, Shivaji Park, Mumbai, Maharashtra 400028
Email: [email protected]
Phone: +91 77000 58024
Follow Dr. Ganesh Nagarajan on Social MediaInstagram | Facebook | YouTube
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Techno-Health: The AI Revolution that will Boost the Future of Healthcare
Technology is revolutionizing healthcare in numerous ways, transforming the industry to be more efficient, accessible, and personalized. Here are some ways in which technology is shaping the future of healthcare:
Telemedicine: Telemedicine allows patients to consult with healthcare providers remotely, using video conferencing and other digital communication tools. This has become particularly important during the COVID-19 pandemic, enabling patients to receive care without risking exposure to the virus.
Artificial Intelligence (AI): AI is being used in healthcare for a variety of purposes, including medical imaging, diagnosis, personalized treatment plans, and predictive analytics. AI algorithms can analyze large amounts of data to identify patterns and trends that may not be apparent to human clinicians, leading to more accurate diagnoses and better treatment outcomes.
Electronic Health Records (EHRs): EHR systems digitize patient medical records, making them easily accessible to healthcare providers and improving coordination of care. EHRs can also incorporate AI algorithms to help clinicians make more informed decisions based on a patient's medical history and other relevant data.
Remote Monitoring Devices: Wearable devices and sensors allow patients to monitor their health outside of traditional healthcare settings. These devices can track vital signs, activity levels, and other health metrics, providing valuable data to both patients and healthcare providers for early detection of health issues and ongoing management of chronic conditions.
Robotics: Robotics technology is being used in healthcare for tasks such as surgery, rehabilitation, and medication management. Surgical robots, for example, enable more precise and minimally invasive procedures, reducing recovery times and improving patient outcomes.
Genomics and Personalized Medicine: Advances in genomics and genetic testing are enabling personalized approaches to healthcare, allowing treatments to be tailored to an individual's genetic makeup. This can lead to more effective treatments with fewer side effects, particularly in the field of cancer treatment.
Blockchain: Blockchain technology has the potential to improve the security and interoperability of healthcare data, enabling secure sharing of patient information across different healthcare providers and systems while maintaining patient privacy.
Virtual Reality (VR) and Augmented Reality (AR): VR and AR technologies are being used in healthcare for purposes such as medical training, pain management, and patient education. VR simulations can provide realistic training scenarios for medical professionals, while AR applications can overlay digital information onto the real world to assist with surgeries and other medical procedures.
Healthcare Forms:
In healthcare, forms play a crucial role in collecting and organizing patient information, facilitating communication between healthcare providers and patients, and ensuring compliance with regulatory requirements. With the advancement of technology, digital forms are increasingly being utilized to streamline these processes and enhance efficiency in healthcare settings.
One key aspect where technology is transforming healthcare forms is in patient intake forms. Digital intake forms allow patients to fill out necessary information online before their appointment, reducing wait times and administrative burdens for both patients and healthcare providers. These forms can be customized to collect specific information relevant to each patient's visit, such as medical history, current medications, and insurance details, ensuring that healthcare providers have all the necessary information to deliver personalized care.
Furthermore, technology is facilitating the integration of electronic signature capabilities into healthcare forms, allowing patients to sign documents securely and conveniently from any device with internet access. This not only eliminates the need for printing, scanning, and faxing paper documents but also enhances security and compliance by providing a digital audit trail of all signed documents.
Overall, technology is playing a transformative role in shaping the future of healthcare, making it more efficient, accessible, and patient-centered. However, it's important to ensure that these technologies are implemented thoughtfully and ethically to maximize their benefits while minimizing potential risks and disparities.
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PACE Hospitals - Best Liver Transplant Hospital in Hyderabad India
PACE Hospitals is a leading healthcare provider in Hyderabad, India, renowned for its advanced liver transplant program. Our team of highly skilled doctors and specialists have extensive experience in performing both deceased donor and living donor liver transplants, with a proven track record of success.
We are one of the Advanced Centre for Liver Transplant in Hyderabad India backed up with team of the best liver transplant surgeon, transplant hepatologist, interventional pulmonologist, cardiologist, nephrologist, paramedical staff, dietitian and physiotherapist in India.
Liver Transplant Team at PACE Hospitals, Hyderabad evaluates the recipient and donor thoroughly before performing the transplant by doing medical and radiological investigations including Blood test, Urine test, CT Scan or MRI Scan to ensure the fitness of the recipient and the donor. Living donor liver transplant followed by a detailed and extensive evaluation of the donor first because donor safety is extremely important before giving medical fitness clearance.
Why Choose PACE Hospitals for Your Liver Transplant?
Experienced Team: Our multidisciplinary team comprises of:
Liver transplant surgeons with over 25 years of experience
Transplant hepatologists specializing in pre- and post-surgical management
Dedicated liver intensive care unit (LICU) staff ensuring exceptional care throughout the process
High Success Rates: PACE Hospitals boasts a commendable success rate for adult and pediatric liver transplants, giving patients a renewed hope for a healthy life.
Advanced Technology: We are equipped with cutting-edge technology to ensure precision and minimally invasive procedures, including:
World's 1st Robotic Surgical System
Advanced 3D HD laparoscopic system
Comprehensive Care: PACE Hospitals offers a comprehensive liver transplant program, guiding patients through every step of the journey, from pre-transplant evaluation to post-operative care and follow-up.
Our Liver Transplant Services :
Deceased Donor Liver Transplants: We efficiently manage the organ allocation process to ensure timely access to donor livers.
Living Donor Liver Transplants: Our team expertly evaluates potential living donors and performs the transplant surgery with meticulous care.
Pre- and Post-operative Care: Our dedicated team provides thorough pre-transplant evaluation to assess a patient's suitability for surgery. We also offer extensive post-operative care and rehabilitation to ensure a smooth recovery.
What is Liver Transplant?
Liver transplantation is a surgical procedure in which the liver which is not functioning properly is replaced by a healthy liver or a part of a liver from a living donor or deceased donor. A liver transplant also called as hepatic transplantation that removes the injured or diseased liver and replaces it with a healthy liver. This process of replacement is also known as allograft. It can potentially save people in case of a liver failure.
Liver failure can have serious complications, accompanied by several health visits, and you can be admitted. Living donor transplant can be an alternative to waiting for a deceased donor liver to become available.
Indications for liver transplantation
Patients are to be considered for liver transplantation if they have any of the following conditions:
Fulminant hepatic failure - severe necrosis of hepatocytes or severe disability of hepatic functions in the absence of preexisting liver disease
Liver-based metabolic defect - Hereditary hemochromatosis, Alpha-I antitrypsin deficiency (AATD), and Wilson Disease
Cirrhosis with complications such as ascites, hepatic encephalopathy, ascites, hepatocellular carcinoma, hepatorenal syndrome Bleeding caused by portal hypertension
Patients are required to go through with a detailed medical evaluation before the transplant by the organ transplant centres. After evaluation approved patients are placed on the transplant list, based on the End-Stage Liver Disease (MELD) score donor liver is assigned to the recipient with the highest estimated short-term mortality.
The wait for a recipient varies greatly based on the extent of the damage. Based on the damage, the recipient may have to wait for day or months or may never receive a liver on time. As the recipient wait for a liver, the doctor may put recipient on medications to relieve the discomfort.
For more information about our Liver Transplant Program, including success rates, patient stories, and physician profiles, please visit the PACE Hospitals website or contact us to schedule a consultation.
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Exploring the Various Types of Knee Replacement Surgery
Exploring the World of Knee Replacement Surgery: Types and Options
Knee pain can significantly impact one's quality of life, limiting mobility and causing discomfort. When conservative treatments like medication and physical therapy prove ineffective, knee replacement surgery becomes a viable option. There are several types of knee replacement surgery, each designed to address specific issues and patient needs. In this blog, we'll delve into the various types of knee replacement surgery to help you better understand your options and make an informed decision about your healthcare.
1. Total Knee Replacement (TKR)
Total Knee Replacement, or TKR, is the most common and well-known type of knee replacement surgery. It's typically performed when all three compartments of the knee joint (medial, lateral, and patellofemoral) are affected by osteoarthritis or other conditions. During a TKR, the damaged joint is removed and replaced with an artificial joint made of metal, plastic, or a combination of both. The procedure aims to restore the natural movement and function of the knee.
2. Partial Knee Replacement (PKR)
Partial Knee Replacement, or PKR, is an option when only one or two compartments of the knee are damaged. This procedure is less invasive than a TKR because it preserves healthy bone and tissue. Patients undergoing a PKR generally experience a faster recovery, less post-operative pain, and better range of motion in the affected knee. It's essential to consult with a surgeon to determine if you're a suitable candidate for PKR based on the location and extent of your knee damage.
3. Bilateral Knee Replacement
Some individuals may require knee replacement surgery in both knees due to extensive damage in both joints. Bilateral Knee Replacement involves replacing both knees in one or two surgeries, depending on the patient's health and surgeon's recommendation. It's crucial to carefully evaluate the pros and cons of this approach, as it may extend the recovery period and require thorough post-operative rehabilitation.
4. Revision Knee Replacement
While knee replacement surgeries are generally successful, they may wear out or fail over time, necessitating a revision knee replacement. Revision surgery is more complex than primary replacements and typically involves removing and replacing worn-out components or addressing other issues such as infection, instability, or bone loss. Surgeons use specialized techniques and implants during revision surgery to ensure the best possible outcome for patients.
5. Custom Knee Replacement
Custom Knee Replacement, also known as Patient-Specific Instrumentation (PSI), is an innovative approach to knee surgery. It involves the use of advanced imaging and computer technology to create customized cutting guides and implant components tailored to each patient's unique anatomy. Custom knee replacements aim to improve the accuracy of implant positioning, potentially leading to better outcomes and faster recovery times.
6. Robotic-Assisted Knee Replacement
Robotic-Assisted Knee Replacement combines the precision of robotic technology with the skills of a skilled orthopedic surgeon. During this procedure, the surgeon uses a robotic arm to assist in precise bone cuts and implant placement. The robotic system provides real-time feedback and enhances the surgeon's ability to optimize the implant's alignment and positioning. This advanced technology is gaining popularity as it offers a high level of precision and potentially reduces the risk of complications.
7. Minimally Invasive Knee Replacement
Traditional knee replacement surgery involves a relatively large incision and more extensive tissue disruption. In contrast, Minimally Invasive Knee Replacement is performed through smaller incisions and with less soft tissue trauma. This approach often results in less pain, a quicker recovery, and reduced scarring. However, it may not be suitable for all patients, depending on the complexity of their knee condition.
8. Gender-Specific Knee Replacement
Research has shown that there are differences in the anatomy and biomechanics of male and female knees. Gender-Specific Knee Replacement takes these differences into account by offering implants designed to better match the anatomy of the patient's gender. These specialized implants aim to provide improved comfort, stability, and long-term outcomes for patients.
Conclusion
Knee replacement surgery is a life-changing procedure that can significantly improve the quality of life for individuals suffering from knee pain and arthritis. The choice of the most suitable type of knee replacement surgery depends on several factors, including the extent of joint damage, the patient's overall health, and the surgeon's expertise. It's essential to consult with a qualified orthopedic surgeon who can evaluate your condition and recommend the most appropriate approach for your specific needs.
You can make an informed decision about your treatment if you understand the various forms of knee replacement surgery and their advantages and downsides. Remember that, regardless of the type of knee replacement surgery you choose, post-operative rehabilitation and a dedication to a healthy lifestyle are critical to the success of your operation. To determine the best course of action for your specific circumstance, always check with your healthcare professional.
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The Role of Innovation in Inclusive Disability Services
In the ongoing pursuit of inclusivity and equal opportunities for all, innovation plays a significant role in advancing disability services.
Innovative approaches and technologies have the power to break down barriers, enhance accessibility, and improve the overall quality of life for individuals with disabilities.
In this blog post, we will explore how innovation is transforming and revolutionising disability services in Brisbane, making them more inclusive and empowering for those who need them.
Advancements in Assistive Technologies
One of the most impactful ways that innovation is improving disability services is through advancements in assistive technologies. Assistive devices and technologies are designed to support individuals with disabilities daily, enabling them to participate more fully in various activities.
From mobility aids like wheelchairs and prosthetics to communication devices and smart home systems, modern assistive technologies are significantly enhancing independence and accessibility for individuals with disabilities.
Accessibility in Digital Platforms
The digital age has opened up new possibilities for individuals with disabilities, thanks to increased efforts to ensure accessibility in digital platforms. Innovative design practices and technologies are being implemented to make websites, applications, and online content more accessible to individuals with visual, hearing, motor, or cognitive impairments. Features such as screen readers, closed captioning, alternative text for images, and keyboard navigation options are just a few examples of how innovation makes the digital world more inclusive for everyone.
Inclusive Transportation Solutions
Innovation is also crucial in improving transportation services for individuals with disabilities. Traditional transportation systems often pose challenges for those with mobility impairments, but innovative solutions are emerging to address these issues. Accessible public vehicles, ridesharing services with options for wheelchair accessibility, and on-demand transportation solutions are transforming how individuals with disabilities travel, providing them with greater freedom and independence.
Cutting-Edge Rehabilitation Techniques
In disability services in Brisbane, rehabilitation techniques are constantly evolving and becoming more sophisticated with the help of innovation. Advancements in physical therapy, occupational therapy, and cognitive rehabilitation enable individuals with disabilities to maximize their potential for recovery and functionality.
From virtual reality simulations for rehabilitation exercises to robotic technologies assisting with mobility, these innovative approaches are reshaping the landscape of rehabilitative care.
Inclusive Design Principles
Inclusive design principles are at the core of innovation in disability services. These principles emphasise the importance of creating products, environments, and in home care services accessible and usable by individuals with a wide range of abilities and disabilities. By integrating inclusive design practices from the beginning of the development process, innovative solutions can be designed to accommodate diverse needs, ensuring no individual is left behind or excluded.
Collaborative Partnerships and Co-creation
Innovation in disability services thrives on collaboration and co-creation. By fostering partnerships between individuals with disabilities, disability service providers, researchers, and technology developers, innovative ideas are generated to address specific needs and challenges. This collaborative approach ensures that the solutions created are practical, relevant, and based on real-life experiences, leading to more effective and impactful disability services.
The Call for Continued Innovation
While great strides have been made in leveraging innovation to improve disability services, much work remains to be done. The call for continued innovation in this field is ongoing. By listening to the voices and experiences of individuals with disabilities, investing in research and development, and fostering a culture of inclusivity and accessibility, we can further push the boundaries of innovation in disability services in Brisbane and create a future where everyone can thrive, regardless of their abilities.
In Conclusion
Innovation is a catalyst for change in the realm of disability services. Through advancements in assistive technologies, digital accessibility, transportation solutions, rehabilitation techniques, inclusive design principles, collaborative partnerships, and co-creation, innovation is revolutionising disability services and promoting inclusivity. By embracing and supporting innovative approaches, we can create a world that provides equal opportunities and empowers individuals with disabilities to live their lives to the fullest.
Source By: The Role of Innovation in Inclusive Disability Services
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Unlocking the Path to Recovery: The Role of Physical Rehabilitation Centers
In a world where injuries, accidents, and medical conditions can strike unexpectedly, physical rehabilitation centers emerge as beacons of hope and healing. These specialized facilities play a pivotal role in assisting individuals on their journey to recovery, helping them regain independence, mobility, and a sense of normalcy in their lives. This article explores the vital role of physical rehabilitation centers in modern healthcare, shedding light on their multifaceted approach and the transformative impact they have on patients' lives.
The Significance of Physical Rehabilitation Centers:
Physical rehabilitation centers serve as comprehensive care hubs for individuals who have experienced various physical setbacks. Whether recovering from a traumatic injury, undergoing post-surgical rehabilitation, managing a chronic condition, or dealing with mobility challenges, these centers cater to a diverse range of patients. Their primary objective is to facilitate recovery through evidence-based therapies, personalized treatment plans, and cutting-edge technology.
Holistic Approach to Rehabilitation:
What sets physical rehabilitation centers apart is their commitment to providing holistic care. They adopt a multidisciplinary approach, bringing together a team of healthcare professionals with different expertise, including physiotherapists, occupational therapists, speech therapists, psychologists, and medical specialists. This collaborative effort ensures that patients receive a well-rounded and tailored treatment plan addressing their unique needs and challenges.
State-of-the-Art Facilities and Technology:
Physical rehabilitation centers invest in the latest medical equipment and technologies to enhance the quality and efficiency of their services. From advanced gait analysis systems and robotic exoskeletons to virtual reality therapy and functional electrical stimulation, these centers leverage cutting-edge innovations to accelerate recovery and optimize patient outcomes.
Empowering Patients Through Education:
Recovery is not solely dependent on therapeutic interventions; education plays a significant role in empowering patients to take an active role in their rehabilitation journey. Physical rehabilitation centers focus on educating patients about their conditions, exercises, and preventive measures. By understanding their bodies better and learning how to manage their conditions independently, patients can continue progress even after leaving the center.
Tailored Treatment Plans:
Each patient's rehabilitation needs are unique, and physical rehabilitation centers understand the importance of personalized care. After conducting thorough assessments, the medical team crafts individualized treatment plans, setting realistic goals and milestones. Regular evaluations and adjustments to the treatment plan ensure that patients' progress is continually monitored and that their therapies remain effective and relevant.
Psychological Support and Mental Health:
The road to recovery can be physically and emotionally demanding. Physical rehabilitation centers recognize the importance of mental health in the healing process. Many centers integrate psychological support into their programs, offering counseling and therapy services to help patients cope with stress, anxiety, and depression that may arise during their rehabilitation journey. A positive mindset and emotional support contribute significantly to overall well-being and successful recovery.
Promoting Independence and Functional Abilities:
The ultimate goal of physical rehabilitation centers is to restore patients' independence and functional abilities. Whether it's relearning essential daily tasks, regaining mobility, or improving communication skills, these centers strive to equip patients with the tools they need to lead fulfilling lives post-recovery.
Support for Caregivers:
Physical rehabilitation centers not only care for patients but also extend their support to caregivers. Caring for a loved one undergoing rehabilitation can be physically and emotionally taxing. These centers offer guidance, education, and respite care to ensure that caregivers have the necessary resources and support to assist their loved ones effectively.
FOR MORE INFO :-
Physical Therapy Clinic
Ankle Physical Therapy
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Revolutionizing Industries: Robotics and Automation
Introduction:
In the realm of technological advancements, few innovations have captured our imagination and transformed industries as profoundly as robotics and automation. From manufacturing and healthcare to agriculture and transportation, robotics and automation have emerged as catalysts for increased efficiency, improved safety, and enhanced productivity. This blog delves into the fascinating world of robotics and automation, exploring their applications, benefits, and potential impact on society.
What is Robotics?
At its core, robotics is the interdisciplinary field that combines engineering, computer science, and other scientific disciplines to design, develop, and deploy robots. A robot, in the context of robotics, is a machine programmed to perform tasks with varying degrees of autonomy. Robots can be physical entities that interact with the physical world or software-based agents that operate in virtual environments.
Applications of Robotics:
Manufacturing: The manufacturing industry has witnessed a profound transformation with the integration of robotics and automation. Robots are now commonly found on assembly lines, performing repetitive tasks with precision and speed. They have enabled increased production rates, improved product quality, and reduced human error, thereby revolutionizing the manufacturing landscape.
Healthcare: Robotics has found a crucial role in healthcare, assisting in surgeries, rehabilitation, and patient care. Surgical robots provide surgeons with enhanced precision and control, resulting in minimally invasive procedures and reduced recovery times. Additionally, robots can perform monotonous tasks such as medication delivery, patient monitoring, and physical assistance, allowing healthcare professionals to focus on critical care.
Agriculture: The agriculture sector has embraced robotics to tackle labor shortages and optimize crop production. Robots equipped with sensors and cameras can autonomously navigate fields, identifying and treating pests, monitoring crop health, and efficiently harvesting crops. This integration of robotics and automation in agriculture promises increased yields, reduced resource usage, and more sustainable farming practices.
Logistics and Transportation: Robotics and automation have revolutionized the logistics and transportation industry. Automated guided vehicles (AGVs) and drones are increasingly used for material handling, warehousing, and last-mile delivery. These technologies enable faster order fulfillment, improved supply chain management, and reduced transportation costs.
Benefits of Automation
Increased Efficiency: Automation eliminates human errors, enhances precision, and accelerates processes. It enables the completion of tasks at a consistent pace without fatigue, significantly boosting overall productivity.
Improved Safety: Robots excel at handling hazardous and repetitive tasks, ensuring the safety of human workers. By delegating dangerous operations to machines, the risk of accidents and injuries can be significantly reduced.
Cost Savings: Although the initial investment in robotics and automation can be substantial, the long-term benefits outweigh the costs. Automation can reduce labor expenses, optimize resource utilization, minimize waste, and enhance operational efficiency, leading to substantial cost savings over time.
Enhanced Quality: Robots perform tasks with high precision and accuracy, resulting in improved product quality and consistency. By reducing human error and variability, automation leads to a higher level of quality control and customer satisfaction.
Societal Impact
While robotics and automation offer numerous benefits, their widespread implementation also raises questions about job displacement and societal implications. It is crucial to adapt to the changing landscape by equipping the workforce with new skills and creating opportunities for human-robot collaboration. By embracing the potential of robotics and automation, society can reap the rewards of increased productivity, economic growth, and a higher quality of life.
As robotics and automation continue to evolve, there is an increasing focus on human-robot collaboration. Rather than replacing jobs, the aim is to augment human capabilities and create new roles that leverage the strengths of both humans and robots. This collaborative approach emphasizes the importance of reskilling and upskilling the workforce to adapt to the changing demands of the modern workplace.
Furthermore, the integration of robotics and automation can lead to the creation of entirely new industries and job opportunities. As technology advances, there will be a growing need for skilled professionals in robotics engineering, programming, maintenance, and supervision. By embracing these emerging fields, individuals can position themselves for rewarding careers in the robotics industry.
Additionally, robotics and automation can have positive societal impacts beyond the realm of work. In healthcare, robots can support aging populations by providing assistance with daily tasks, monitoring vital signs, and offering companionship. In disaster scenarios, robots can be deployed to navigate hazardous environments and perform search and rescue operations, potentially saving lives.
Ethical considerations also come into play with the increasing autonomy of robots. As robots become more capable of decision-making and independent action, it becomes essential to establish guidelines and frameworks to ensure their responsible use. This includes addressing issues such as privacy, security, and accountability to prevent misuse or unintended consequences.
In conclusion, robotics and automation are reshaping industries and revolutionizing the way we work. With their ability to enhance efficiency, improve safety, and drive innovation, these technologies have the potential to unlock new possibilities and drive economic growth. It is crucial for businesses, governments, and society at large to embrace these advancements responsibly, taking into account the needs of the workforce and the ethical implications. By doing so, we can harness the full potential of robotics and automation to create a brighter and more prosperous future.
Furthermore, the integration of robotics and automation has the potential to address some of the pressing challenges faced by society. For instance, in the field of environmental sustainability, robots can play a crucial role in tasks such as waste management, pollution monitoring, and renewable energy production. By automating these processes, we can reduce our ecological footprint and work towards a more sustainable future.
Moreover, robotics and automation have the potential to enhance accessibility and inclusivity. Assistive robots can assist individuals with disabilities in their daily tasks, providing them with greater independence and improving their quality of life. Similarly, automation can help bridge the digital divide by enabling access to technology and educational resources in remote or underserved areas.
However, it is essential to acknowledge and address the potential challenges that come with the widespread adoption of robotics and automation. One of the primary concerns is job displacement, as certain tasks previously performed by humans are automated. It is crucial to support affected workers through retraining programs and ensure a smooth transition to new roles and industries.
Additionally, the ethical implications of robotics and automation must be carefully considered. Questions regarding privacy, data security, and the potential for bias in algorithms need to be addressed to ensure responsible and fair use of these technologies. Transparency, accountability, and regulations play a vital role in establishing guidelines for the development and deployment of robotic systems.
Collaboration and interdisciplinary approaches are key to realizing the full potential of robotics and automation. Engineers, computer scientists, policymakers, ethicists, and social scientists must work together to navigate the challenges and maximize the benefits of these technologies. This collaboration can foster innovation, promote responsible practices, and shape the future of robotics and automation in a way that aligns with human values and societal needs.
Certainly! Here are some key points summarizing about Robotics and Automation:
Robotics and automation have revolutionized industries, bringing increased efficiency, improved safety, and enhanced productivity.
Applications of robotics include manufacturing, healthcare, agriculture, and logistics, among others.
Benefits of automation include increased efficiency, improved safety, cost savings, and enhanced quality control.
The societal impact of robotics and automation raises concerns about job displacement and ethical considerations.
Human-robot collaboration is essential to maximize the benefits of automation and create new job opportunities.
Robotics and automation can have positive impacts beyond work, such as in healthcare and disaster response.
Responsible use of robotics and automation involves addressing ethical implications and establishing guidelines.
Integration of robotics and automation can address challenges related to sustainability and accessibility.
Collaboration among professionals from various disciplines is crucial for navigating challenges and maximizing benefits.
By embracing robotics and automation responsibly, we can shape a better and technologically advanced future.
Conclusion
Robotics and automation have revolutionized various industries, empowering businesses to achieve new levels of efficiency, productivity, and safety. From manufacturing and healthcare to agriculture and transportation, the integration of robots has transformed traditional practices, opening doors to unprecedented possibilities. While the future of robotics and automation holds great promise, it is essential to approach this technological advancement thoughtfully, ensuring a balance between the benefits of automation and the well-being of the workforce and society as a whole.
In conclusion, robotics and automation are driving significant transformations across various industries, revolutionizing the way we live and work. While there are challenges to overcome, the potential benefits are immense. By harnessing the power of robotics and automation responsibly, we can improve efficiency, enhance safety, address environmental concerns, and promote inclusivity. It is an exciting time for robotics and automation, and the journey ahead holds tremendous promise for shaping a better and more technologically advanced world.
FAQ’s?
1. What is the difference between robotics and automation?
Robotics refers to the interdisciplinary field that deals with the design, development, and deployment of robots, while automation is the process of using technology to perform tasks without human intervention. Robotics often involves the integration of automation technologies to create autonomous or semi-autonomous systems.
2. Will robots replace human workers in the future?
While some tasks previously performed by humans may be automated, the widespread belief is that robots will augment human capabilities rather than replace humans entirely. Collaborative approaches that combine the strengths of humans and robots are more likely to emerge, creating new job opportunities and increasing overall productivity.
3. How do robotics and automation impact job opportunities?
The integration of robotics and automation may lead to the transformation of certain job roles. While some tasks may become automated, new roles will emerge in areas such as robotics engineering, programming, maintenance, supervision, and human-robot collaboration. Upskilling and reskilling programs can help individuals adapt to these changing job demands.
4. How can robotics and automation contribute to sustainability?
Robotics and automation can contribute to sustainability by optimizing resource usage, reducing waste, and addressing environmental challenges. In industries like agriculture, robotics can enable precise application of resources, leading to more efficient and sustainable farming practices. Additionally, automation can help monitor and manage energy consumption, waste management, and pollution control.
5. What are some challenges in the adoption of robotics and automation?
Challenges include the initial investment cost, retraining the workforce for new roles, addressing job displacement concerns, and ensuring the responsible and ethical use of the technology. Collaboration between stakeholders, including businesses, policymakers, and academia, is crucial for overcoming these challenges and maximizing the benefits of robotics and automation.
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‘TherapeiaVR,’ Pain-Management System That Uses VR to Distract Patients
‘TherapeiaVR,’ Pain-Management System That Uses VR to Distract Patients.
Evidence-based therapy has enabled anesthesia-free medical procedures in clinical trials.
LAS VEGAS (Dec. 27, 2022) - At CES® 2023 (Jan. 5-8), xCura, a Japanese health-tech startup, will showcase “TherapeiaVR,” a pain management system that uses VR contents to take patients’ minds away from what’s happening to their bodies, effectively reducing or eliminating the need to use anesthesia and/or pain medication. Developed by the company’s founder & CEO Yuichiro Niijima using his years of experience as a hypnotherapist, “TherapeiaVR” was released on Dec. 2 in Japan following the successful clinical trials across the country, in which both patients and clinicians reported the system’s effectiveness in helping patients manage their fear and pain during dental procedures, gastroscopy, and various other procedures.
“Taking anesthesia and strong pain medication can take heavy tolls on one’s body, in some cases leading
to long-term problems, such as addiction. As a non-pharmaceutical approach to pain management,
‘TherapeiaVR’ can help reduce these problems,” Niijima said. “TherapeaiVR’s VR content combines
evidence-based psychotherapy methods with VR technology, measuring physical signs of pain while
guiding patients to follow specific breathing techniques. We are thrilled to introduce this innovative pain
reduction system at CES 2023.”
How It Works:
- Therapy consists of a VR app and VR goggles. VR content varies, depending on what types of medical procedures it is used for. (In some videos, patients would virtually walk through the forest, space, etc.)
- VR is designed to visually guide the patients to breathe in certain tempos to engender parasympathetic dominance in their bodies, allowing their bodies and minds to relax, while VR narration helps them perform autogenic training (a self-induced calming and relaxation method) and progressive muscle relaxation method to reduce their anxiety and pain.
- Throughout a procedure, TherapeiaVR keeps track of the size of patients’ pupils and the frequency of pupil dilation, as the pupil dilates when one is feeling pain.
- Simple operation. Only requires users to plug in the system and turn it on.
- TherapeiaVR could be used as a pain management tool in procedures and treatments in ophthalmology, obstetrics, nephrology, orthopedics, anesthesiology, psychiatry, rehabilitation, among others.
- • Scheduled for a release in Indonesia and Finland in April 2023.
About xCura
xCura is a Japanese health-tech startup with a mission to reduce people’s sufferings through
innovative use of technology. The company develops pain-management systems that use VR to ease
patients’ fear and pain during medical procedures.
Presented by the Japan External Trade Organization (JETRO), the “Japan (J-Startup) Pavilion @Eureka
Park” brings together the country’s innovative startups with proprietary leading-edge technologies. At
CES 2023, the pavilion will feature 36 companies in industries ranging from AI to robotics, space to
mobility, among others.
CES® is one of the world’s largest technology trade shows held annually in Las Vegas. Bringing together
2,279 exhibitors and 84,500 attendees between Las Vegas and online venues at CES 2022, the event is
billed as the “the proving ground for breakthrough technologies and global innovators.” At CES 2020
held prior to the COVID-19 pandemic, 4,600 companies showcased 20,000 products and services.
Read the full article
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Robo-boot concept promises 50% faster running
by David Braun
The old idea of running with springs on your feet gets a high-tech makeover. Krisztina Braun
No matter how well designed, there are no running shoes that allow runners to keep up with cyclists. The bicycle was a key invention that doubled human-powered speed. But what if a new kind of shoe could allow people to run faster by mimicking cycling mechanics?
This is the question my students in Vanderbilt’s Center for Rehabilitation Engineering & Assistive Technology and I explored as we developed a new theory of spring-driven robotic exoskeletons. We came up with a concept for a new type of lower limb exoskeleton that could allow the world’s fastest human to reach a speed of 18 meters per second or about 40 miles per hour.
Robo-boots allow the legs to supply energy in the air during running, similar to the pedaling mechanism in cycling. A. Sutrisno and D. J. Braun, CC BY-ND
The cutting edge of today’s running shoes is Nike’s Vaporfly, which allows runners to use 4% less energy than standard running shoes. Three-time Olympic medalist Eliud Kipchoge recently wore them to run a marathon in under two hours. Though the Vaporfly upended the world of professional running by increasing the efficiency of standard running shoes, it doesn’t provide the advantages of cycling or otherwise fundamentally alter the physics of running.
There has been a lot of research and development in robotic exoskeletons that augment human power. These use actuators and external energy: motors and batteries. But they haven’t helped humans run faster. Springs have also been used to make high-tech prostheses for paralympic running, but have not been shown to provide an unfair advantage compared to legs. For human-powered speed, the bicycle has been the reigning champion for over a century.
Running versus cycling
The precursor to the modern bicycle, dubbed the hobby horse, was invented in 1817 by Baron Karl von Drais. Canada Science and Technology Museum/Flickr, CC BY-NC-ND
The first running machine was a bicycle with no pedals. It reduced the energy cost of running by supporting the body’s weight on a seat and using wheels to avoid the inevitable energy loss when runners step.
But early bicycles did not allow cyclists to move faster than runners because the rider propelled himself by pushing against the ground with his legs – just like running. What changed the game for bicycling was the invention of the pedaling mechanism, which allowed the legs to propel the rider continuously rather than only when the foot hits the ground.
In 1890, Nicolas Yagn invented a spring-leg that supported the weight of a person’s body. USPTO
The bicycle’s speed advantage over running has not endured for lack of trying. People have been imagining spring legs and refining running springs for generations, but these springs are not like a bicycle with pedals because they don’t allow the legs to supply energy when they’re off the ground.
The robo-boot
To apply the advantage of cycling to running, we came up with a concept for a new type of robo-boot that emulates the function of bicycle pedals. Using the robo-boot, runners supply energy by compressing a spring with each leg while it’s in the air. With each footstep, the spring releases its stored energy by pushing against the ground faster and stronger than the legs could otherwise do.
We found that an ideal robo-boot would allow the fastest runner on Earth to use his legs 96% of the step time to run faster than 20 meters per second, comparable to the top speed of cycling. A more practical robo-boot that is used only about 60% of the step time could still help a runner reach a top speed of 18 meters per second. That’s 50% faster than the world record speed of 12 meters per second in the 100 meter sprint.
Top speed of human-powered locomotion. Adapted from A. Sutrisno, D. J. Braun, How to run 50% faster without external energy, vol. 6, no. 13, eaay1950, 2020., CC BY-ND
The high-tech component of the robo-boot is a variable stiffness spring that can increase its stiffness without changing its stored energy. The stiffness of the spring determines how forcefully it can push against the ground to accelerate the runner’s body – the stiffer the spring, the greater the force given the same spring compression.
Conventional springs like those in retractable pens have a constant stiffness based on the spring’s material, shape and size. Variable stiffness springs are a special type of spring that can change shape or size. One type of variable stiffness spring increases stiffness by getting shorter. A mechanism shortens the spring by moving the spring’s attachment point from its end to its middle. The mechanism in the robo-boot shortens the spring as the runner extends her leg in the air.
Running with robo-boots. Adapted from A. Sutrisno, D. J. Braun, How to run 50% faster without external energy, vol. 6, no. 13, eaay1950, 2020., CC BY-ND
Increasing the stiffness of the spring as the runner picks up speed is analogous to switching to a higher gear on a bike as a cyclist rides faster. This allows runners to supply more energy and bypass the biomechanical limitation of supplying energy only during the short ground contact time of high-speed running.
Next steps
Modern racing bikes nearly double the top speed of running. Robo-boots that leverage bicycle mechanics could similarly allow people to run faster without hefty motors and batteries. We hope to have an initial robo-boot prototype within a year. But just as it took many years after their invention for bicycles to take full advantage of their unique mechanics, it will take some time to make a robo-boot that can achieve its full potential.
These more portable human-powered devices could enable more widespread adoption of wearable robotic technology, and could push the boundaries of search and rescue, law enforcement and sports. What would it mean for first responders to be able to move 50% faster? Would a running shoe that provides a 50% speed increase lead to a new event at the Olympics similar to ice skating and bicycle racing?
Using science and advanced robotics technology, we’re able to envision next generation robo-boots that offer the first major boost to human-powered movement since the invention of the bicycle pedal in the 19th century.
About The Author
David Braun is an Assistant Professor of Mechanical Engineering and Computer Engineering at Vanderbilt University
This article is republished from our content partners over at The Conversation under a Creative Commons license.
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The Stunning Beauty of Anthropology Within Horizon: Zero Dawn
Part 1 of ?: The Evolution of the Stories of Their Origin and the Collective Human Subconscious
“...oral tradition was never the other we accused it of being; it was never the primitive, preliminary technology of communication we thought it to be. Rather, if the whole truth is told, oral tradition stands out as the single most dominant communicative technology of our species as both a historical fact and, in many areas still, a contemporary reality.”
John Foley, Signs of Orality
Horizon: Zero Dawn, put as simply as possible, is a post-apocalyptic game about a young female trying to find the truth of who her mother is. Delve just a little deeper, however, and any player will find a rich world full of cultural signficance with a storied history.
This will contain spoilers for the game Horizon: Zero Dawn and its DLC, the Frozen Wilds.
To figure out how the oral traditions of the tribes seen in Horzion: Zero Dawn—the Nora, the Carja, the Banuk, and the Oseram—evolved, we first need to see where they ended up. At the start of the game, the player controls a protagonist by the name of Aloy. She’s a young woman starting out with one goal in mind: find out who her mother is. In the tribe she belongs to, the Nora, motherhood and childbirth are considered the holiest of acts. To be unaware of who your mother is (to be “motherless,” as Aloy is refered to in the game) is to be an outcast to the tribe.
Early gameplay will teach the player a bit about the culture of the Nora. For one, Aloy is an outcast, and was raised by an outcast—a man named Rost—from birth. The tribe are not to speak to them, to trade with them, and outcasts are not meant to speak to each other. This, of course, is with the exception of Rost and Aloy.
The first instance the player sees of the Nora’s oral traditions come during the quest Mother’s Heart, in which Aloy ventures into the Nora’s largest village for the first time in her life. It’s here that we the player first hears the story of the origin of the Nora, as told by one of the Nora’s leaders: a matriarch, a woman who has at least two generations beneath her (making her the grandmother to the youngest generation).
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The Metal Devil, as it’s referred to in the matriarch’s story, does in fact sit upon the mountain that the Nora call All-Mother.
So, how did this origin story of the Nora evolve? For the player to understand this, they must venture far into the story of the game.
To make an incredibly long story short: a man named Ted Faro created a line of intelligent, self-replicating and self-reparing, virtually unhackable robots to take over the fighting in the world’s increasingly hostile environment. These robots were capable of, in times of emergency, utilizing a function to consume biomass for creation into biofuel. A glitch in the system controlling these robots released them from their functions, and they began attacking humans and using this biofuel creation. A scientist by the name of Elisabet Sobeck estimated that all life on Earth—plants, animals, and even humans—would be extinct within 16 months.
This is the chain of events that would lead to the eventual creation of Project Zero Dawn. With no way to shut the swarm down before Earth’s extinction, Sobeck gathered the brightest minds from across the globe in an effort to preserve as much of the world as possible. This would only be possible with the help of an extremely advanced system piloted by a highly sophisticated artificial intelligence. And so, GAIA was born along with several subfunctions that would help her bring life back to a barren planet. However, in a last ditch effort by Ted Faro to save the future generation of humans from the knowledge of the pre-extinction world, the subfunction APOLLO was purged from the system.
Despite the loss of APOLLO, GAIA would continue to function as intended. The subfunction MINVERA cracked the codes to permanently shut down the swarm that ended the world. This opened up the rest of GAIA’s subfunctions—AETHER, ARTEMIS, DEMETER, HEPHAESTUS, and POSEIDON—to begin the greuling task of rehabilitating the Earth to make it liveable for humans once again by using robots. When this task was considered complete, the ELEUTHIA function was activated, birthing the first new generation of humans from inside artificial wombs stored in cradle facilities across the glob. These babies would be raised by android caretakers until they were eventually let outside.
Due to the loss of the APOLLO system, this first generation of humans post-Zero Day received only an elementary-level of education. They were provided with no information of what transpired prior to their birth, and were led out into a world where terraforming robots were the dominant species.
So, how did this story end up being represented in the Nora’s origin story?
All-Mother was the name given to the cradle facility, built into a mountain, from which the first humans exited. That part is the easiest to decipher. It comes to reason that this first generation of humans would also believe that every living thing came from within the facility, since they knew that they did at least. That covers the first part of the story.
The cradle facility that the first generation emerged from was built into what is theorized to be Cheyenne Mountain in Colorado (based on information that the main character, Aloy, learns through the game). From this facility, the first generation would have to explore the world. They would eventually find the ruins of what used to be Colorado Springs and the surrounding cities. It stands to reason that they would believe whoever had been here before them had seriously messed up, and that these ruins were all that remained. Take into account the massive machine atop their mountain, and the fact that humans as a species tend to fill in the blanks where they can, a story began to take shape.
The faithless would have to be those who were no longer around, those who had built the cities of metal that eventually fell. The machine above their mountain was made of the same metal, so the first generation of humans came to reason that the fall of the old world would be linked to this machine. Over time, the humans that would become the Nora tribe forgot what was inside the mountain that they worshiped. They would forget the android caretakers, the metal walls within the mountain that had once been their home.
Also interesting enough to note, however, is that the story the Nora have isn’t entirely different from what happened. The machine they call a “Metal Devil” was one of Ted Faro’s robotic creations. It did want all things to serve him, but not in the way they might believe. Instead, it wanted all things to serve him as a source for his biofuel. This brings us to the idea of a collective human subconscious—the idea that, as a species, there are certain things so pivitol in our history that it’s impossible for us to forget it.
Other tribes within Horizon Zero Dawn have origin stories that are similar but not exact, but they do contain elements of truths to them. The Oseram, for example, believe that the world is one large machine and that those that came before them failed to take care of it. As such, they died. This isn’t untrue, as it could be said that pre-extinction humans did fail to care for the Earth by engaging in wars that made the market for Ted Faro’s robots recessary.
The Carja, on another hand, worship the sun as their prime deity and also recognize the existence of a counter diety, the “Buried Shadow.” Their religion says that the Buried Shadow destroyed the world of the Old Ones (a name given to the pre-extinction humans), which will one day rise again and destroy the Carja as well. However, in the same way that the sun rises every morning, a new society will also rise after the Carja. This also has elements of truth to it, and it’s important to note that the Carja tribe developed from a group of Nora who found and learned to read a book preserved within the ruins. Perhaps the Buried Shadow referred to in Carja mythology refers to the machine half-buried in dirt and snow atop the Nora’s main mountain.
The tribes of Horzion: Zero Dawn are the product of a highly sophistiaced artificial intelligence who were thrust into a world with no knowledge of what came before. However, the myths of their origins each hold elements of truth to them, truths that they would have had no way of discovering on their own. It’s possible that through a phenomenon known as the collective human subconscious that these new humans created stories from the memory of devestation too large for the human species to ever truly forget.
#horizon zero dawn#not kpop#hey! heres the first of some super nerdy stuff#this doesnt get really technical bc i dont think it needs to but#if you're interested in this i HIGHLY recommend you do some research into the collective human subconscious
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Rehabilitations Robotics Market Key Players Analysis, Size, Growth, Trends and Forecast up to 2023
Rehabilitation robotics has achieved burgeoning importance in the healthcare industry in terms of societal and economic benefits. The introduction of this promising technology has revolutionized the field of physical disabilities, by decreasing the burden on trainers and making the life of physically disabled patients easier.
The rehabilitation robotics market is likely to witness lucrative growth in the coming years owing to the increase in proportion of older people. According to National Institutes of Health, the proportion of people aged 65 years and above will increase to 17% of world’s population by 2050 from 8.5% in 2015. This demographic shift will create a significant increase in demand for elder-care services such as robots that can assist with the care and support of the older populations and the disabled.
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Rising prevalence of stroke worldwide is a significant factor driving the growth of rehabilitation robotics market. Stroke is the leading cause of disabilities in the western countries. Each year, 15 million people around the globe suffer a stroke. Nearly six million die and another five million are left permanently disabled. Rehabilitation robotic systems are able to identify and assess dynamic movements as well as coordination disorders, thus support the training given by physical therapists. There is a further growing market need for such better robotic solutions for rehabilitation.
Various notable players operating the rehabilitation robotics market include Ekso Bionics, Alter G, Hocoma, Kinova, ReWalk Robotics, Interactive Motion Technologies, Myomo, Inc, Rehab-Robotics Co. Ltd. , and Honda Motor among others.
The global rehabilitation robotics market has been segmented on the basis of type, application, and key geographies. Based on type, the market comprises of Assistive Robots, Therapeutic Robots, Prosthetics, Exoskeleton Robotic Systems, and Orthotics. On the basis of application, the market is segmented into Neurorehabilitation, Orthopaedics, Cognitive & Motor Skills, and Sports
This research report on rehabilitation robotics market provides in-depth analysis of the global rehabilitation robotics market based on type, application, and major geographies for the forecast period from 2018 to 2025. The report highlights the major market drivers propelling the growth as well as challenges faced by market participants. The research report provides market size and forecast for rehabilitation robotics market. The report also analyses the competitive landscape, major players and their strategies in 2018. The competitive landscape section of the report captures and highlights the recent development in the market.
Key questions answered in this research report:
1. At what pace is rehabilitation robotics market growing? What will be growth trend in future?
2. What are the key drivers and restraints in the current market? What will be the impact of drivers and restraints in the future?
3. What are the regional revenue and forecast breakdowns? Which are the major regional revenue pockets for growth in the rehabilitation robotics market?
4. What are the various application areas and how they are poised to grow?
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The global rehabilitation robotics market is segmented on the basis of type, application, and geography:
Global Rehabilitation Robotics Market by Type
· Assistive Robots
· Prosthetics
· Orthotics
· Therapeutic Robots
· Exoskeleton Robotic Systems
Global Rehabilitation Robotics Market by Application
· Neurorehabilitation
· Orthopaedics
· Cognitive & Motor Skills
· Sports
Global Rehabilitation Robotics Market by Geography
· North America
· Asia-Pacific
· Europe
· Rest of World
Global Rehabilitation Robotics Market Competitive Landscape
· Major Players and their Key Strategies
· New product launches
· Mergers and acquisitions
· Collaborations, partnerships, agreements and joint venture
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Medical Robots Market Trends Forecast and Industry Analysis to 2030
Global Medical Robots Market: Snapshot
Computer-assisted surgery or robotically assisted surgery or robotic surgery are the terms that are being used for the technological development that employs a robotic systems to assist in various surgical procedures. Robot assisted surgeries came into place to augment the capabilities of surgeons performing open surgeries on a patient or to deal with the limitations of already existing procedures of minimally-invasive surgeries.
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In minimally-invasive surgeries, surgeons make use of one or two methods to direct the instruments, instead of directly moving the instruments himself. He either makes use of a computer or a telemanipulator to control and move the instruments that are being used there. A telemanipulator is being defined as a distant manipulator that enables the surgeon to accomplish normal movements that pertaining to the surgery. On the other hand, a robotic arm is used to perform those movements making use of manipulators and end-effectors to execute surgery on the patient. In computer control systems, the surgeon makes use of a computer to regulate the end-effectors and the robotic arms that are being used for the surgery. One advantage of such surgeries are that the surgeon could be present at any location of the world, he does not necessarily need to be present there at the operation theatre (OT) to perform the operation thereby resulting in possibility of remote surgery
However, all is not rosy with the deployment of robots in the medical industry. Robotic surgeries are quite often criticized for being too expensive. They also require very high-end technical know-how to assist in surgeries.
Global Medical Robots Market: Overview
Medical robots comprise the use of robotics in various disciplines of medical science to execute a variety of functions performed by clinicians and healthcare workers. Requiring limited human oversights, they can be configured to support, extend, and automate various healthcare services, especially those involving monotonous tasks. The rising application of robotic and autonomous systems in the healthcare industry has transformed the quality of medical treatment making their use increasingly popular worldwide.
The spiraling demand for medical robots in areas of disease diagnosis, treatment, and prevention is propelled by the marked dexterity with which they perform various tasks. The successful use of robotic technology for a range of complex tasks such as targeted drug deliveries, precision surgeries, decontamination of healthcare spaces, and detection of biological targets has paved the way for commercial applications of medical robots.
Global Medical Robots Market: Trends
The enormous benefits of robot-assisted training in rehabilitation therapy, soaring governmental funding for robotics in developed regions, and constant technological advances in the medical industry are the factors propelling the growth of the medical robots market. The rising application of robots in hospitals worldwide to carry out various tasks that call for extreme precision and unmatched promptness has spurred the demand for medical robots.
Over the past few decades, medical robots have gained traction among surgeons for performing complex and non-invasive surgeries in different medical specialties, particularly urology and neurosurgery. However, a host of emerging legal and ethical concerns related to robotic surgeries, coupled with the high cost of robotic systems, is likely to restrain the market. Nevertheless, concerned stakeholders, including leading regulatory agencies, are actively taking initiatives to address various patient safety concerns. The substantial benefits of boosting surgical outcomes have kept a large number of surgeons ebullient of the promising avenues emanating in the market.
Global Medical Robots Market: Market Potential
Curexo Inc., a Korea-based manufacturer of medical devices and an importer of surgical robots, has recently acquired medical robots division of Hyundai Heavy Industries for a sum of 11.1 billion won (approximately $9.9 million). With this, Curexo intends to lead the regional medical robots market by expanding its product portfolio by including robots for the purpose of rehabilitation, patient care, and other healthcare operations. The leading shipbuilding company will become the second largest shareholder of Curexo with a significant stake of 6.7%. Previously, the shipbuilder has developed medical robots for a variety of tasks such as patient-handling, endovascular therapies robots, and orthopedic surgeries.
In an another encouraging market development that will spur the investment to the development of medical robots, Myomo Inc., a orthotics and prosthetics service company based in Massachusetts, has recently announced a crowdfunding campaign through an online brokerage which will enable it to sell shares in an initial public offering (IPO). The start-up, founded in 2004, actively markets braces and other similar medical devices for people suffering from neurological disorders and upper-limb paralysis. The issuance of IPO will allow a large number of individual investors—ordinary and institutional investors—participate in IPOs. As a result, the medical device manufacturer hopes to raise a whopping sum of $15 million before it begins trading on NYSE by the end of April, 2017.
Medical Robots Market: Regional Outlook
North America is a prominent market for medical robots. Europe and Asia Pacific markets contribute significant shares in the global medical robots market. Asia Pacific is anticipated to register an impressive CAGR along the forecast period. The spiraling demand for medical robots is driven by staggering rise in the number of regulatory approvals of robots to be used in various medical areas in Japan. In addition, the increasing prevalence of various cancer types in China, and growing popularity of robotic-assisted procedures in hospitals in India are expected to fuel the market. Furthermore, the increasing collaborations between various stakeholders in emerging nations of Asia has propelled the regional market.
Medical Robots Market: Competitive Analysis
The global medical robots market is highly competitive and fragmented with the presence of several small and medium- scale companies competing against each other and with a handful of large players. Among the intense rivalry, major players eyeing a significant share in this market include Intuitive Surgical, Inc., Mazor Robotics Ltd., Stryker Corporation, Hocoma AG, Hansen Medical Inc., Omnicell, Inc., Accuray Incorporated, Ekso Bionics Holdings, Inc., and Kirby Lester LLC.
Key questions answered in this report
What are the diverse growth parameters influencing the market?
Which regions will contribute largely to the growth of the market
What are the recent innovations and technological advancements in the market?
What are the emerging trends across the market?
How has COVID-19 affected the market?
What will be the post-pandemic scenario of the market?
What are the major threats that will dent the growth prospects of the market?
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Robotic Wheelchairs Market Size Worth $142.6 Million By 2025 | Global and Regional Forecast | Grand View Research, Inc.
The global robotic wheelchairs market size is expected to reach a value of USD 142.6 million by 2025, according to a new report by Grand View Research, Inc., expanding at a CAGR of 9.4% over the forecast period. Growing need for independent mobility assistance by the geriatric population with moving disabilities is expected to drive the market. Moreover, rising spending power among the consumers, along with introduction of technologically advanced mobility products by the companies, is expected to drive the market.
Growing penetration of robotic wheelchairs as an artificial assistance due to advanced features such as navigation, detecting obstacles, sensor technology, and artificial intelligence. Presence of people with physical ailments or loss of mental control is expected to increase the demand in the market. According to the Journal of Rehabilitation Research and Development, the NavChair is an assistive navigation system developed with a mobile robot i.e. vector field histogram to avoid obstacles, follow walls, and travel safely.
In 2018, the residential application segment held the largest share of 82.9%. Application of manual wheelchairs for daily life activities increases the dependency level on others. For instance, Toyota, as a part of an agreement with DEKA Research and Development, is making the iBot wheelchairs for climbing stairs. The commercial application segment is expected to expand at a CAGR of 10.8% over the forecast period. Smart future urban mobility research group developed smart wheelchairs that can be used at airports and hospitals.
Retail distribution held the largest share of 82.5% in 2018. Reliability of the product is considered to be high in retail stores than other modes of distribution channel. In addition, e-commerce distribution mode is expected to register the fastest CAGR of 11.0% over the forecast period. Ease of accessibility throughout the world for the best smart wheelchairs is a key factor expected to drive the channel over the forecast period. Many companies have their own online platforms and some of them are tying up with others.
North America emerged as the largest regional market with a value of USD 25.0 million in 2018. The region is expected to maintain its lead over the forecast period. Reimbursement of insurance claims, growing aging population, and technological advancements are driving the market. For instance, Massachusetts scientist, Matt Walter and PhD candidate, Sachi Hemachandra launched a voice controlled robotic wheelchair for elder care. Similarly, Invacare Corporation launched a wheelchair with a special technology called G-trac technology for better control system.
Companies are integrating with universities and startups to develop something advance to cater to the needs of the vast consumer base. For instance, Intel collaborated with Brazilian startup Hoobox Robotics to develop a smart wheelchair “wheelie”, which has an access to read facial expressions as human behavior.
Key players in the market include Sunrise Medical LLC; Invacare Corporation; Permobil Corporation; Meyra GmbH; Karman Healthcare; Ottobock SE& Company; Matia Robotics; Upnride Robotics; DEKA Research & Development; and Whill Inc.
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