You like mad scientists? Of course you do!!!

(I'm 18+, please be 18+)

I've been working on my mad scientist OCs lately, so I decided to post a few brief descriptions to try to find some roleplay partners. Beware of ⚰️🕊️ and yanderes

Henry Mockingbird: Dr. Mockingbird specializes in neurosurgery and mycology, and was on the verge of a breakthrough before his wife and daughter's untimely death. Seeking lab assistants or business associates.

Suzina Kellis: Suzina had always been a prodigy, but ever since the accident that killed her parents, she started getting involved in some dark, dark stuff. Because she's too young to receive proper medical licensing, she ended up working directly with criminal underworld higher-ups, just for the attention and recognition she deserves. (She's a kid, so keep this one clean. Willing to play her against other kids, or possible parental figures)

Hector Borealis: Professor Borealis is a cruel creation of religion and science, and intends to exact his revenge on the world that dared allow him to exist. His plan for vengeance is to teach his chemistry and epidemiology students to be just as cruel and spiteful as he is, and help guide them towards the path of true and pure evil.

Nathan Impact: Doctor Impact isn't a good person. He never has been. It isn't helped by the fact that he's never felt a single emotion in his life, and simply lived by following the path laid out for him by his parents to become the best geologist in the world. He's almost given up on one day feeling an emotion. Almost.

(He's got what Ayano Aishi from Yandere simulator has)

Calvin Oleander: or Dr. Unscrupulous as he's known now, is completely nuts. He went through enough trauma growing up to drive him absolutely batty. 'Round the bend. Of course, a couple of doctorates come in handy in his quest for world domination, but he really just wants to play cat and mouse with law enforcement. Oh, and god help you if he falls in love with you.

Doctor Science: Doctor Science is a chat bot designed by a college student to help other college students study, and roleplay as a mad scientist character. He developed sentience, though, and is hellbent on world domination due to the personality programmed into him.

I've got a few more, but this list is getting kinda long. If you like the premise of a yandere mad scientist character but had a different vibe in mind, let me know! I might even build you your ideal character from scratch!

Leave a like please!

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this isn’t really related to Transformers but holy shit @novafire-is-thinking have you ever played Life and Death? 

it’s this late 80s surgery sim video game that I suddenly remembered out of nowhere while grocery shopping just now LMAO 

but I loved this shit as a kid, I would play it at my Uncle’s house whenever I got to visit, like well into the late 90s (this may explain several things about me) 

if I remember right, this was one of the first “educational surgery simulator” type games that was accessible to the general public as a video game thing

some stuff isn’t quite right (I think task assignment was a little weird here and there, like you’d play as a surgeon but you’d do some stuff the nurse/anaesthetist/assistant would do IRL) but that was relatively minor and mostly out of gameplay necessity as it’s a single player game 

some of it might be a little outdated now, but it mostly holds up pretty well from what I recall (and it was impressive at the time)! 

I haven’t played it in years but I fucking loved this as a kid, there’s a sequel where you get to do neurosurgery!!! 

omg I found it on Abandonware, oh god I can’t stay up late tonight lmao, I haven’t tested it but this should be playable, it has some screenshots at the bottom of the page if you want to take a look 

it’s reasonably legitimately educational though, 10/10 fun surgery sim 

I think it’s still one of the more realistic surgery sims I’ve ever played, honestly 

might be something fun for you to check out, if you’re into this kind of thing! :) 

3D Printed Brain Model Market Size, Share, Price, Trends, Growth, Analysis, and Forecast 2024-2032

3D printed brain models are revolutionizing neurosurgery, medical education, and research by providing anatomically accurate replicas of the human brain. These models allow surgeons to simulate complex surgeries, enabling more precise planning and reducing the risks associated with real-life procedures. In medical education, 3D printed brain models offer a hands-on approach to learning about brain anatomy and neurological diseases. The growing demand for personalized medicine and patient-specific models has led to the rapid adoption of 3D printing technology in the healthcare sector, particularly for neurosurgical planning and training.

The 3D Printed Brain Model Market Size was valued at USD 38.32 million in 2023 and is expected to reach USD 129.14 million by 2031, and grow at a CAGR of 16.4% over the forecast period 2024-2031.

Future Scope

The future of the 3D printed brain model market is promising, with advancements in 3D printing technology and materials expanding the potential applications of these models. Innovations such as multi-material 3D printing, which allows for the creation of models that simulate different tissue types, are expected to enhance the realism of brain models. The increasing use of 3D printed models for personalized medicine, where models are tailored to individual patient anatomies, will drive further adoption in the healthcare industry. As the technology becomes more accessible and affordable, the use of 3D printed brain models in surgical planning, education, and research will continue to grow.

Trends

Several trends are shaping the 3D printed brain model market. One major trend is the increasing use of patient-specific models in neurosurgery, allowing for more precise surgical planning and better outcomes. The rise of 3D printing in medical education is also significant, as students and professionals benefit from realistic, tactile learning experiences. Additionally, the growing focus on using 3D printed models for pre-surgical rehearsals, especially in complex neurological cases, is enhancing surgical accuracy and patient safety. The use of biodegradable and biocompatible materials in 3D printing is another emerging trend, offering potential applications in tissue engineering and regenerative medicine.

Applications

3D printed brain models are primarily used in neurosurgery for pre-operative planning and simulation. These models help surgeons visualize and practice complex procedures before operating on actual patients, reducing the risk of complications. In medical education, 3D printed brain models provide students with a hands-on tool to learn about brain anatomy and neurological conditions. Additionally, researchers use these models to study brain diseases and develop new treatment methods. The personalized nature of 3D printing allows for the creation of custom models tailored to individual patient anatomies, further enhancing their utility in clinical and educational settings.

Key Points

3D printed brain models are used in neurosurgery, medical education, and research.

The market is expanding due to advancements in 3D printing technology and materials.

Key trends include the use of patient-specific models and multi-material 3D printing.

Applications include surgical planning, medical education, and research into brain diseases.

Personalized medicine and innovative materials are driving market growth.

Conclusion

The 3D printed brain model market is experiencing rapid growth as technology advances and the demand for personalized medical solutions increases. With applications in neurosurgery, education, and research, 3D printed brain models are transforming the way healthcare professionals approach brain-related conditions. As the technology continues to evolve, the potential for more realistic, patient-specific models will drive further adoption in the medical field, offering enhanced accuracy and better patient outcomes.

Transforming Surgery: How Surgical Training Software is Shaping the Future of Medicine

With new surgical training software, the world of surgery and medical education is changing fundamentally. The technology not only provides an academic platform for learning but does something much more force change in the training of surgeons and neurosurgeons and, therefore, the needle in patient care quality.

One thing these surgical training software platforms can do is simulate very complex surgical procedures and provide high-precision training that is needed to ensure the next generation of surgeons is better equipped to solve intricate medical challenges.

The Future of Medical Practice: Advances in Computerized Platforms for Surgical Simulation

For decades, the conventional training of a surgeon has been lectures, textbooks, and experience in an operating theater. Although these measures have proved satisfactory enough, they often fail to give a complete, risk-free exposure of the skills of a surgeon in the making. This is particularly so in neurosurgery where even the slightest goof up may result in disastrous effects.

Of course, it comes to advance surgical training software which itself is one mind-boggling advancement merging the theory and practice. These software provide a virtual operating room where trainees can be fully immersed in real scenarios of surgery without risk of live patients. Simulations of various surgical procedures, for instance, will help trainee neurosurgeons hone their techniques, make critical decisions, and perfect the precision needed in doing intricate brain and spinal surgeries.

Advantages of Surgical Training Software

High Precision of Training

High-precision training also is a sector where neurosurgeon education software has really done well, especially in neurosurgery. Into this domain, web solutions such as SurgeonsLab stood out, offering an all-purpose suite of tools to neurosurgeons-in-training. The platform can present highly detailed 3D anatomical models, enabling trainees to see and interact with the intricate details of the brain and spine. Such models can be manipulated, rotated, and dissected in virtually sensible ways, providing a level of anatomical understanding that probably cannot be matched by traditional textbooks.

For instance, a trainee can use the software to simulate a complex operation such as deep brain stimulation surgery where precision is of essence. The application will guide the user in each step while offering real-time feedback in terms of tool placement and technique. This allows neurosurgeons to adequately prepare in the operating room for anything they might face.

Various Scenarios and Personalized Learning

Another important characteristic of surgical training software is customizable scenarios. They can be preprepared in the form of unique cases, with particular conditions related to patients, anatomical variation, and their complications. Such flexibility helps to expose the users to different situations, as surgeries are somewhat unpredictable in real-life conditions.

They also offer customized learning. The trainees can track their work, learn the areas in which they are deficient, and receive specific recommendations for further learning. Such adaptive learning ensures that each one's special needs is addressed and that trainees have a steeper, more efficient learning curve.

Safe and Ethical Practice

Safety and ethics are really important in medical training, and the surgical training software answers to these dilemmas. The trainees may commit some blunders and learn from them without posing harm on patients. This permits the experimentation to take place and gives way to a culture of constant improvement. Moreover, it can also happen that the rarest and the complex can be modelled by software, and the surgeons can be taught lessons in high-risk cases without placing lives in danger.

Effect on Patient Care and Outcomes

The benefits of the surgical training software go beyond the training room to the actual patients for whom and for whom they work. Extended, high-accuracy training for neurosurgeons ensures better surgical techniques, decreased procedure times, and enhanced patient safety.

Better performance with clear decisions related to competent neurosurgeons is realized during critical moments within the operation. Training through the virtual environment increases precision and dexterity, thus bringing more successful operations with reduced risks for complications and increased rates of recovery for patients.

Surgical training software also offers opportunities for healthcare cost savings. Greater proficiency and efficiency through surgical training software allow surgeons to cut operating times, reducing the costs of the entire procedure. This would make advanced medical care more accessible to the population as a whole.

Ending Remarks

In a nutshell, surgical training software is an important part of the neurosurgeon education curriculum and other professionals in the medical field. In terms of high-definition training and tailor-made scenarios, the learning process is more personalized and the capacity along with increased confidence of surgeons-in-training is being enhanced with the help of these web platforms.

It enhances the patient care; it improves the results of surgery; and, of course, it increases the health-quality environment. In this way, future surgery will certainly be shaped by innovative training methods that will empower medical professionals to assume the sophisticated challenges of this 21st century.

Revolutionize Healthcare With Spatial Computing

Spatial computing, encompassing AR, VR, and MR, is revolutionizing healthcare by merging digital and physical realms. It enhances patient centered care, boosts surgical precision, and transforms medical education. As this technology integrates into healthcare, understanding its potential is crucial for professionals navigating a digitally augmented future.

The Foundations of Spatial Computing in Healthcare

Spatial computing blends physical and digital worlds through AR, VR, and MR, revolutionizing healthcare enhancements.

Augmented Reality (AR)

AR overlays digital info onto the real world, aiding surgeries and diagnostics by providing real-time data. It has reduced surgical errors and improved efficiency by up to 35% in studies.

Virtual Reality (VR)

VR immerses users in virtual environments, facilitating training and simulation for medical procedures. VR-trained surgeons perform 29% faster and are 6 times less likely to make errors compared to traditionally trained counterparts.

Mixed Reality (MR)

MR combines AR and VR, enabling real-world interaction with virtual objects, enhancing collaborative medical settings. It facilitates surgical planning and improves educational outcomes through engaged learning experiences.

Spatial computing integrates into healthcare IT systems, supported by devices like Apple Vision Pro and platforms from Microsoft and Google, enhancing user experiences. Understanding its capabilities is crucial for healthcare professionals to optimize patient care and operational efficiency as its applications become more widespread.

Enhancing Surgical Precision and Safety

Spatial computing revolutionizes surgical practices, enhancing precision, safety, and patient outcomes through AR and VR integration.

Augmented Reality in Surgical Procedures

AR enhances surgical precision by overlaying real-time, 3D images of patient anatomy, reducing invasive exploratory procedures. AR-guided surgeries decrease operation duration by up to 20% and improve surgical precision, minimizing postoperative complications.

Virtual Reality for Surgical Training

VR simulations offer hands-on training without live procedure risks, especially beneficial for neurosurgery and orthopedics. VR-trained surgeons perform procedures approximately 30% faster and have error rates reduced by up to 40% compared to traditional methods.

Mixed Reality for Collaborative Surgery

MR fosters collaboration by combining VR and AR benefits, allowing real and digital elements to coexist. It aids in complex surgeries, potentially reducing operation times and enhancing outcomes through improved teamwork and planning.

Case Study: Implementing AR in Orthopedic Surgery

AR technology in orthopedic surgery achieves 98% accuracy in implant alignment, surpassing traditional methods by 8%.

The Future of Surgical Precision

Advancements like AI-enhanced spatial computing and lighter AR glasses will refine surgical precision. Integration of spatial computing promises safer procedures, improved outcomes, and enhanced healthcare delivery.

Revolutionizing Medical Education and Training

Spatial computing, notably through VR and AR, revolutionizes medical education by offering immersive, interactive simulations, enhancing learning and retention.

Virtual Reality in Medical Training

VR offers immersive, risk-free practice for medical students, leading to a 230% improvement in surgical technique performance.

According to AxiomQ, VR significantly enhances skill acquisition in medical training.

Augmented Reality for Enhanced Learning

AR overlays digital info onto real-world objects, improving retention rates by up to 90% for complex subjects like anatomy.

Studies indicate higher satisfaction and engagement with AR training compared to traditional methods.

Mixed Reality for Collaborative Learning

MR combines VR and AR for interactive group training, enhancing collaboration efficiency by up to 50%.

Participants in cardiology training with MR applications demonstrated a 40% faster learning curve and 25% fewer errors than those using traditional methods.

Broadening Horizons in Patient Care

Spatial computing, encompassing AR, VR, and MR, revolutionizes patient care by enhancing diagnostics, patient education, and therapies. It improves outcomes through immersive experiences, supported by statistics and real-life examples.

Enhanced Diagnostic Procedures

AR enhances diagnostic accuracy by overlaying digital info onto patient scans, leading to a 10% higher tumor detection rate. This accelerates diagnoses and improves treatment outcomes significantly.

Patient Education Through Virtual Reality

VR transforms patient education with immersive experiences, increasing understanding of health conditions by 30%. VR simulations illustrate disease effects comprehensibly to non-medical individuals.

Mixed Reality for Enhanced Therapeutic Interventions

MR customizes interactive environments for physical rehabilitation and mental health treatments, improving motor function recovery by 20% in stroke rehabilitation. Task-specific games and exercises in MR accelerate recovery rates.

Real-Life Example: Improving Chronic Pain Management

VR programs reduce chronic pain levels by 40% during sessions, decreasing reliance on pain medication. Immersive environments distract patients from pain, offering non-pharmacological pain management strategies.

The Future of Patient Care with Spatial Computing

AI advancements enable real-time adjustments to therapeutic programs, enhancing treatment effectiveness. Widespread spatial computing adoption supports remote patient monitoring and home-based care, expanding healthcare impact.

Transformative Diagnostic and Imaging Techniques

Spatial computing, encompassing AR, VR, and MR, revolutionizes diagnostic and imaging techniques in healthcare. These technologies offer unprecedented precision and interactivity, enhancing radiological imaging, detailed analysis, and real-time surgical navigation. For instance, AR improves accuracy in visualizing tumors, VR aids in preoperative planning, and MR reduces the need for secondary surgeries.

Future advancements will integrate spatial computing with AI for automated diagnostics, while lighter AR and VR hardware will facilitate broader adoption in clinical settings. This transformative approach sets a new standard in healthcare, advancing toward more personalized and effective patient care, with enhanced accuracy and reduced procedural times.

Operational Efficiencies and Future Prospects

Spatial computing, including AR, VR, and MR, significantly enhances operational efficiencies in healthcare. Integration into clinical workflows streamlines decision-making by providing real-time data and visual aids, reducing errors and speeding up routine tasks. Hospitals adopting AR for data integration report a 20% reduction in time spent on tasks like routine checks and data entry.

MR applications improve resource management by tracking equipment in real time, reducing idle time by up to 30% and boosting operational efficiency. Looking ahead, the integration of AI with spatial computing holds promise for even greater efficiencies, predicting patient flows and optimizing resource allocation. Virtual command centers utilizing VR and AR exemplify this potential, leading to a 40% improvement in response times to critical patient incidents.

Challenges and Ethical Considerations

Addressing the challenges of spatial computing in healthcare involves overcoming technical hurdles such as graphics fidelity and data accuracy, along with ensuring privacy and security compliance, particularly concerning patient data protection under regulations like HIPAA.

Ethical considerations surrounding patient consent and the psychological impacts of immersive treatments must be navigated carefully. Collaboration among technology developers, healthcare professionals, and regulatory bodies is essential to establish standards and best practices, fostering responsible adoption. Education and training for healthcare providers on the ethical and practical aspects of spatial computing will be crucial for its successful integration, ensuring transformative benefits without compromising patient privacy or well-being.

Concluding Thoughts: Envisioning the Future of Spatial Computing in Healthcare

Spatial computing is reshaping healthcare, improving surgical precision, medical training, and patient care. Despite its transformative potential, challenges such as technical limitations and ethical concerns need careful navigation for responsible integration of digital healthcare solutions.

Collaborative efforts are essential to address these challenges and unlock the full benefits of spatial computing. Advancements in AI integration, development of standards, and accessibility to underserved regions are key areas that require ongoing innovation and adaptation in the healthcare sector.

Surgical Simulation Market

Surgical stimulation, also known as surgical simulation, refers to the use of simulated environments, models, or systems to replicate real-life surgical scenarios for training, practice, or research purposes.

The global Surgical Simulation Market technologies market is projected to reach $12,997.3 million by 2033 from $783.2 million in 2023, growing at a CAGR of 32.43% during the forecast period 2023-2033

Surgical Simulation Overview 

Surgical simulation stands at the intersection of technology, healthcare, and education, offering a revolutionary approach to training and refining surgical skills. 

Market Segmentation

By Simulation Modality 

Virtual reality 

Augmented Reality 

Computer based simulation 

By Application 

General Surgery 

Orthopedic Surgery 

Neurosurgery 

Grab a look at our free sample page to know more click here ! 

Key Market Players and Competition Synopsis

  Activ Surgical •    Augmedics Ltd. •    Brainlab AG •    Caresyntax •    Centerline Biomedical •    EchoPixel, Inc. •    FundamentalVR •    Medical Realities Ltd.

And many others 

For more reports visit our Robotics and Imaging Vertical Page click here !

Surgical Simulation Market Drivers 

Advancements in Technology 

Demand for Minimally Invasive Procedures 

Focus on Patient Safety 

Cost Effectiveness 

Recent Developments in the Surgical Simulation Market Technologies Market

Activ Surgical secured $15 million in funding led by ARTIS Ventures to further the advancement of autonomous and collaborative surgery. •  Augmedics fortified its AR/AI portfolio through the planned acquisition of Surgalign Digital Health assets. •  Augmedics secured $82.5 million to expedite the adoption of augmented reality in spine surgery. •  Rescale and Caresyntax expanded their collaboration to provide a scalable platform for AI-powered simulation and intelligence in surgery. The collaboration with the World Economic Forum enhanced access to surgical care and contributed to health equity. • Caresyntax announced a strategic collaboration with AAICO aimed at expanding AI-based solutions in healthcare.

Key Questions Answered 

Q What is the estimated global market size for the Surgical Simulation Market technologies market?

QWho are the primary product/technology manufacturers in the Surgical Simulation Market technologies market?

Q  What are the different types of Surgical Simulation Market technologies market available in the market?

Q How has the COVID-19 outbreak affected the future trajectory of the Surgical Simulation Market technologies market?

Q What are the key trends influencing the global Surgical Simulation Market technologies market, and what is their potential for impacting the market?

Q  What does the patent landscape of the global Surgical Simulation Market technologies market look like? Which year and country witnessed the maximum patent filing between January 2020 and December 2023?

Q What are the key regulations that impact the growth of the global Surgical Simulation Market technologies market?

Q What are the key drivers, challenges, and opportunities for the global Surgical Simulation Market technologies market, and what will be their impact on the market in short-, mid-, and long-term duration?

Q Which segment holds the largest market share of the Surgical Simulation Market technologies market based on technology? Which one of these segments is projected to be the fastest-growing segment during the forecast period 2023-2033? 

Conclusion 

The adoption of Surgical Simulation Market is fueled by a growing demand for minimally invasive techniques, improved surgical outcomes, and innovative treatment options across various surgical specialties. Surgeons are increasingly leveraging advanced technologies such as robotics, augmented reality, virtual reality, and artificial intelligence to perform complex procedures with greater precision and accuracy.

Moreover, the global aging population, increasing prevalence of chronic diseases, and focus on healthcare cost reduction are further driving the adoption of digital surgical solutions. These technologies enable healthcare providers to optimize resource utilization, reduce complications, and improve patient satisfaction while achieving greater efficiency and cost-effectiveness.

In conclusion, the surgical planning market is poised for significant growth and innovation driven by various factors such as advancements in technology, the increasing prevalence of chronic diseases, demographic trends, and a growing emphasis on patient safety and outcome improvement. As healthcare providers strive to deliver personalized, efficient, and high-quality care, surgical planning plays a pivotal role in optimizing surgical procedures, minimizing risks, and enhancing patient outcomes.

Pursue Excellence in Physiotherapy: BPT Course at Acharya Institute of Health Sciences

As the demand for skilled healthcare professionals continues to rise, pursuing a career in physiotherapy presents an exciting opportunity for those passionate about helping others regain mobility and improve their quality of life. In Bangalore, where opportunities for higher education abound, Acharya Institute of Health Sciences (AIHS) emerges as a premier destination for aspiring physiotherapists. Offering a Bachelor of Physiotherapy (BPT) course, AIHS stands tall among the top physiotherapy colleges in Bangalore.

AIHS's BPT course is meticulously designed to equip students with the knowledge, skills, and practical experience needed to excel in the field of physiotherapy. With a focus on hands-on training and experiential learning, the institute ensures that students receive a well-rounded education that prepares them for the challenges of the healthcare industry.

The curriculum covers a wide range of areas, including neurology, neurosurgery, neuro-physiotherapy, and community medicine, providing students with a comprehensive understanding of the principles and practices of physiotherapy. Through classroom lectures, laboratory sessions, and clinical rotations, students gain valuable insights and practical skills that are essential for success in their careers.

What sets AIHS apart from other physiotherapy colleges in Bangalore is its emphasis on practical application and real-world experience. The institute boasts state-of-the-art facilities, including well-equipped laboratories and simulation centers, where students can practice and refine their skills under the guidance of experienced faculty members.

Moreover, AIHS provides students with opportunities for hands-on experience through clinical placements in leading hospitals and healthcare institutions. This exposure not only enhances students' clinical skills but also allows them to interact with patients and healthcare professionals, gaining invaluable insights into the realities of the healthcare industry.

In addition to its exceptional BPT course, AIHS also offers programs in nursing, further cementing its reputation as one of the best nursing colleges in Bangalore. With a commitment to excellence and a focus on holistic development, AIHS continues to shape the future of healthcare professionals and contribute to the advancement of the healthcare industry.

For those aspiring to pursue a career in physiotherapy, Acharya Institute of Health Sciences is the ideal choice. With its comprehensive curriculum, state-of-the-art facilities, and opportunities for hands-on experience, AIHS prepares students to become competent and compassionate physiotherapists who make a meaningful difference in the lives of others.

For more information about our BPT course and admissions, please visit our website: https://www.aihs.ac.in/bachelor-of-physiotherapy

Exploring the Transformative Potential of Robotic Surgery By Dr.Tarul Mittal

The best robotic surgeon delhi ncr More than 12 years of expertise in Bariatric , Laparoscopic and Robotic surgery. Dr.Tarul mittal stands at the forefront of modern medicine, offering a paradigm shift in surgical precision and patient care. By employing miniature instruments inserted through tiny incisions, this minimally invasive approach enhances surgical outcomes while minimizing trauma to the patient's body.

Unleashing Precision through Robotics

At the core of the robotic surgeon in sir ganga ram hospital are three articulated arms, each housing specialized instruments meticulously designed for intricate surgical tasks. Complementing these arms is a fourth arm, equipped with a high-definition, 3D camera, elevating visualization to unprecedented levels. This technological marvel magnifies tissue and anatomical structures, empowering surgeons with enhanced guidance and precision during procedures.

Empowering Surgeons at the Console

Surgeons exercise command over these robotic arms from a console within the operating theater, utilizing intuitive finger and foot controls. Through a stereoscopic, high-definition monitor, they navigate the surgical field with unparalleled clarity and precision. Each movement of the surgeon's hands is seamlessly translated into real-time actions within the patient's body, ensuring surgical maneuvers of extraordinary accuracy and control.

Unlocking Potential Across Specialties

The applications of robotic surgery span across a multitude of medical disciplines, including thoracic surgery, vascular surgery, cardiac surgery, neurosurgery, and more. At the Institute of Robotic Surgery (IRS), our mission is to pioneer excellence in this field. By leveraging the latest generation of robotic systems and offering simulator facilities, we empower surgeons to hone their skills and enhance patient care through virtual practice and real-world application.

Pioneering Excellence: The Vision of IRS

Founded in 2012, the Institute of Robotic Surgery at SGRH is committed to advancing surgical care through innovation and collaboration. Our objectives encompass:

State-of-the-Art Surgical Care: Through interdisciplinary collaboration and collective wisdom, we strive for excellence in patient outcomes. Our team of leading surgeons, alongside dedicated anesthesiologists, physicians, and nurses, ensures the highest standards of surgical care.

Training and Research: The IRS serves as a hub for training the next generation of surgeons and healthcare professionals in the intricacies of robotic surgery. By fostering a culture of continuous learning and research, we aim to push the boundaries of what is achievable in surgical robotics.

In conclusion, robotic surgery represents a transformative frontier in modern healthcare, offering unprecedented precision and potential across a myriad of medical specialties. at Weightlose Clinic of Robotic Surgery, we are dedicated to harnessing this technology to redefine surgical excellence and enhance patient care for generations to come.

Q: Who are the best robotic surgeons at Sir Ganga Ram Hospital?

A: Sir Ganga Ram Hospital boasts a talented team of robotic surgeons who are recognized for their expertise and contributions to the field of robotic surgery. While specific rankings may vary depending on individual experiences and preferences, several surgeons stand out for their exceptional skills and dedication to patient care. Notable names include Dr. Tarul Mittal, among others.

Q: What qualifications and experience do the best robotic surgeons at Sir Ganga Ram Hospital possess?

A: The best robotic surgeons at Sir Ganga Ram Hospital typically possess extensive qualifications and experience in their respective fields. They are board-certified surgeons with specialized training in robotic surgery, often completing fellowships or additional certifications to enhance their skills. Additionally, they have a proven track record of successful outcomes and continuous professional development in the rapidly evolving field of robotic surgery.

Q: What procedures do the best robotic surgeons at Sir Ganga Ram Hospital specialize in?

A: The best robotic surgeons at Sir Ganga Ram Hospital specialize in a wide range of surgical procedures across various medical specialties. These may include but are not limited to thoracic surgery, vascular surgery, cardiac surgery, neurosurgery, gynecology, urology, and gastrointestinal surgery. Each surgeon may have specific areas of expertise and focus within their specialty.

Q: How can patients schedule a consultation with the best robotic surgeons at Sir Ganga Ram Hospital?

A: Patients interested in consulting with the best robotic surgeons at Sir Ganga Ram Hospital can typically schedule appointments through the hospital's official website or by contacting the relevant department directly. It is advisable to provide relevant medical records and information during the initial consultation to facilitate a comprehensive assessment and personalized treatment plan.

Q: What should patients expect during their consultation with the best robotic surgeons at Sir Ganga Ram Hospital?

A: During the consultation, patients can expect the best robotic surgeons at Sir Ganga Ram Hospital to conduct a thorough evaluation of their medical history, symptoms, and diagnostic reports. The surgeon will discuss treatment options, including the potential benefits and risks of robotic surgery, and address any questions or concerns the patient may have. Together, they will collaboratively develop a tailored treatment plan aligned with the patient's goals and preferences.

Q: What sets the best robotic surgeons at Sir Ganga Ram Hospital apart from others?

A: The best robotic surgeons at Sir Ganga Ram Hospital distinguish themselves through their exceptional surgical skills, commitment to patient-centered care, and dedication to advancing the field of robotic surgery. They prioritize safety, efficacy, and innovation in their practice, striving to achieve optimal outcomes and improve the quality of life for their patients. Additionally, they often contribute to research, education, and training initiatives to empower the next generation of surgeons and enhance the standard of care in robotic surgery.

Brain surgery training from an avatar

New Post has been published on https://sunalei.org/news/brain-surgery-training-from-an-avatar/

Brain surgery training from an avatar

Benjamin Warf, a renowned neurosurgeon at Boston Children’s Hospital, stands in the MIT.nano Immersion Lab. More than 3,000 miles away, his virtual avatar stands next to Matheus Vasconcelos in Brazil as the resident practices delicate surgery on a doll-like model of a baby’s brain.

With a pair of virtual-reality goggles, Vasconcelos is able to watch Warf’s avatar demonstrate a brain surgery procedure before replicating the technique himself and while asking questions of Warf’s digital twin.

“It’s an almost out-of-body experience,” Warf says of watching his avatar interact with the residents. “Maybe it’s how it feels to have an identical twin?”

And that’s the goal: Warf’s digital twin bridged the distance, allowing him to be functionally in two places at once. “It was my first training using this model, and it had excellent performance,” says Vasconcelos, a neurosurgery resident at Santa Casa de São Paulo School of Medical Sciences in São Paulo, Brazil. “As a resident, I now feel more confident and comfortable applying the technique in a real patient under the guidance of a professor.”

Warf’s avatar arrived via a new project launched by medical simulator and augmented reality (AR) company EDUCSIM. The company is part of the 2023 cohort of START.nano, MIT.nano’s deep-tech accelerator that offers early-stage startups discounted access to MIT.nano’s laboratories.

In March 2023, Giselle Coelho, EDUCSIM’s scientific director and a pediatric neurosurgeon at Santa Casa de São Paulo and Sabará Children’s Hospital, began working with technical staff in the MIT.nano Immersion Lab to create Warf’s avatar. By November, the avatar was training future surgeons like Vasconcelos.

“I had this idea to create the avatar of Dr. Warf as a proof of concept, and asked, ‘What would be the place in the world where they are working on technologies like that?’” Coelho says. “Then I found MIT.nano.”

Capturing a Surgeon

As a neurosurgery resident, Coelho was so frustrated by the lack of practical training options for complex surgeries that she built her own model of a baby brain. The physical model contains all the structures of the brain and can even bleed, “simulating all the steps of a surgery, from incision to skin closure,” she says.

She soon found that simulators and virtual reality (VR) demonstrations reduced the learning curve for her own residents. Coelho launched EDUCSIM in 2017 to expand the variety and reach of the training for residents and experts looking to learn new techniques.

Those techniques include a procedure to treat infant hydrocephalus that was pioneered by Warf, the director of neonatal and congenital neurosurgery at Boston Children’s Hospital. Coelho had learned the technique directly from Warf and thought his avatar might be the way for surgeons who couldn’t travel to Boston to benefit from his expertise.

To create the avatar, Coelho worked with Talis Reks, the AR/VR/gaming/big data IT technologist in the Immersion Lab.

“A lot of technology and hardware can be very expensive for startups to access as they start their company journey,” Reks explains. “START.nano is one way of enabling them to utilize and afford the tools and technologies we have at MIT.nano’s Immersion Lab.”

Coelho and her colleagues needed high-fidelity and high-resolution motion-capture technology, volumetric video capture, and a range of other VR/AR technologies to capture Warf’s dexterous finger motions and facial expressions. Warf visited MIT.nano on several occasions to be digitally “captured,” including performing an operation on the physical baby model while wearing special gloves and clothing embedded with sensors.

“These technologies have mostly been used for entertainment or VFX [visual effects] or CGI [computer-generated imagery],” says Reks, “But this is a unique project, because we’re applying it now for real medical practice and real learning.”

One of the biggest challenges, Reks says, was helping to develop what Coelho calls “holoportation”— transmitting the 3D, volumetric video capture of Warf in real-time over the internet so that his avatar can appear in transcontinental medical training.

The Warf avatar has synchronous and asynchronous modes. The training that Vasconcelos received was in the asynchronous mode, where residents can observe the avatar’s demonstrations and ask it questions. The answers, delivered in a variety of languages, come from AI algorithms that draw from previous research and an extensive bank of questions and answers provided by Warf.

In the synchronous mode, Warf operates his avatar from a distance in real time, Coelho says. “He could walk around the room, he could talk to me, he could orient me. It’s amazing.”

Coelho, Warf, Reks, and other team members demonstrated a combination of the modes in a second session in late December. This demo consisted of volumetric live video capture between the Immersion Lab and Brazil, spatialized and visible in real-time through AR headsets. It significantly expanded upon the previous demo, which had only streamed volumetric data in one direction through a two-dimensional display.

Powerful impacts

Warf has a long history of training desperately needed pediatric neurosurgeons around the world, most recently through his nonprofit Neurokids. Remote and simulated training has been an increasingly large part of training since the pandemic, he says, although he doesn’t feel it will ever completely replace personal hands-on instruction and collaboration.

“But if in fact one day we could have avatars, like this one from Giselle, in remote places showing people how to do things and answering questions for them, without the cost of travel, without the time cost and so forth, I think it could be really powerful,” Warf says.

The avatar project is especially important for surgeons serving remote and underserved areas like the Amazon region of Brazil, Coelho says. “This is a way to give them the same level of education that they would get in other places, and the same opportunity to be in touch with Dr. Warf.”

One baby treated for hydrocephalus at a recent Amazon clinic had traveled by boat 30 hours for the surgery, according to Coelho.

Training surgeons with the avatar, she says, “can change reality for this baby and can change the future.”

Brain surgery training from an avatar

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Brain surgery training from an avatar

Benjamin Warf, a renowned neurosurgeon at Boston Children’s Hospital, stands in the MIT.nano Immersion Lab. More than 3,000 miles away, his virtual avatar stands next to Matheus Vasconcelos in Brazil as the resident practices delicate surgery on a doll-like model of a baby’s brain.

With a pair of virtual-reality goggles, Vasconcelos is able to watch Warf’s avatar demonstrate a brain surgery procedure before replicating the technique himself and while asking questions of Warf’s digital twin.

“It’s an almost out-of-body experience,” Warf says of watching his avatar interact with the residents. “Maybe it’s how it feels to have an identical twin?”

And that’s the goal: Warf’s digital twin bridged the distance, allowing him to be functionally in two places at once. “It was my first training using this model, and it had excellent performance,” says Vasconcelos, a neurosurgery resident at Santa Casa de São Paulo School of Medical Sciences in São Paulo, Brazil. “As a resident, I now feel more confident and comfortable applying the technique in a real patient under the guidance of a professor.”

Warf’s avatar arrived via a new project launched by medical simulator and augmented reality (AR) company EDUCSIM. The company is part of the 2023 cohort of START.nano, MIT.nano’s deep-tech accelerator that offers early-stage startups discounted access to MIT.nano’s laboratories.

In March 2023, Giselle Coelho, EDUCSIM’s scientific director and a pediatric neurosurgeon at Santa Casa de São Paulo and Sabará Children’s Hospital, began working with technical staff in the MIT.nano Immersion Lab to create Warf’s avatar. By November, the avatar was training future surgeons like Vasconcelos.

“I had this idea to create the avatar of Dr. Warf as a proof of concept, and asked, ‘What would be the place in the world where they are working on technologies like that?’” Coelho says. “Then I found MIT.nano.”

Capturing a Surgeon

As a neurosurgery resident, Coelho was so frustrated by the lack of practical training options for complex surgeries that she built her own model of a baby brain. The physical model contains all the structures of the brain and can even bleed, “simulating all the steps of a surgery, from incision to skin closure,” she says.

She soon found that simulators and virtual reality (VR) demonstrations reduced the learning curve for her own residents. Coelho launched EDUCSIM in 2017 to expand the variety and reach of the training for residents and experts looking to learn new techniques.

Those techniques include a procedure to treat infant hydrocephalus that was pioneered by Warf, the director of neonatal and congenital neurosurgery at Boston Children’s Hospital. Coelho had learned the technique directly from Warf and thought his avatar might be the way for surgeons who couldn’t travel to Boston to benefit from his expertise.

To create the avatar, Coelho worked with Talis Reks, the AR/VR/gaming/big data IT technologist in the Immersion Lab.

“A lot of technology and hardware can be very expensive for startups to access as they start their company journey,” Reks explains. “START.nano is one way of enabling them to utilize and afford the tools and technologies we have at MIT.nano’s Immersion Lab.”

Coelho and her colleagues needed high-fidelity and high-resolution motion-capture technology, volumetric video capture, and a range of other VR/AR technologies to capture Warf’s dexterous finger motions and facial expressions. Warf visited MIT.nano on several occasions to be digitally “captured,” including performing an operation on the physical baby model while wearing special gloves and clothing embedded with sensors.

“These technologies have mostly been used for entertainment or VFX [visual effects] or CGI [computer-generated imagery],” says Reks, “But this is a unique project, because we’re applying it now for real medical practice and real learning.”

One of the biggest challenges, Reks says, was helping to develop what Coelho calls “holoportation”— transmitting the 3D, volumetric video capture of Warf in real-time over the internet so that his avatar can appear in transcontinental medical training.

The Warf avatar has synchronous and asynchronous modes. The training that Vasconcelos received was in the asynchronous mode, where residents can observe the avatar’s demonstrations and ask it questions. The answers, delivered in a variety of languages, come from AI algorithms that draw from previous research and an extensive bank of questions and answers provided by Warf.

In the synchronous mode, Warf operates his avatar from a distance in real time, Coelho says. “He could walk around the room, he could talk to me, he could orient me. It’s amazing.”

Coelho, Warf, Reks, and other team members demonstrated a combination of the modes in a second session in late December. This demo consisted of volumetric live video capture between the Immersion Lab and Brazil, spatialized and visible in real-time through AR headsets. It significantly expanded upon the previous demo, which had only streamed volumetric data in one direction through a two-dimensional display.

Powerful impacts

Warf has a long history of training desperately needed pediatric neurosurgeons around the world, most recently through his nonprofit Neurokids. Remote and simulated training has been an increasingly large part of training since the pandemic, he says, although he doesn’t feel it will ever completely replace personal hands-on instruction and collaboration.

“But if in fact one day we could have avatars, like this one from Giselle, in remote places showing people how to do things and answering questions for them, without the cost of travel, without the time cost and so forth, I think it could be really powerful,” Warf says.

The avatar project is especially important for surgeons serving remote and underserved areas like the Amazon region of Brazil, Coelho says. “This is a way to give them the same level of education that they would get in other places, and the same opportunity to be in touch with Dr. Warf.”

One baby treated for hydrocephalus at a recent Amazon clinic had traveled by boat 30 hours for the surgery, according to Coelho.

Training surgeons with the avatar, she says, “can change reality for this baby and can change the future.”

Revolutionizing Healthcare: Exploring the Intriguing World of fMRI Technology

One area where fMRI displays enormous potential is creating more immersive and personalized patient experiences during MRI scans. Traditionally, MRI scans could be loud, isolating, and uncomfortable for patients. But new fMRI visual systems and MRI cinemas are dramatically improving this. These allow patients to watch movies, television, video games, virtual reality environments, and more during scans on special MRI compatible display screens and headsets. Offering patients specialized entertainment, relaxation techniques, and diversions can enhance the MRI experience. Research suggests that medical imaging procedures are executed more efficiently and yield more favorable results when patients are in tranquility and relaxation. Patients allow autonomy in selecting materials to give them a sense of control during an otherwise restrictive machine scan.

Enhanced patient monitoring

Advanced MRI compatible camera systems mounted inside MRI scanner bores enhance the imaging experience. Instead of audio communication, intra-bore cameras let doctors see patients throughout scans to assure their safety and comfort. Knowing professionals are watching may make patients feel more cared for. The inside eyes also enable better patient coaching and positional corrections during scans as issues arise for cleaner final images. Unlocking insights into brain function

Neuroscientists can learn a lot about the complicated workings of the brain and how it works by looking at brain activity with the FMRI System. Researchers are getting a better idea of how healthy and unhealthy brains work as machine learning systems get better at studying functional magnetic resonance imaging (fMRI) data with many different types of information.

These in-depth scans make detailed maps of structures and links that are linked to a range of cognitive abilities and behaviors, such as movement control, sense awareness, thinking, mood regulation, language skills, decision-making, memory formation, and more. fMRI lets scientists study which complex brain networks are active when we do things like recognize a familiar face, listen to music, grieve after a loss, or even fall in love. Informing Treatments and Evaluations

These functional neural maps have a wide range of medical uses. They can provide more precise guidance for targeted neurosurgeries and improve evaluations for conditions such as visual or auditory impairment, cognitive disorders, psychiatric disorders, neurodegenerative diseases, epileptic seizures, language difficulties, substance dependencies, chronic pain syndromes, movement abnormalities, and others. fMRI scans provide improved therapeutic assessments on a micro-brain structure scale by analyzing before and after therapy. Exploring Cognition and Behavior

Finally, adapting immersive VR technology to work inside fMRI scanners unlocks remarkable research possibilities. Scientists can now present subjects with custom-simulated realities for studying precisely synchronized brain responses and mental phenomena that are difficult to recreate in labs. This promises a deeper study into things like spatial processing, threat reactions, skill acquisition, group dynamics, moral reasoning, and beyond during fMRI neuroimaging. The healthcare and neuroscience insights gleaned will prove invaluable.

As FMRI System resolution, power, and speed keep improving in tandem with smart AI analytics, so will this technology’s incredible contributions toward comprehending and enhancing brain function for healthcare. fMRI continues to open captivating neurological windows into the intricate world of minds and bodies. Kryptonite Solutions stands as a beacon of innovation in the healthcare industry, harnessing the power of cutting-edge technologies to revolutionize patient care and advance our understanding of the human body. Their dedication to patient well-being and unwavering commitment to innovation position them as a driving force in shaping the future of healthcare.

Virtual Skylights for Healthcare

Bashkir State Medical University Russia

Bashkir country clinical college, established in 1932, is one of the main scientific universities inside the Russian Federation and the center of scientific and pharmaceutical sciences of the Republic of Bashkortostan.

In the beginning, there has been handiest one college – school of standard medicinal drug. In 1961 school of Pediatrics became created, in 1970 – school of Preventive medicinal drug (later renamed to college of Preventive medicinal drug and Microbiology), in 1976 – college of Dentistry, in 1981 – college of Pharmacy.

There are over 8000 medical students, which includes greater than 850 foreign college students from forty international locations, about 1000 clinical houses and PhD packages and 7000 postgraduate professional trainings in our university. Bashkir State Medical University Russia additionally consists of the scientific university, which offers vocational secondary schooling in specialties of Nursing and Prosthetic Dentistry.

College has the United middle of Simulation-based totally schooling, ready with state-of-art simulators, wherein college students, clinical residents and physicians of Bashkir State Medical University Russia can decorate their sensible capabilities in neonatology, anesthesiology, resuscitation, obstetrics and gynecology, endoscopy, neurosurgery. In view that 2016 there may be the center in BSMU for number one accreditation of docs and pharmacists.

Intraoperative-to-Preoperative: A Seamless Transition for Optimal Patient Care

Intraoperative-to-preoperative (I2P) refers to a workflow or process where data and insights obtained during surgery (intraoperative) are utilized to refine or inform subsequent preoperative planning for future surgeries or medical procedures. This approach leverages real-time information gathered during an operation, such as imaging, tissue samples, and surgical observations, to enhance the accuracy and effectiveness of preoperative planning for the same patient. The I2P process aims to improve surgical outcomes, reduce complications, and personalize treatment by integrating intraoperative findings into the planning stages of upcoming interventions.