A couple people said they were interested so I took a few pics of me connected to the monitor. Unfortunately they didn’t turn out as well as I’d hoped, I might need to take these at night so there’s no glare on the monitor screen. Just to put it out there so no one gets discouraged that they can’t get pics to turn out like this, I did a lot of editing in photoshop to get these to turn out like this. Let me know what you think and if you’d like to see more.

Here’s a list of all the medical and kink stuff I’ve got

-Oxygen mask

-non rebreather oxygen mask

-nasal cannulas

-pink isolation gown

-blue isolation gown

-pink bouffant cap

-blue bouffant cap

-blue shoe covers

-white bouffant cap

-green hospital gown

-white hospital gown

-3 lead ECG

-5 lead ECG

-pink diapers

-girls goodnites diapers

-blue plastic isolation gowns

-high flow nasal cannula for CPAP

-ventilator circuit for diy ventilator

-LMA

-oral airways

-pink gloves

-white gloves

-natural latex gloves

-black gloves

-blue gloves

-condom catheters and leg bag

-pediatric oxygen mask and nasal cannula

-pink chucks

-blue chucks

-Philips Intellivue MP50 monitor

-Philips intellivue MP5 monitor

-Philips Intellivue MP2 monitor

-thigh BP cuff

-arm BP cuff

-2 rectal temperature sensors

-ability to print reports from the monitor

-DIY ventilator (currently out of service due to software issues)

-3d printed and machined metal butt plugs I’ve made

-oxygen concentrator

-dental pick

-sterile syringes

-dental mirrors

If there’s anything you’d like to see me use please let me know.

How expensive would it be to get a full 3D scan of my skeletal system if I don't medically need it. And how would I get it? Are there private practices that I could book an appointment with? Would the file output be compatible with 3D printing software? What I am asking is; where can I get a life sized 3D print of my own skeleton?

Transfemoral Monocoque Polyaxial Study

There will never be enough trained medical professionals to meet the global need for prosthetic limbs.  This means that the solution must be digital, must scale exponentially, and must avoid the human bottleneck.This concept leg proved that a complex leg may be created by algorithm and 3D printed, entirely custom per user.  The geometry is based on a contralateral 3D scan, guaranteeing a recreation of body symmetry.   Complex knee and ankle joints are printed integrally at no burden to process or cost. This remains an ongoing project.

Design: Scott Summit Software: GeoMagic Pro/Engineer Creo Fabrication: EOS Selective Laser Sintering Materials: polyamide

You're right. Other than modern drip irrigation, water saving innovations, geothermal power, solar powered windows, cherry tomatoes, monitors for sudden infant death syndrome, MobileEye, Waze, silent wind turbines, the 8088 Intel chip which paved the way for modern computers, USB flash drive, harmful microorganism counters for food and beverage industry, using the ocean to produce solar energy, optical heart beat monitoring, increasing plastic recycling efficiency by 50%, portable sleep apnea monitors, the world's smallest camera for medical procedures, water utility leak detection technology, HP digital printing press, remote heart and vitals monitoring for medical staff, contributions to developing a COVID vaccine, R&D that led to the first cell phone, a phone that can detect diseases including cancer, multiple sclerosis, and Parkinson's with 93% accuracy, an exoskeleton that helps paraplegic people walk again, a digestible medical camera in the form of a pill, a flexible heart stent that saved millions of lives of people suffering from coronary heart disease, computer firewalls, antivirus software, ICQ, the iron Dome missile defense system, glasses that read text to visually impaired people, leading breakthrough medical technologies like the ability to 3d print a functioning human heart and nanotechnology that detects and attacks cancer cells, home kits for analysing guy bacteria, desalination tech and a machine that can literally make safe drinking water out of air... WHAT HAS ISRAEL ACTUALLY DONE FOR YOU.

The Mossad: Satirical, Yet Awesome

@TheMossadIL

what if after searching for almost 20 years, you found that there isn't a problem, you just can't be happy? no medication can help you, no therapist is willing to take you, your family and friends have all but given up, that's your reality is simply you cannot be happy. would you do anything at all?

what am i doing so wrong that I'm so far behind and so stagnant after so long when it's easy to do what I'm trying to do. im trying to reach top 1k in the world in beat saber so i can give up on hobbies and everyone else is like "oh im top 500 and i had a lot of fun getting here this game is so good and i just play it on the side" and here i am, literally not having fun at all, giving it everything i have, taking it very seriously, and not getting anywhere

therapists stop showing up to appointments after the third appointment or so, simply just ghost me. so many to the point where I've run out of people licenced in my area to help

I've tried just about every antidepressant under the sun, including non FDA approved ones and lithium, which is typically for crazy people

in my state who can legally help me, i have nobody left who can help, and have been out for months. i regularly check for appointments through 3 different agencies. plus, i don't know what else to do. ive tried kooky stuff like spit tests to see what meds would work best, or essential oil treatment. Believe me, ive had an open mind.

and 988 is the most fucking useless thing ever. you call, get put on hold for 30 ish minutes, then hung up on. nkt disconnected, hung up on. (I have a software that tells the difference). the 1 time I did actually wait for someone in the past 4 days, they said "call right back if we are disconnected, it'll put you right back with me"

called again, hung up on again

tried texting, nobody bothered to respond after 3 hours, then i gave up.

im simply trying to reach a goal in one thing that i might have even a small chance at achieving so i can give up on hobbies as a whole

it becomes bleak and meaningless when your efforts are not only in vain, but joyless and worthless

I have tried this list of hobbies:

Gardening

PC gaming

PC building

Coding

Woodworking

Whittling

Pet husbandry

Crocheting

Drawing/painting

Writing

Car detailing

3d modeling

3d printing

Anime

Soap opera

Comedy shows

Doom scrolling

House flipping

Virtual reality

Vacationing

Camping

Road tripping

Forest exploring

Shotgun and rifle shooting

list of hobbies I've tried for months and got zero enjoyment out of, but also were terrible at

ive tried online and in person therapy, psychiatric care, mental hospitals admission, Therapy groups, out of state therapy which i got warned for because it's technically a crime, and there's no medication i can try left

I'm tired

im so god fucking damn tired

The Rise of 3D Printing in Prosthetics and Orthotics Market

The global prosthetics and orthotics market plays a vital role in improving quality of life for millions worldwide. Worth an estimated $7.2 billion in 2024, the market facilitates mobility for those with limb differences or injuries through highly customized external limb replacements and braces. The market introduces prosthetics and orthotics—Medical devices that enhance or assist impaired body parts and mobility. Orthotics are braces or supports for joints, spine, and limbs; prosthetics externally replace missing limbs. Together they improve functionality and quality of life for users. Major players in the prosthetics and orthotics space utilizing advanced manufacturing include Ossur, Steeper Group, Blatchford, Fillauer, Ottobock, and WillowWood Global. These industry leaders increasingly deploy cutting-edge 3D printing and customized design software to produce state-of-the-art prosthetics and braces. Current trends in the prosthetics and orthotics market include growing utilization of 3D printing and advanced manufacturing techniques. 3D printing enables on-demand production of complex, customized devices. It reduces manufacturing costs and wait times while improving fit and comfort. Expanding material options also allow more lifelike prosthetics. As technology evolves, the market is positioned for continued growth through 2031 in facilitating mobility worldwide. Future Outlook The prosthetics and orthotics market is expected to witness significant advancements in the coming years. Manufacturers are constantly focusing on developing innovative technologies such as 3D printed prosthetics that provide a better fit, enhanced comfort, and unrestricted movement. There is also a rising trend of using lightweight, highly durable and comfortable materials like carbon fiber and thermoplastics to manufacture prosthetic devices. Advancements in myoelectric prosthetics with touch and motion sensors are making them more dexterous and responsive. Using pattern recognition and machine learning techniques, next-gen prosthetics could gain functionality approaching that of natural limbs.

PEST Analysis Political: Regulations regarding clinical trials and approvals of new prosthetic technologies may affect market growth. Favorable reimbursement policies for prosthetic devices can boost adoption. Economic: Rising disposable incomes allow more individuals to opt for higher-end prosthetics. Emerging markets present abundant opportunities for growth. Inflation and economic slowdowns can hinder market profitability. Social: Increasing incidence of amputations and disabilities due to aging population, accidents, war injuries etc. drive market demand. Growing awareness regarding prosthetics and orthotics aids adoption. Stigma associated with limb loss poses challenges. Technological: Advancements in materials, manufacturing techniques like 3D printing, sensors, computing power and battery technologies are enhancing functionality and usability of prosthetics/orthotics. Myoelectric and robotic prosthetics have vastly improved in recent years. Opportunity Rising aging population presents a huge opportunity for prosthetics and orthotics targeting mobility issues and disabilities. Over 630,000 amputations occur annually in the U.S. due to dysvascular conditions like diabetes, presenting a sizable patient pool. Expanding applications of prosthetics and orthotics beyond mobility impairment into sports and military could drive significant growth. Growing incidence of trauma and injuries globally increases the number of patients relying on these devices. Emerging markets like Asia Pacific and Latin America offer immense opportunities owing to increasing disposable incomes, expanding healthcare infrastructure and rising medical tourism. Technological advancements are constantly improving functionality and usability of prosthetic devices, fueling adoption rates. The lightweight, durable and comfortable characteristics of newer materials expand addressable indications and patient acceptance. Key Takeaways Growing demand from aging population: The rapid increase in aging population worldwide who are prone to mobility issues, disabilities and chronic diseases like diabetes is a key driver spurring sales of orthotic and prosthetic devices. Global expansion into emerging markets: Emerging markets like Asia Pacific, Latin America, Eastern Europe and the Middle East offer immense opportunities owing to their large population bases and improving healthcare penetration. Technological advancements: Constant R&D bringing advancements in areas such as 3D printing, lightweight materials,

Photoinitiator Market Industry Leaders Size & Share Outlook & New Revenue Pockets

Growing applications and environmental restrictions on VOCs to drive the acceptance of photoinitiators in the market

The global photoinitiators market size was USD 1.6 billion in 2021 and is expected to reach USD 2.6 billion by 2026, projecting a CAGR of 10.3% between 2021 and 2026. photoinitiators are increasingly used in the adhesive, ink, coating and other end-use industries. The increasing demand of coating industry drives the demand for photoinitiators. However, the outbreak of COVID-19 has created ripples across various application industries leading to reduced demand for photoinitiators. Due to the lockdown scenario in most of the world, the demand for photoinitiators from adhesive, coating, ink and other industries have declined sharply in 2020.

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As the world is getting ready to open up its economies and reduce restrictions from June 2021, the market will take an upward turn. The photoinitiators market is expected to witness high growth in 2021 owing to increasing applications, technological advancements, and growing demand in APAC. Photoinitiators are largely used in the coating applications by the wood, furniture, and architectural end-use industries apart from adhesive and printing ink industries. This market growth is backed by growing environmental concerns and increasingly stringent regulations.

The increasing number of restrictions on VOCs across the globe is pushing the industry to search for an alternative. Photoinitiators proved to be a safer and economical substitute. It enhances the surface finish as well as the shelf life of the product. Photoinitiators have been developed so that they are safe even for use in the dental industry. Many food safety compatible photoinitiators are also developed. All these photoinitiators are eco-friendly and have virtually no impact on human health.

UV curable resins market has developed high growth prospects in 3D printing, digital printing, packaging, barrier films, and printed circuit applications. Automotive, architecture, medical, and several other industries are using 3D printing solutions to improve their design and manufacturing strategies. The 3D printing technology is expected to advance further in printers and printing methods, materials used in 3D printing, and software for designing and printing. All this directly affects the demand of the photoinitiators market.

Photoinitiators are the key to innovation in coatings, which have influenced the major trends in the coatings industry. The coating industry is largely influenced by stringent regulations set by authorities, including the European Union (EU), for reducing the VOC content from coatings, adhesives and inks. Consequently, the demand has shifted from solvent-borne UV to environmentally friendly products, such as waterborne UV using photoinitiators.

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The demand for waterborne photoinitiators has witnessed substantial growth in the past five years owing to rapid technological developments. In addition to eliminating solvent emissions, photoinitiator-based UV curing formulations provide improved mechanical characteristics, and increased production efficiency, particularly, in the spray application. These benefits encourage end users to adopt photoinitiator-based UV technology for new applications.

Mold Design: A Key to Precision Manufacturing

Mold design is a critical aspect of manufacturing, serving as the blueprint for creating high-quality, precise products. It involves the development of molds used in various industrial processes, such as injection molding, blow molding, and die-casting. These molds act as templates that shape materials—like plastics, metals, or ceramics—into the desired forms. The success of a manufacturing process heavily depends on the accuracy, efficiency, and durability of its molds, making mold design a pivotal step in production.

Importance of Mold Design

Precision and Accuracy Mold design ensures that every product produced meets exact specifications. With the advent of advanced design software, such as CAD (Computer-Aided Design) and CAM (Computer-Aided Manufacturing), engineers can create molds with unparalleled precision, reducing errors and waste.

Efficiency in Production A well-designed mold streamlines the manufacturing process. It minimizes cycle times, reduces material wastage, and enhances product consistency, ultimately improving production efficiency.

Cost Optimization While designing molds may require an upfront investment, a robust design reduces the likelihood of defects, rework, and material loss. This leads to significant long-term cost savings.

Versatility Mold designs are highly customizable to meet various industry needs, from automotive and aerospace components to consumer goods and medical devices. A tailored mold ensures that unique product requirements are met.

Key Elements of Mold Design

Material Selection The choice of material for the mold depends on factors such as durability, thermal conductivity, and resistance to wear and tear. Common materials include steel, aluminum, and sometimes even high-grade plastics.

Cooling Systems Effective cooling channels within the mold are crucial for regulating the temperature during production. This helps in maintaining product quality and reducing cycle times.

Ejection Mechanisms Proper ejection systems ensure that finished parts are removed without damage, allowing for smooth and uninterrupted operations.

Parting Line and Draft Angles The parting line determines where the mold opens, while draft angles facilitate the easy removal of the molded part. These aspects must be carefully calculated to avoid defects like flash or deformation.

Trends in Mold Design

3D Printing in Mold Making Additive manufacturing has revolutionized mold design by enabling rapid prototyping and complex geometries that were previously unattainable. This innovation accelerates design iterations and reduces lead times.

Simulation Software Advanced simulation tools allow designers to predict potential issues, such as warping or shrinkage, before creating the physical mold. This predictive capability enhances accuracy and efficiency.

Sustainability With an increasing focus on eco-friendly manufacturing, mold design now incorporates materials and methods that reduce energy consumption and waste.

Challenges in Mold Design

Despite technological advancements, mold design faces challenges such as high initial costs, the need for skilled labor, and the complexity of meeting diverse product specifications. However, ongoing innovations continue to address these issues, making mold design more accessible and efficient.

For more info:-

Injection Molding

Plastic Molding

Product Design Engineering Services: Transforming Australia's Electronics Industry

In the fast-evolving landscape of Australia's electronics industry, innovation is the key to success. Whether it's developing cutting-edge consumer devices or advanced industrial equipment, product design engineering services play a crucial role in turning ideas into functional and market-ready products. This article delves into the significance of these services, their benefits, and why they are vital for businesses in the Australian electronics industry.

What Are Product Design Engineering Services?

Product design engineering services involve the conceptualization, design, prototyping, and optimization of products to ensure they meet industry standards, customer expectations, and operational requirements. These services encompass a range of activities, such as:

Conceptual Design: Creating initial sketches and CAD models to visualize the product.

Prototyping: Developing working models for testing and validation.

Testing & Analysis: Ensuring the product's durability, functionality, and compliance with Australian regulations.

Manufacturing Support: Assisting with the production process to ensure scalability and cost-efficiency.

Why Are These Services Essential for the Australian Electronics Industry?

1. Fostering Innovation

The electronics industry thrives on innovation. Product design engineering services enable businesses to develop groundbreaking technologies, improving their competitive edge in a global market.

2. Enhancing Product Quality

Meticulous design and testing processes ensure that products are reliable, durable, and meet stringent industry standards.

3. Cost Efficiency

By optimizing designs for manufacturability and material use, businesses can reduce production costs without compromising on quality.

4. Compliance with Australian Standards

Australia has strict regulations for electronic products, including safety and environmental guidelines. Professional design services ensure compliance, avoiding costly delays and recalls.

How Product Design Engineering Services Work

Step 1: Requirement Analysis

The process begins with understanding client needs, market demands, and industry trends.

Step 2: Ideation and Concept Development

Designers and engineers collaborate to create innovative concepts tailored to the client's goals.

Step 3: Prototyping and Testing

Prototypes are developed to test functionality, usability, and performance under real-world conditions.

Step 4: Refinement and Finalization

Based on feedback, the design is optimized for efficiency and manufacturability.

Step 5: Production Support

Engineers work closely with manufacturers to streamline the production process and ensure high-quality output.

Benefits of Partnering with a Product Design Engineering Firm in Australia

Access to Expertise: Leverage the knowledge of experienced engineers familiar with the Australian market.

Cutting-edge Tools: Benefit from advanced technologies like 3D printing, CAD software, and simulation tools.

Time-to-Market Advantage: Streamlined processes reduce development timelines, helping you launch products faster.

FAQs on Product Design Engineering Services

1. What industries can benefit from product design engineering services?

These services are invaluable for industries like consumer electronics, telecommunications, automotive, medical devices, and industrial equipment.

2. How can I choose the right design firm in Australia?

Look for firms with experience in the electronics sector, a strong portfolio, and expertise in local regulations and standards.

3. Are these services expensive?

While initial costs may seem high, the long-term benefits, such as reduced production costs and enhanced product quality, outweigh the investment.

4. Can these services help with sustainable product design?

Yes, many firms specialize in eco-friendly designs that minimize environmental impact while meeting industry standards.

5. What technologies are used in product design engineering?

Technologies like CAD software, 3D printing, finite element analysis (FEA), and virtual prototyping are commonly used.

Conclusion

Product design engineering services are the backbone of innovation and efficiency in Australia's electronics industry. They not only ensure high-quality, compliant products but also empower businesses to stay ahead in a competitive market. Whether you're a startup or an established company, investing in these services can be a game-changer for your success.

Ready to elevate your product development? Contact a trusted product design engineering firm today and unlock your potential in Australia's electronics industry!

Aiyana Kaur, 29, was born and raised in Birmingham, UK, to parents Jasleen Kaur (54) and Arjun Kaur (56). Jasleen, a chemistry professor, and Arjun, a software engineer, immigrated to the UK from India as university students, seeking to expand their academic horizons. Aiyana grew up in a household brimming with curiosity and intellectual passion. While her parents were often engrossed in their work, they always made time to answer her endless questions about the natural world, nurturing her love for science and problem-solving.

Aiyana has an older brother, Kabir (32), a civil rights lawyer, who shares her fierce drive for making a difference in the world. Their relationship is warm and supportive, though their fields couldn’t be more different. Kabir often teases Aiyana for her “mad scientist” tendencies, while she quips back about his flair for courtroom drama.

As a child, Aiyana was empathetic and meticulous, often bandaging her dolls or tinkering with broken electronics to “fix” them. These traits carried into her teenage years, where she excelled in biology and computer science. A particularly formative moment was when she accompanied her mother to a science fair and saw a 3D-printed prosthetic arm in action. The way technology could restore someone’s mobility and independence left her awestruck, sparking her dream of pursuing biomedical engineering.

Aiyana earned a first-class degree in biomedical engineering from Imperial College London, followed by a master’s in bioinformatics. During her studies, she interned with a nonprofit in India that focused on low-cost medical devices, which deepened her commitment to accessibility in healthcare. Her career has since taken off, and she now works for a leading biotech firm, designing prosthetics and medical devices tailored to underserved communities worldwide.

Despite her busy schedule, Aiyana has a vibrant personality and a knack for connecting with others. She’s known for her thoughtful nature and sharp wit. In her free time, she loves thrifting, watching reality tv, and playing volleyball at her local recreational center. She’s also started to dip her toes into the world of rock climbing at the gym. Her bookshelf is lined with novels by contemporary South Asian authors, reflecting her love for stories that intertwine identity and culture.