December orders of manufacturing technology totaled $456.7 million, nearly a 40% increase from November 2020 and a 17.6% increase over December 2019, according to the latest U.S. Manufacturing Technology Orders (USMTO) report published by AMT – The Association For Manufacturing Technology. This is the highest monthly total since November 2018 and the second-straight month of year-over-year gains. Total orders in 2020 were $3.87 billion, a decrease of 15% from 2019.

“In December, the manufacturing technology industry saw growth in all geographic regions of the country as well as across the majority of manufacturing sectors,” said Douglas K. Woods, president of AMT. “Given the reduced holiday schedules of most companies in December, this is particularly striking. The aerospace industry, which has been anemic since the spring due to the collapse of global travel, did significantly better than it has in many months. The November FAA approval of the Boeing 737 Max led to increased capital equipment investments by both small and large companies who had financing dependent upon FAA approval in place for these investments.

“Last spring, industry economic forecasters were predicting a 50% decline in manufacturing technology orders for the year amid U.S. industrial production contracting at a lower annualized rate than any point during the Great Depression. But as 2020 closes, we can now confirm that orders were down only 15% for 2020. Given the strength of December, and with pent up demand, depleted inventories, continued reshoring, several COVID vaccines, and a lot of cash on the sidelines, things bode well for a positive start to 2021.”

As the challenges multiply and pressure mounts, Stäubli Robotics is actively expanding its offerings to the life sciences market, including a full range of flexible and collaborative robotic arms and mobility solutions. The company has been developing high-throughput screening (HTS) technologies since the early 2000s and presented its latest innovations for lab automation at SLAS 2021.

Many challenges in the life sciences sector pre-date the COVID-19 pandemic but were accelerated by these unprecedented circumstances. Demands for higher throughput, greater efficiency and productivity have intensified, along with increased need to minimize time spent on repetitive tasks, ensure safety, and maintain compliance with strict hygienic requirements. In response, labs are increasingly implementing robotics for automated liquid handling and diagnostic systems.

Swiss-based Stäubli has been making innovative leaps in automation for sensitive environments for over two decades as a supplier of robots, and more recently, mobility solutions including AMRs (autonomous mobile robots) and AGVs (automated guided vehicles). The company was the first to develop a fully encapsulated robot design with a minimized footprint and optimized work envelope, ideal for stringent laboratory requirements.

Working with specialized equipment builders, Stäubli offers customized solutions for lab automation that can transform biotech and pharmaceutical applications in terms of precision, safety, ease of use and integration, enabling seamless functioning with sequencing software.

The mobile and connected laboratory of the future has arrived, and Stäubli has the technology and capabilities to meet the most demanding requirements in life science, covering:

• Cell culture apparatus/supplies
• Clinical automation/CLIA
• Diagnostics, clinical and pre-clinical
• Drug discovery
• Genomics & DNA sequencing
• HTS products and services
• Liquid handling equipment
• Microplate handlers
• Custom robotics
  

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3D technologies, developed by Materialise, played a crucial role in the world’s first simultaneous double hand and face transplant that was successfully performed at NYU Langone Health in Manhattan, New York. Materialise’s 3D planning and printing tools enable the speed and accuracy required for such a complex medical procedure. 3D printed personalized tools, such as those used in the double hand and face transplant, are also increasingly common for use in routine surgery, providing surgeons with an additional level of confidence which results in improved patient outcome.

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The 22-year-old patient suffered burn wounds resulting from a car accident, leaving him with severe injuries to his face and both arms. He suffered significant damage to his soft tissue, which severely limited his ability to lead a normal life. During a preparation period of 14 months, Materialise clinical engineers formed a cohesive team alongside NYU Langone surgeons, rehearsing the operation in a lab environment to develop and fine-tune the surgical plan. Once a suitable donor was found, the team, led by Dr. Eduardo D. Rodriguez, the Helen L. Kimmel Professor of Reconstructive Plastic Surgery and chair of the Hansjörg Wyss Department of Plastic Surgery at NYU Langone, had only 24 hours to begin the procedure that would improve the patient’s function, appearance, and quality of life.

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In the months leading up to the surgery Materialise engineers coordinated the development of a surgical plan and created an on-screen 3D model based on CT-scans. This allowed the surgeons and clinical engineers to virtually plan the procedure and visualize different scenarios in three dimensions, creating an in-depth understanding of the anatomical bone structure and determining the optimal surgical flow. Pre-surgical planning also made it possible for surgeons to virtually select and position various medical implants to predict the optimal anatomical fit. Once the surgical plan was finalized, Materialise 3D printed the personalized surgical guides, anatomical models, and tools for use during the transplant surgery.

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During this momentous procedure, Rodriguez and his surgical team of 16 used Materialise’s 3D printed cutting and drilling guides. This fully guided system for bone fragment repositioning and fixation was unique to the patient’s anatomy and helped position the medical tools with great precision, reducing the overall surgery time. Additionally, Materialise created 3D printed sterilizable identification tags for nerves and blood vessels, 3D printed models that were used during donor transport, and 3D printed splints, enabling optimal donor hand position during soft tissue reconstruction.

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“Complex transplant surgery like this brings together a large team of specialists and presents new and unique challenges,” Rodriguez says. “This demands careful planning and makes timing, efficiency and accuracy absolutely critical. Virtually planning the surgery in 3D and creating 3D printed, patient-specific tools offer additional insights in the pre-operative phase and increased levels of speed and accuracy during a time-critical surgery.”

“Image-based planning and medical 3D printing have completely revolutionized personalized patient care by providing surgeons with detailed insights and an additional level of confidence before entering the operation room,” says Bryan Crutchfield, vice president and general manager – North America. “As a result, leading hospitals are adopting 3D planning and printing services as part of their medical practices because they create a level of predictability that would be impossible to achieve without the use of 3D technologies.”

Materialise has pioneered many leading medical applications of 3D printing and enables researchers, engineers, and clinicians to develop innovative, personalized treatments that help improve and save lives. The Materialise platform of software and services forms the foundation of certified medical 3D printing in clinical and research environments, offering virtual planning software tools, 3D-printed anatomical models, and personalized surgical guides and implants.

Cygnus Manufacturing Company (CMC) provides full-service manufacturing from prototype through production of high precision products and components for the medical device, transportation, energy, and aerospace industries.

As an FDA compliant and ISO 13485 medical device certified manufacturer, a leading U.S. ventilator company approached CMC at the start of the COVID-19 pandemic requesting expeditious assistance to substantially increase its production of a specialty valve in response to the country’s shortage of life-saving ventilators.

The ventilator company had a chrome on brass part requiring documented measurements of 31 datapoints after manufacturing and again after plating. While CMC had been manufacturing this valve prior to the start of the pandemic, the substantial increase in production volume in a short time frame necessitated much faster and more automated measuring capability.

They needed a precision optical instrument designed to scan and measure cylindrical parts in seconds, not minutes so they turned to Inspection Technologies to identify a metrology solution. As an OGP representative, Inspection Technologies suggested a TurnCheck precision optical instrument system equipped with intelligent and intuitive software.

Since CMC needed an immediate production ramp-up solution, Inspection Technologies worked with OGP to expedite order and production of the TurnCheck while OGP was able to fast-track the delivery.

Craig Harding, chairman and CEO of CMC comments, “We were extremely pleased with the speed of OGP’s responsiveness and the high-quality performance of the TurnCheck system, allowing immediate increased ventilator production to help meet the country’s demand during this crisis.”

OGP President, R. Stephen Flynn adds, “It is with great pleasure that we were able to meet the expectations of this customer to enable the manufacturing of such an important product during this difficult time.”