A new study published by the European Patent Office (EPO) has revealed a number of interesting statistics and trends regarding innovation in additive manufacturing. The report points out the origins of all notable patent applications from 2000 – 2018 and the industries leading innovation with the most inventions. In general, there has been a global […]
Roster of medical and 3D printing experts will come together for ASME’s AM Medical forum
The American Society of Mechanical Engineers (ASME), a multidisciplinary professional association, has announced the roster of speakers, exhibitors and tours for its AM Medical: Additive Manufacturing & 3D Innovations event. Set to take place May 27-28, 2020, at the Minneapolis Convention Center in Minnesota, the event is dedicated to 3D printing applications of medical and […]
3D Printing Industry News SLICED: Rize, 3D Systems, Essentium, Protect3d, Xioneer Systems
In this edition of Sliced, the 3D Printing Industry news digest, we cover the latest partnerships, acquisitions, medical developments and creative applications from across our industry. Additionally, you’ll find out how 3D printing helped to miniaturize the tallest statue in the world; the novel technique used by law enforcers to help keep the Super Bowl […]
Interview with Johnson & Johnson’s Bioprinting Lead Orchid Garcia
Orchid Garcia is a Research Fellow and Lead for 3D Bioprinting and Tissue Regen Technologies at Johnson & Johnson. As Johnson & Johnson’s technical lead for bioprinting she is both responsible for leading the technical aspects of the firm’s entry into bioprinting and educating the firm on the technology. Orchid previously worked scouting and developing new technologies, in Medical Affairs, Clinical Affairs and Regulatory Affairs. She holds a Bachelor of Science degree in Biochemistry and Cellular Biology from the University of California San Diego; a Master of Science degree in Microbiology from California State University Los Angeles; and a PhD from the University of Southern California. We are used to seeing bioprinting as an emerging technology with huge potential. With huge companies such as J&J getting involved however, we’re seeing the arrival of organizations with the experience and wherewithal to bring bioprinting from the lab into a clinical setting.
There seems to be a little bit of a disconnect between bioprinting reality and the optimism in the media?
I think that healthy optimism encourages discussion about the potential of new technologies such as bioprinting in the future. However, I think the disconnect lies within an understanding of current capabilities and limitations of the technology. While there is promising news about how bioprinting could be used to create fully functional, transplantable organs, that just isn’t the case at present due to technological limitations and gaps in the regulatory landscape.
With that being said, there are areas where bioprinted products can potentially bring value to patients in the near term. For example, bioprinted tissue can be used for in vitro testing for various pharmaceutical and consumer products. Bioprinting can also be used to create various tissue or anatomical constructs for physician training to allow clinicians to plan or practice complex procedures. Additionally, bioprinting can be used to create various regenerative scaffolds that can potentially be used to encourage tissue regeneration in patients.
The future holds promise that bioprinting may have the ability to engineer human tissue and organoids—fully functioning 3D printed organ prototypes—for testing or transplant. For now, however, our efforts are focused on near-term tissue regenerative technologies and bioprinting applications that will ultimately improve treatments or access to treatment for patients.
How did you first get involved in bioprinting?
During my doctoral and postdoctoral training in tissue engineering and regenerative medicine, bioprinting was a new and emerging technology that was always out of reach (due to cost and availability).Many of the challenges encountered in traditional tissue engineering approaches can be address via the use of bioprinting.
When I transitioned to industry, I continued to watch the development of the technology on the sidelines.When J&J announced their commitment to investing in world-class 3D printing capabilities, specifically bioprinting, I couldn’t resist jumping at the opportunity to get involved in the development and acceleration of this technology that has the potential to change the way we treat patients in the field of regenerative medicine.
What about it still excites you?
Bioprinting is exciting because it represents a technology at the nexus of academic, industrial, technological and clinical collaboration. The advances we’ve seen in this technology have been a testament to the global scientific ecosystem and its ability to drive innovation. What excites me about my role is that this technology is changing and advancing so quickly, I constantly have the opportunity to learn through our partnerships with both academic and industry collaborators as well as internal J&J collaborators.
What are the challenges in bioprinting right now?
Because 3D bioprinting is a new and disruptive technology, gaps currently exist in standards, guidance documents, regulatory frameworks and manufacturing frameworks for these products. Although these gaps represent challenges in terms of launching a product commercially, health agencies worldwide have begun working on frameworks to address these hurdles and have begun partnering with clinicians, industry stakeholders and academics to simultaneously develop these frameworks alongside technological advancements so as not to delay the availability of patient access to bioprinting innovations.
Which technologies are you focusing on (LIFT, Inkjet, SLA?)?
Everything we do is ultimately guided by patient need. Our team works to determine where patients can be best served through bioprinted technologies in the near and long term.Based on those needs, our team evaluates all technologies and determines which technology to incorporate into our portfolio.
We’re seeing a lot of excitement around hydrogels at the moment?
Much of the early work done in bioprinting focused on hard tissue constructs, however, with advancements in materials science, hydrogels afford the ability to print and maintain the shape fidelity of softer tissues. I look forward to following the development of hydrogel capabilities, as they will be critical from a regenerative medicine standpoint.
How important is tissue regeneration?
Tissue regeneration is critical if we are looking to repair tissue, rather than simply replace tissue.3D printing in general, and bioprinting specifically, affords us the opportunity to utilize 3D printing technology to create constructs that promote tissue regeneration, through composition, architecture and design.Furthermore, the creation of living tissue, through either 3D printing or regeneration, offers advantages that address limitations of currently available materials like metals and polymers, which can break down over time in the body.
What are some of the technical challenges with tissue regeneration?
The technical challenge lies in understanding how cells will ultimately react within the human body or to our engineered constructs and ensure that we are enabling regeneration.An understanding of mechanical, biological, physical and chemical principles is critical, and thus, you can see why collaboration is such an important pillar within the field.
What tissues are you the most excited about now?
I wouldn’t say that I’m excited about a particular tissue per se, but I am excited about the recent advancements in the creation of 3D printed vascular and microvascular networks.The ability to create and potentially implant tissue and/or organs in the future will rely on the ability to deliver oxygen and nutrients to tissue.Some of the new techniques and technologies being created are exciting because they have served as proof-of-principle that the challenge of vascularization can be addressed.
What are some of the opportunities?
Broadly, bioprinting can be used in a wide range of applications that will enable Johnson & Johnson to evolve the way we create and deliver personalized products and solutions for providers and patients.3D printed biological tissue models have the potential of making medical product and drug development more effective and efficient. Furthermore, an entirely new class of next-generation medical implants customized for the individual patient may exist in the future using bioprinting technologies that enable cellular growth and tissue regeneration.
How should we explain bioprinting to the general public?
Bioprinting is rapidly evolving as a promising new option to produce, repair and regenerate human biological tissue. From a technical perspective, bioprinting utilizes many of the same principles of 3D printing to create 3D constructs of tissue based on digital models. These constructs can be made from a combination of biomaterials, bioactive molecules and living cells.
The post Interview with Johnson & Johnson’s Bioprinting Lead Orchid Garcia appeared first on 3DPrint.com | The Voice of 3D Printing / Additive Manufacturing.
Interview: Grace X. Gu, UC Berkeley, developer of a self-correcting 3D printer
In 2017 multinational pharmaceutical company Johnson & Johnson, launched the WiSTEM2D Scholars Award program to increase the representation of women in six scientific and technical fields. Open to assistant and associate academic professors from across the STEM field, winners of the prize are awarded $150,000 in funding and three years of mentorship from Johnson & […]
UC Berkeley Researcher Receives Award from Johnson & Johnson for Smart 3D Printer
In 2015, Johnson & Johnson launched the WiSTEM2D (Women in Science, Technology, Math, Manufacturing and Design) program in order to increase the representation of women in the scientific and technical fields, along with the development of female leaders. The unique, multifaceted program is meant to engage women at three important development phases of their lives: youth (ages 5-18), the university graduate level, and in their professional careers.
J&J began offering its WiSTEM2D Scholars Award in 2017, which is meant to fuel development of female leaders in STEM2D, as well as add to the talent pipeline. The award supports the winners’ research, while also inspiring other women to go down similar career paths in their own STEM2D fields. Now in its third year, nominations for the Scholars Award were accepted from female scholars in each of the STEM2D disciplines: Science, Technology, Engineering, Math, Manufacturing and Design. An independent Advisory Board was set up to choose the winners from over 400 international applicants, and the six winners were recently announced.
“Through this Award and other programs, Johnson & Johnson is working to increase the participation of women in STEM2D fields worldwide. We want to nourish the development of women leaders building a larger pool of highly-trained, female researchers so that they can lead STEM2D breakthroughs in the future,” said Cat Oyler, Vice President, Global Public Health, Tuberculosis, Johnson & Johnson and WiSTEM2D University Sponsor.
In addition to being recognized at an awards ceremony tonight at Johnson & Johnson’s worldwide headquarters in New Jersey, the winners – all assistant or associate academic professors, or the global equivalent of such – will each receive $150,000 in research funding, as well as three years of mentorship from Johnson & Johnson.
Just like Johnson & Johnson, we here at 3DPrint.com have also worked hard to highlight the 3D printing-related accomplishments of young girls and women in STEM and tech fields. That’s why I was thrilled to learn that one of this year’s winners is focused on manufacturing and 3D printing.
Each Scholars Award winner represents one of the STEM2D disciplines:
- Katia Vega, PhD, Assistant Professor of Design, UC Davis: while she’s already using the human body as a source of wearable technology, she’ll move on to experimenting with interactive skin and biosensors.
- Ronke Olabisi, PhD, Assistant Professor of Biomedical Engineering at Rutgers University: developing a new hydrogel that can be placed over an injury and constantly deliver insulin and stem cell growth factors for faster skin and tissue growth.
- Grace X. Gu, PhD, Assistant Professor of Mechanical Engineering at University of California, Berkeley: developing a smarter, more efficient 3D printer that can self-correct during a print job.
- Rebecca Morrison, PhD, Assistant Professor of Computer Science at University of Colorado, Boulder: identifying flexible algorithms that can run calculations on shifting variables more quickly and accurately.
- Naama Geva-Zatorsky, PhD, Assistant Professor of Medicine, Technion-Israel Institure of Technology: studying the interactions between the immune system and gut microbes.
- Shengxi Huang, PhD, Assistant Professor of Electrical Engineering, The Penn State University: developing one device to measure potential disease-causing biomolecules, like cancer cells.
Grace Gu, PhD
Gu, who joined the UC Berkeley faculty in 2018, is looking to address the limitations in manufacturing and materials design with her smart, self-correcting 3D printer.
“I am really excited to build my research group at Berkeley, meet and mentor undergraduate and graduate students, teach foundational mechanical engineering classes, collaborate with exceptional faculty members within and outside the university, and work on 3D-printing projects with students to create a better tomorrow,” Gu said when she began her job at the university.
Gu received her BS in Mechanical Engineering from the University of Michigan in 2012, picking up an MS from MIT two years later and remaining at MIT to earn her PhD in Mechanical Engineering in 2018. According to UC Berkeley, her research interests include harnessing the power of “tools such as advanced computational analysis, machine learning and topology optimization to revolutionize the field of smart additive manufacturing.”
In her research group at the university, the work is focused on bio-inspired materials.
“The big goal is to develop materials that are inspired by nature, like seashells and bones, and discover new material combinations never before manufactured. These biomaterials possess remarkable mechanical properties that are yet to be replicated by man-made counterparts,” Gu said. “This way we can make implants, for instance, tailored to each individual with the properties necessary for structural integrity of the part—and push the frontiers of additive manufacturing.”
[Image: UC Berkeley]
The work for which she received her WiSTEM2D Scholars Award is centered around building a smarter 3D printer. As Berkeley Engineering put it, she trained “a model for a smart 3D printer that can perform predictive diagnostics to ensure optimal printing quality.”
Gu is taking computer science concepts and applying them to manufacturing in order to create her smart 3D printer. The ultimate goal of this particular research is develop a 3D printer that’s able to correct mistakes by itself while working, while also using a wider range of materials in order to more quickly and reliably produce objects like tougher bike helmets and stronger prosthetics.
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[Images: Johnson & Johnson unless otherwise noted]
DePuy Synthes invests €36 million to advance 3D printing material science in Ireland
DePuy Synthes, the orthopedic and neurological branch of Johnson & Johnson, has invested €36 million through its Ireland Innovation Centre to advance material science in 3D printing. This investment will contribute to R&D at DePuy Synthes’ Materials and Surface Technology Centre, Johnson & Johnson’s 3D Printing Centre of Excellence, and the Advanced Materials + BioEngineering […]
Neutrogena to launch personalised 3D printed face masks
Neutrogena, the American skincare brand of the multinational healthcare company, Johnson & Johnson, has introduced its customizable 3D printed face mask. Known as the MaskiD, this beauty venture uses photographs from a smartphone to micro 3D print a face mask suited to the consumer’s skin type and desired treatment. Speaking to Condé Nast beauty publication […]
3D Printing Industry Review of the Year February 2018
Following January’s vision of the year ahead, February 2018 was a month of 3D printer releases. In this month, Stratasys shared material details of its upcoming metal 3D printer, and HP expanded its range of Multi Jet Fusion (MJF) systems to include full color 3D printers. This month, we also marked the 20th anniversary of SOLIDWORKS World, […]
Johnson & Johnson acquires EIT 3D printed spinal implant range
Johnson & Johnson Medical GmbH, the subsidiary of Johnson & Johnson Medical Devices Companies (JJMDC) has acquired spinal implant 3D printing specialist Emerging Implant Technologies (EIT), headquartered in Germany. Following this acquisition, Johnson & Johnson’s orthopedics branch DePuy Synthes will also strengthen its interbody implant portfolio which includes titanium integrated PEEK technology for minimally invasive spinal surgery. […]