Tag Archives: Vijay Kumar

I sing the body cyber: two projects funded by the US National Science Foundation

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Points to anyone who recognized the reference to Walt Whitman’s poem, “I sing the body electric,” from his classic collection, Leaves of Grass (1867 edition; h/t Wikipedia entry). I wonder if the cyber physical systems (CPS) work being funded by the US National Science Foundation (NSF) in the US will occasion poetry too.

More practically, a May 15, 2015 news item on Nanowerk, describes two cyber physical systems (CPS) research projects newly funded by the NSF,

Today [May 12, 2015] the National Science Foundation (NSF) announced two, five-year, center-scale awards totaling $8.75 million to advance the state-of-the-art in medical and cyber-physical systems (CPS).

One project will develop “Cyberheart”–a platform for virtual, patient-specific human heart models and associated device therapies that can be used to improve and accelerate medical-device development and testing. The other project will combine teams of microrobots with synthetic cells to perform functions that may one day lead to tissue and organ re-generation.

CPS are engineered systems that are built from, and depend upon, the seamless integration of computation and physical components. Often called the “Internet of Things,” CPS enable capabilities that go beyond the embedded systems of today.

“NSF has been a leader in supporting research in cyber-physical systems, which has provided a foundation for putting the ‘smart’ in health, transportation, energy and infrastructure systems,” said Jim Kurose, head of Computer & Information Science & Engineering at NSF. “We look forward to the results of these two new awards, which paint a new and compelling vision for what’s possible for smart health.”

Cyber-physical systems have the potential to benefit many sectors of our society, including healthcare. While advances in sensors and wearable devices have the capacity to improve aspects of medical care, from disease prevention to emergency response, and synthetic biology and robotics hold the promise of regenerating and maintaining the body in radical new ways, little is known about how advances in CPS can integrate these technologies to improve health outcomes.

These new NSF-funded projects will investigate two very different ways that CPS can be used in the biological and medical realms.

A May 12, 2015 NSF news release (also on EurekAlert), which originated the news item, describes the two CPS projects,

Bio-CPS for engineering living cells

A team of leading computer scientists, roboticists and biologists from Boston University, the University of Pennsylvania and MIT have come together to develop a system that combines the capabilities of nano-scale robots with specially designed synthetic organisms. Together, they believe this hybrid “bio-CPS” will be capable of performing heretofore impossible functions, from microscopic assembly to cell sensing within the body.

“We bring together synthetic biology and micron-scale robotics to engineer the emergence of desired behaviors in populations of bacterial and mammalian cells,” said Calin Belta, a professor of mechanical engineering, systems engineering and bioinformatics at Boston University and principal investigator on the project. “This project will impact several application areas ranging from tissue engineering to drug development.”

The project builds on previous research by each team member in diverse disciplines and early proof-of-concept designs of bio-CPS. According to the team, the research is also driven by recent advances in the emerging field of synthetic biology, in particular the ability to rapidly incorporate new capabilities into simple cells. Researchers so far have not been able to control and coordinate the behavior of synthetic cells in isolation, but the introduction of microrobots that can be externally controlled may be transformative.

In this new project, the team will focus on bio-CPS with the ability to sense, transport and work together. As a demonstration of their idea, they will develop teams of synthetic cell/microrobot hybrids capable of constructing a complex, fabric-like surface.

Vijay Kumar (University of Pennsylvania), Ron Weiss (MIT), and Douglas Densmore (BU) are co-investigators of the project.

Medical-CPS and the ‘Cyberheart’

CPS such as wearable sensors and implantable devices are already being used to assess health, improve quality of life, provide cost-effective care and potentially speed up disease diagnosis and prevention. [emphasis mine]

Extending these efforts, researchers from seven leading universities and centers are working together to develop far more realistic cardiac and device models than currently exist. This so-called “Cyberheart” platform can be used to test and validate medical devices faster and at a far lower cost than existing methods. CyberHeart also can be used to design safe, patient-specific device therapies, thereby lowering the risk to the patient.

“Innovative ‘virtual’ design methodologies for implantable cardiac medical devices will speed device development and yield safer, more effective devices and device-based therapies, than is currently possible,” said Scott Smolka, a professor of computer science at Stony Brook University and one of the principal investigators on the award.

The group’s approach combines patient-specific computational models of heart dynamics with advanced mathematical techniques for analyzing how these models interact with medical devices. The analytical techniques can be used to detect potential flaws in device behavior early on during the device-design phase, before animal and human trials begin. They also can be used in a clinical setting to optimize device settings on a patient-by-patient basis before devices are implanted.

“We believe that our coordinated, multi-disciplinary approach, which balances theoretical, experimental and practical concerns, will yield transformational results in medical-device design and foundations of cyber-physical system verification,” Smolka said.

The team will develop virtual device models which can be coupled together with virtual heart models to realize a full virtual development platform that can be subjected to computational analysis and simulation techniques. Moreover, they are working with experimentalists who will study the behavior of virtual and actual devices on animals’ hearts.

Co-investigators on the project include Edmund Clarke (Carnegie Mellon University), Elizabeth Cherry (Rochester Institute of Technology), W. Rance Cleaveland (University of Maryland), Flavio Fenton (Georgia Tech), Rahul Mangharam (University of Pennsylvania), Arnab Ray (Fraunhofer Center for Experimental Software Engineering [Germany]) and James Glimm and Radu Grosu (Stony Brook University). Richard A. Gray of the U.S. Food and Drug Administration is another key contributor.

It is fascinating to observe how terminology is shifting from pacemakers and deep brain stimulators as implants to “CPS such as wearable sensors and implantable devices … .” A new category has been created, CPS, which conjoins medical devices with other sensing devices such as wearable fitness monitors found in the consumer market. I imagine it’s an attempt to quell fears about injecting strange things into or adding strange things to your body—microrobots and nanorobots partially derived from synthetic biology research which are “… capable of performing heretofore impossible functions, from microscopic assembly to cell sensing within the body.” They’ve also sneaked in a reference to synthetic biology, an area of research where some concerns have been expressed, from my March 19, 2013 post about a poll and synthetic biology concerns,

In our latest survey, conducted in January 2013, three-fourths of respondents say they have heard little or nothing about synthetic biology, a level consistent with that measured in 2010. While initial impressions about the science are largely undefined, these feelings do not necessarily become more positive as respondents learn more. The public has mixed reactions to specific synthetic biology applications, and almost one-third of respondents favor a ban “on synthetic biology research until we better understand its implications and risks,” while 61 percent think the science should move forward.

I imagine that for scientists, 61% in favour of more research is not particularly comforting given how easily and quickly public opinion can shift.

POD (print-on-demand) robots

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I’ve heard of print-on-demand (POD) books before but not robots as per the April 4, 2012 article on BBC News online (link to National Science Foundation removed),

Researchers aim to build a desktop technology that would allow an average person to design and print a machine within 24 hours.

The team says that making it easier to create specialised robots could have a “profound impact on society”.

The effort is being funded by a $10m (£6.3m) grant from the National Science Foundation [NSF].

The Virginia-based organization [NSF] described the move as a “game changing investment”.

“It has the potential to democratise and personalise automation to meet the needs of individual users – whether for search and rescue workers in remote areas of the world or educators in classrooms around the US – possibilities for social impact abound,” said spokeswoman Lisa-Joy Zgorski.

The April 3, 2012 MIT (Massachusetts Institute of Technology) news item by Abby Abazorius provides more detail,

“This research envisions a whole new way of thinking about the design and manufacturing of robots, and could have a profound impact on society,” says MIT Professor Daniela Rus, leader of the project and a principal investigator at the MIT Computer Science and Artificial Intelligence Laboratory (CSAIL). “We believe that it has the potential to transform manufacturing and to democratize access to robots.”

“Our goal is to develop technology that enables anyone to manufacture their own customized robot. This is truly a game changer,” says Professor Vijay Kumar, who is leading the team from the University of Pennsylvania. “It could allow for the rapid design and manufacture of customized goods, and change the way we teach science and technology in high schools.”

The five-year project, called “An Expedition in Computing for Compiling Printable Programmable Machines,” brings together a team of researchers from MIT, the University of Pennsylvania and Harvard University, and is funded as part of the NSF’s “Expeditions in Computing” program.

It currently takes years to produce, program and design a functioning robot, and is an extremely expensive process, involving hardware and software design, machine learning and vision, and advanced programming techniques. The new project would automate the process of producing functional 3-D devices and allow individuals to design and build functional robots from materials as easily accessible as a sheet of paper.


Researchers hope to create a platform that would allow an individual to identify a household problem that needs assistance; then head to a local printing store to select a blueprint, from a library of robotic designs; and then customize an easy-to-use robotic device that could solve the problem. Within 24 hours, the robot would be printed, assembled, fully programmed and ready for action.

By altering the way in which machines can be produced, designed and built, the project could have far reaching implications for a variety of fields.

“This project aims to dramatically reduce the development time for a variety of useful robots, opening the doors to potential applications in manufacturing, education, personalized health care and even disaster relief,” says Rob Wood, an associate professor at Harvard University.


Thus far, the research team has prototyped two machines for designing, printing and programming, including an insect-like robot that could be used for exploring a contaminated area and a gripper that could be used by people with limited mobility.

Here’s a video demonstrating a few of the prototypes the team has developed (an “insect-like robot that could be used for exploring a contaminated area and a gripper that could be used by people with limited mobility”).

You can find out more about the CSAIL project at MIT here.

Other research collaborators on the five-year NSF project include Visiting Scientist Martin Demaine, Associate Professor Wojciech Matusik, Professor Martin Rinard, and Assistant Professor Sangbae Kim of MIT. Besides Wood (Harvard) and Kumar (UPenn), the team also includes Associate Professor Andre DeHon, Professor Sanjeev Khanna and Professor Insup Lee, all from UPenn.