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Tag: Columbia University School of Engineering and Applied Science

  • New Method Uses Engineered Bacteria and AI to Sense and Record Environmental Signals

    New Method Uses Engineered Bacteria and AI to Sense and Record Environmental Signals

    Newswise — New York, NY—May 9, 2023—Researchers in Biomedical Engineering Professor Tal Danino’s lab were brainstorming several years ago about how they could engineer and apply naturally pattern-forming bacteria. There are many bacteria species, such as Proteus mirabilis (P. mirabilis), that self-organize into defined patterns on solid surfaces that are visible to the naked eye. These bacteria can sense several stimuli in nature and respond to these cues by “swarming”—a highly coordinated and rapid movement of bacteria powered by their flagella, a long, tail-like structure that causes a whip-like motion to help propel them. 

    For inspiration, Danino’s team at Columbia Engineering, which has a good deal of experience using synthetic biology methods to manipulate bacteria, discussed where else they might find similar patterns in nature and what their functions might be. They noted how tree rings record tree age and climate history, and that sparked their idea of applying P. mirabilis rings as a recording system. They had also been interested in applying AI to characterize the distinct features of bacterial colony patterns, an approach that they realized could then be used to decode an engineered pattern. 

    “This seemed to us to be an untapped opportunity to create a natural recording system for specific cues,” said Danino, a member of Columbia’s Data Science Institute (DSI).

    In a new study, published May 4 in Nature Chemical Biology, the researchers worked with P. mirabilis, commonly found in the soil and water and occasionally the human gut, known for its bullseye-appearing colony patterns. When the bacteria are grown on a Petri dish of a solid growth media, they alternate between phases of bacterial growth, which make visible dense circles, and bacterial movement, called “swarming” movement, which expands the colony outwards.  

    The team engineered the bacteria by adding what synthetic biologists call “genetic circuits”—systems of genetic parts, logically compiled to make the bacteria behave in a desired way. The engineered bacteria sensed the presence of the researchers’ chosen input—ranging from temperature to sugar molecules to heavy metals such as mercury and copper—and responded by changing their swarming ability, which visibly changed the output pattern.  

    Working with Andrew Laine, Percy K. and Vida L. W. Hudson Professor of Biomedical Engineering and a DSI member  and Jia Guo, assistant professor of neurobiology (in psychiatry) at the Columbia University Irving Medical Center the researchers then applied deep learning–a state-of-the-art AI technique–to decode the environment from the pattern, in the same way scientists look at the rings in a tree trunk to understand the history of its environment. They used models that can classify patterns holistically to predict, for example, sugar concentration in a sample, and models that can delineate or “segment” edges within a pattern to predict, for example, the number of times the temperature changed while the colony grew. 

    An advantage of working with P. mirabilis is that, compared to many of the typical engineered bacterial patterns, the native P. mirabilis pattern is visible to the naked eye without costly visualization technology and forms on a durable, easy-to-work-with solid agar medium. These properties increase the potential to apply the system as a sensor readout in a variety of settings. Using deep learning to interpret the patterns can enable researchers to extract information about input molecule concentrations from even complex patterns. 

    “Our goal is to develop this system as a low-cost detection and recording system for conditions such as pollutants and toxic compounds in the environment ,” said Anjali Doshi, the study’s lead author and a recent PhD graduate from Danino’s lab. “To our knowledge, this work is the first study where a naturally pattern-forming bacterial species has been engineered by synthetic biologists to modify its native swarming ability and function as a sensor.”

    Such work can help researchers better understand how the native patterns form, and beyond that, can contribute to other areas of biotechnology beyond the area of sensors. Being able to control bacteria as a group rather than as individuals, and control their movement and organization in a colony, could help researchers build living materials at larger scales, and help with the Danino lab’s parallel goal of engineering bacteria to be living “smart” therapeutics, by enabling better control of bacterial behaviors in the body. 

    This work is a new approach for building macroscale bacterial recorders, expanding the framework for engineering emergent microbial behaviors. The team next plans to build on their system by engineering the bacteria to detect a wider range of pollutants and toxins and moving the system to safe “probiotic” bacteria. Ultimately, they aim to develop a device to apply the recording system outside of the lab.

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    About the Study

    Journal: Nature Chemical Biology

    The study is titled “Engineered bacterial swarm patterns as spatial records of environmental inputs.”

    Authors are: Anjali Doshi 1 , Marian Shaw 1 , Ruxandra Tonea1 , Soonhee Moon1 , Rosalía Minyety1 , Anish Doshi2 , Andrew Laine1 , Jia Guo3,4 & Tal Danino 1,5,61 Department of Biomedical Engineering, Columbia University2 Department of Electrical Engineering and Computer Sciences, University of California, Berkeley3 Department of Psychiatry, Columbia University4 Mortimer B. Zuckerman Mind Brain Behavior Institute, Columbia University5 Herbert Irving Comprehensive Cancer Center, Columbia University6 Data Science Institute, Columbia University

    This work was supported by an NSF CAREER Award (1847356 to T.D.), Blavatnik Fund for Innovations in Health (T.D.), and NSF Graduate Research Fellowship (A.D., Fellow ID 2018264757).

    A.D., M.S., J.G., A.L. and T.D. are named as inventors on a provisional patent application that has been filed by Columbia University with the US Patent and Trademark Office related to all aspects of this work. The remaining authors declare no competing interests. 

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    LINKS:

    Paper: https://www.nature.com/articles/s41589-023-01325-2
    DOI:  10.1038/s41589-023-01325-2

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  • Team Led by Columbia University Wins $20M NSF Grant to Develop AI Institute for Artificial and Natural Intelligence

    Team Led by Columbia University Wins $20M NSF Grant to Develop AI Institute for Artificial and Natural Intelligence

    Newswise — New York, NY—May 5, 2023—The National Science Foundation (NSF) announced today that it is awarding $20 million to establish the AI Institute for ARtificial and Natural Intelligence (ARNI), an interdisciplinary center led by Columbia University that will draw together top researchers across the country to focus on a national priority: connecting the major progress made in artificial intelligence (AI) systems to the revolution in our understanding of the brain.

    Collaborative partnerships

    ARNI is a collaboration between Columbia, Baylor College of Medicine, City University of New York, Harvard, Princeton, Howard Hughes Medical Institute, Mila Quebec AI Institute, Tuskegee University, the University of Pennsylvania, and UTHealth Houston. Industry partners include Amazon, DeepMind, Google, IBM, and Meta, and outreach partners include the Neuromatch Academy and the New York Hall of Science. In addition to receiving NSF funding, ARNI is funded by a partnership between NSF and the Office of the Under Secretary of Defense for Intelligence and Security (R&E).

    “The National Science Foundation has long been a strong supporter of research at Columbia University and we are very excited about this new collaboration,” said Mary Boyce, Provost, Columbia University. “The AI Institute for Artificial and Natural Intelligence draws not only on our interdisciplinary strengths throughout the University but also our partnerships — both old and new — across the country. By bringing together  the amazing progress being made in AI systems and our growing understanding of the brain, ARNI will ignite advances in both neuroscience and AI, and transform our world in the next decade.”

    Revolution in neuroscience, cognitive science, and AI research

    The past 10 years have seen spectacular progress in interrogating neural activity, circuitry, and learning, yet our neuroscience insights have so far informed AI only superficially. Conversely, our rapidly advancing AI methods and systems based on massive amounts of data have only begun to impact neuroscience. ARNI will meet the urgent need for new paradigms of interdisciplinary research between neuroscience, cognitive science, and AI. This will accelerate progress in all three fields and broaden the transformative impact on society in the next decade.  

    “ARNI is an ambitious plan that requires a dedicated effort across institutions, and we have assembled one of the strongest groups of investigators in theoretical neuroscience and foundational machine learning in the world,” said Jeannette Wing, Executive Vice President for Research, Columbia University. “Our PIs are building on existing, and often tightly interacting, neural and AI groups at Columbia, Baylor, Penn, together with Janelia, MILA, Google/DeepMind, and Meta. At the same time, we are building new bridges to Tuskegee, CUNY, Yale, IBM, and beyond. Our track record is already strong and now, thanks to the National Science Foundation, we expect ARNI to meet the urgent need for new paradigms of interdisciplinary research between neuroscience and AI.”

    Research team

    ARNI will be led by Principal Investigators (PIs) Richard ZemelKathleen McKeown, and Christos Papadimitriou (Computer Science, Columbia Engineering), Liam Paninski (Zuckerman Institute and Statistics and Neuroscience Departments, Columbia University), and Xaq Pitkow (Baylor College of Medicine, Rice University). These PIs bring together expertise from a wide variety of disciplines, including artificial intelligence, theoretical computer science, statistics, neuroscience, physics, and cognitive science. They will work with a large team of researchers to tackle the limitations and challenges of current machine learning systems, including learning with limited data, reasoning about causality and uncertainty, and lifelong learning–all hallmarks of biological systems–while also pushing the boundaries of our understanding of how brains compute and learn. 

    Bridging the gaps between artificial and biological networks

    ARNI will bridge the current significant gaps between artificial and biological networks and make room for a broad, diverse range of applications, from the industrial sector, such as robust, interpretable medical decisions and smarter home assistants; to societal applications, such as better social safety nets and assistive multimodal systems to help the vulnerable; to scientific discoveries such as providing hypotheses about brain function and creating powerful tools for extracting insights from massive data. 

    “Thanks to new AI algorithms, our knowledge of neuroscience and cognitive science expands every day,” said Shih-Fu Chang, Dean of Columbia Engineering. “And with our growing knowledge of the brain and cognitive science, we have better AI algorithms, making progress on important applications that impact our world. ARNI aims to overcome current limitations in AI while also introducing modern AI into neuroscience, foundational machine learning, and cognitive science. Engineers are pivotal for applying scientific insights to real-world problems, and we look forward to the groundbreaking discoveries that will come from this exciting large-scale collaboration. We are grateful to the National Science Foundation for helping us create this modern cross-disciplinary arsenal, converging to generate new insights and advance this very important, emerging field.”

    Trustworthy systems

    Richard Zemel, the Director of ARNI and the Trianthe Dakolias Professor of Engineering and Applied Science at Columbia Engineering, has been integral in the development of AI technology, most recently as the co-founder and Research Director of the Vector Institute for Artificial Intelligence. His research spans machine learning and its interaction with neuroscience and cognitive science, as well as robust and fair machine learning. He noted that robust and fair machine learning is critical for using these new AI tools to improve society. 

    “A key characteristic of our approach is a focus on developing interpretable models, often based on causal approaches, that are cognitively grounded, given our research on the brain,” Zemel said. “This will lead to the development of trustworthy systems that can explain their reasoning to end users in terms they understand. This is critical in high-stakes applications such as healthcare, law, and in support of vulnerable populations.” 

    Education and outreach

    The institute will provide educational and research opportunities for undergraduate and graduate students, as well as postdoctoral trainees, within and at the interface of AI, neuroscience, and cognitive science. Outreach partners, including the Neuromatch Academy and the New York Hall of Science, will help inform the public of these new developments and teach critical skills to the next generation of students.

    Columbia Engineering

    Since 1864, the Fu Foundation School of Engineering and Applied Science at Columbia University has been a resource to the world for major advances in human progress. Today, Columbia Engineering is a leading engineering school and a nexus for high-impact research. Embedded in New York City, the School convenes more than 250 faculty members and more than 6,000 undergraduate and graduate students from around the globe to push the frontiers of knowledge and solve humanity’s most pressing problems.

    Zuckerman Institute

    In collaboration with Columbia’s Zuckerman Institute, the ARNI team includes leading senior investigators and visionaries in the field of theoretical and cognitive neuroscience. The Zuckerman Institute brings together diverse researchers whose expertise spans a wide range of interdisciplinary neuroscience research areas, providing an unsurpassed intellectual environment, multi-level support, and opportunities for interaction.

    NSF

    The U.S. National Science Foundation propels the nation forward by advancing fundamental research in all fields of science and engineering. NSF supports research and people by providing facilities, instruments, and funding to support their ingenuity and sustain the U.S. as a global leader in research and innovation. With a fiscal year 2022 budget of $8.8 billion, NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities, and institutions. Each year, NSF receives more than 40,000 competitive proposals and makes about 11,000 new awards. Those awards include support for cooperative research with industry, Arctic and Antarctic research and operations, and U.S. participation in international scientific efforts. www.nsf.gov

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  • New Bacterial Therapy Approach to Treat Lung Cancer

    New Bacterial Therapy Approach to Treat Lung Cancer

     

    Newswise — New York, NY—December 23, 2022—Lung cancer is the deadliest cancer in the United States and around the world. Many of the currently available therapies have been ineffective, leaving patients with very few options. A promising new strategy to treat cancer has been bacterial therapy, but while this treatment modality has quickly progressed from laboratory experiments to clinical trials in the last five years, the most effective treatment for certain types of cancers may be in combination with other drugs. 

    Columbia Engineering researchers report that they have developed a preclinical evaluation pipeline for characterization of bacterial therapies in lung cancer models. Their new study, published December 13, 2022, by Scientific Reports, combines bacterial therapies with other modalities of treatment to improve treatment efficacy without any additional toxicity. This new approach was able to rapidly characterize bacterial therapies and successfully integrate them with current targeted therapies for lung cancer.

    “We envision a fast and selective expansion of our pipeline to improve treatment efficacy and safety for solid tumors,” said first author Dhruba Deb, an associate research scientist who studies the effect of bacterial toxins on lung cancer in Professor Tal Danino’s lab in Biomedical Engineering, “As someone who has lost loved ones to cancer, I would like to see this strategy move from the bench to bedside in the future.”

    The team used RNA sequencing to discover how cancer cells were responding to bacteria at the cellular and molecular levels. They built a hypothesis on which molecular pathways of cancer cells were helping the cells to be resistant to the bacteria therapy. To test their hypothesis, the researchers blocked these pathways with current cancer drugs and showed that combining the drugs with bacterial toxins is more effective in eliminating lung cancer cells. They validated the combination of bacteria therapy with an AKT-inhibitor as an example in mouse models of lung cancer.

    “This new study describes an exciting drug development pipeline that has been previously unexplored in lung cancer – the use of toxins derived from bacteria,” said Upal Basu Roy, executive director of research, LUNGevity Foundation, USA. “The preclinical data presented in the manuscript provides a strong rationale for continued research in this area, thereby opening up the possibility of new treatment options for patients diagnosed with this lethal disease.”

    Deb plans to expand his strategy to larger studies in preclinical models of difficult-to-treat lung cancers and collaborate with clinicians to make a push for the clinical translation. 

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    About the Study

    Journal: Scientific Reports

    The study is titled: “Design of combination therapy for engineered bacterial therapeutics in non-small cell lung cancer.”

    Authors are: Dhruba Deb 1, Yangfan Wu 1, Courtney Coker 1, Tetsuhiro Harimoto 1, Ruoqi Huang 1 & Tal Danino 1,2,3

    1 Department of Biomedical Engineering, Columbia Engineering
    2 Herbert Irving Comprehensive Cancer Center, Columbia University
    3 Data Science Institute, Columbia University

    The study was funded by the Pershing Square Foundation (PSF) PSSCRA CU20-0730 (T.D.), Cancer Research Institute (CRI) CRI 3446 (T.D.) and NIH-NIBIB RO1 EB029750 (T.D.). 

    The authors declare no financial or other conflicts of interest.

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    LINKS:

    Paper: https://www.nature.com/articles/s41598-022-26105-1   

    DOI: 10.1038/ s41598- 022- 26105-1  

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  • Tackling Crowd Management in Subways during Pandemics

    Tackling Crowd Management in Subways during Pandemics

    Newswise — Mass transit, and subways in particular, are essential to the economic viability and environmental sustainability of cities across the globe. But public transit was hit hard during the COVID pandemic and subways especially experienced substantial drops in ridership. Spurred on by a Columbia Engineering Transit Design Challenge in 2020, researchers from across the University have been collaborating on a project to strengthen both the preparedness and resilience of transit communities facing public health disasters.

    The team, led by Civil Engineering Professor Sharon Di, recently won a $2,500,000 four-year grant from the National Science Foundation to tackle crowd management in subways. The project–”Preparing for Future Pandemics: Subway Crowd Management to Minimize Airborne Transmission of Respiratory Viruses”–is focused on developing a system for public transit communities, including riders, workers, and agencies, that will help transit riders to make informed decisions and adapt travel behavior accordingly and provide transit agencies engaged in planning and policymaking with recommendations for mitigating virus transmission risks to riders and workers. 

    “We think our system, which we’re calling Way-CARE, will be transformative, especially for people in low-income communities who are among the most impacted by reduced accessibility to safer travel modes,” said Di, who is a leader in transportation management. “We expect our project to improve the social, economic, and environmental well-being of those who live, work, and travel within cities.” 

    The team, which includes Co-PIs Jeffrey Shaman (Columbia Climate School; Mailman School of Public Health); Marco Giometto, Xiaofan Jiang, and Faye McNeill (Columbia Engineering); Ester Fuchs (School of International and Public Affairs); and Kai Ruggeri (Columbia University Irving Medical Center), is working with New York City’s Metropolitan Transportation Authority and local rider communities in Harlem and at Columbia on the Way-CARE project. They hope that their system will enable smart city transit operators to access real-time sensing information collected from subway stations and/or trains for crowd management.

    The researchers are integrating sensing and crowd and airflow modeling with public health expertise on a microscale applied to subway crowd management. They are developing coupled airborne dispersion and epidemiological models that account for microscale processes–the transport of droplets and aerosols–that affect respiratory virus transmission. In addition, they are integrating behavioral science data that will help inform travel choices and policy making. 

    “This is an important interdisciplinary collaboration,” said Shaman, an epidemiologist who is a leader in infectious disease modeling. “The transmission of respiratory viruses is not directly observed, and the microscale processes influencing infection risk are not well known. Our project will address these shortcomings by advancing understanding of the physical, biological, and behavioral features that enable transmission of respiratory viruses in subway settings, and equip transit officials and the public with real-time information that improves worker and rider safety.”

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