News — New York, NY—September 17, 2021—Imagine having your own digital personal chef; ready to cook up whatever you want; able to tailor the shape, texture, and flavor just for you; and it’s all at the push of a button. have been working on doing just that, using lasers for cooking and 3D printing technology for assembling foods.

Under the guidance of Professor , the “Digital Food” team of his has been building a fully autonomous digital personal chef. Lipson’s group has been developing 3D-printed foods since 2007. Since then, food printing has progressed to multi-ingredient prints and has been explored by researchers and a few commercial companies. 

“We noted that, while printers can produce ingredients to a millimeter-precision, there is no heating method with this same degree of resolution,” said Jonathan Blutinger, a PhD in Lipson’s lab who led the project. “Cooking is essential for nutrition, flavor, and texture development in many foods, and we wondered if we could develop a method with lasers to precisely control these attributes.”

, the team explored various modalities of cooking by exposing blue light (445 nm) and infrared light (980 nm and 10.6 μm) to chicken, which they used as a model food system. They printed chicken samples (3 mm thick by ~1in2 area) as a test bed and assessed a range of parameters including cooking depth, color development, moisture retention, and flavor differences between laser-cooked and stove-cooked meat. They discovered that laser-cooked meat shrinks 50% less, retains double the moisture content, and shows similar flavor development to conventionally cooked meat. 

Video 01 

Robots that Cook: precision cooking with multiwavelength lasers

Video 02

Precision Cooking with Multiavelength Lasers: temperature data

 

“In fact, our two blind taste-testers preferred laser-cooked meat to the conventionally cooked samples, which shows promise for this burgeoning technology,” Blutinger said.

While Lipson and Blutinger are excited about the possibilities of this new technology, whose hardware and software components are fairly low-tech, they note that there is not yet a sustainable ecosystem to support it. Lipson states that “what we still don’t have is what we call ‘Food CAD,’ sort of the Photoshop of food. We need a high level software that enables people who are not programmers or software developers to design the foods they want. And then we need a place where people can share digital recipes, like we share music.”   

Still, says Blutinger, “Food is something that we all interact with and personalize on a daily basis--it seems only natural to infuse software into our cooking to make meal creation more customizable.” 

About the Study 

The paper is titled “Precision Cooking for Printed Foods via Multi-wavelength Lasers.”

Journal: npj Science of Food  

Authors are: Jonathan Blutinger, Alissa Tsai, Erika Storvick, Gabriel Seymour, Elise Liu, Noà Samarelli, Shravan Karthik, Yorán Meijers, and Hod Lipson, Departments of Mechanical Engineering and Computer Science, Columbia Engineering. 

This work was supported in part by Columbia University’s SEAS Interdisciplinary Research Seed (SIRS) funding program and by NSF NRI Award #1925157. 

The authors declare no financial or other conflicts of interest. 

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Video 01 -- Robots that Cook: precision cooking with multiwavelength lasers

Video 02 -- Precision Cooking with Multiavelength Lasers: temperature data

PROJECT WEBSITE: 

 

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Columbia Engineering

Columbia Engineering, based in New York City, is one of the top engineering schools in the U.S. and one of the oldest in the nation. Also known as The Fu Foundation School of Engineering and Applied Science, the School expands knowledge and advances technology through the research of its more than 220 faculty, while educating undergraduate and graduate students in a collaborative environment to become leaders informed by a firm foundation in engineering. School’s faculty are at the center of the University’s cross-disciplinary research, contributing to the Data Science Institute, Earth Institute, Zuckerman Mind Brain Behavior Institute, Precision Medicine Initiative, and the Columbia Nanμmo Initiative. Guided by its strategic vision, “Columbia Engineering for Humanity,” the School aims to translate ideas into innovations that foster a sustainable, healthy, secure, connected, and creative humanity.

 

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