Tag Archives: cyborg soil

Internet of living things (IoLT)?

Leave a reply

It’s not here yet but there are scientists working on an internet of living things (IoLT). There are some details (see the fourth paragraph from the bottom of the news release excerpt) about how an IoLT would be achieved but it seems these are early days. From a September 9, 2021 University of Illinois news release (also on EurekAlert), Note: Links have been removed,

The National Science Foundation (NSF) announced today an investment of $25 million to launch the Center for Research on Programmable Plant Systems (CROPPS). The center, a partnership among the University of Illinois at Urbana-Champaign, Cornell University, the Boyce Thompson Institute, and the University of Arizona, aims to develop tools to listen and talk to plants and their associated organisms.

“CROPPS will create systems where plants communicate their hidden biology to sensors, optimizing plant growth to the local environment. This Internet of Living Things (IoLT) will enable breakthrough discoveries, offer new educational opportunities, and open transformative opportunities for productive, sustainable, and profitable management of crops,” says Steve Moose (BSD/CABBI/GEGC), the grant’s principal investigator at Illinois. Moose is a genomics professor in the Department of Crop Sciences, part of the College of Agricultural, Consumer and Environmental Sciences (ACES). 

As an example of what’s possible, CROPPS scientists could deploy armies of autonomous rovers to monitor and modify crop growth in real time. The researchers created leaf sensors to report on belowground processes in roots. This combination of machine and living sensors will enable completely new ways of decoding the language of plants, allowing researchers to teach plants how to better handle environmental challenges. 

“Right now, we’re working to program a circuit that responds to low-nitrogen stress, where the plant growth rate is ‘slowed down’ to give farmers more time to apply fertilizer during the window that is the most efficient at increasing yield,” Moose explains.

With 150+ years of global leadership in crop sciences and agricultural engineering, along with newer transdisciplinary research units such as the National Center for Supercomputing Applications (NCSA) and the Center for Digital Agriculture (CDA), Illinois is uniquely positioned to take on the technical challenges associated with CROPPS.

But U of I scientists aren’t working alone. For years, they’ve collaborated with partner institutions to conceptualize the future of digital agriculture and bring it into reality. For example, researchers at Illinois’ CDA and Cornell’s Initiative for Digital Agriculture jointly proposed the first IoLT for agriculture, laying the foundation for CROPPS.

“CROPPS represents a significant win from having worked closely with our partners at Cornell and other institutions. We’re thrilled to move forward with our colleagues to shift paradigms in agriculture,” says Vikram Adve, Donald B. Gillies Professor in computer science at Illinois and co-director of the CDA.

CROPPS research may sound futuristic, and that’s the point.

The researchers say new tools are needed to make crops productive, flexible, and sustainable enough to feed our growing global population under a changing climate. Many of the tools under development – biotransducers small enough to fit between soil particles, dexterous and highly autonomous field robots, field-applied gene editing nanoparticles, IoLT clouds, and more – have been studied in the proof-of-concept phase, and are ready to be scaled up.

“One of the most exciting goals of CROPPS is to apply recent advances in sensing and data analytics to understand the rules of life, where plants have much to teach us. What we learn will bring a stronger biological dimension to the next phase of digital agriculture,” Moose says. 

CROPPS will also foster innovations in STEM [science, technology[ engineering, and mathematics] education through programs that involve students at all levels, and each partner institution will share courses in digital agriculture topics. CROPPS also aims to engage professionals in digital agriculture at any career stage, and learn how the public views innovations in this emerging technology area.

“Along with cutting-edge research, CROPPS coordinated educational programs will address the future of work in plant sciences and agriculture,” says Germán Bollero, associate dean for research in the College of ACES.

I look forward to hearing more about IoLT.

Cyborg soil?

Leave a reply

Edith Hammer, lecturer (Biology) at Lund University (Sweden) has written a July 22, 2021 essay for The Conversation (h/t July 23, 2021 news item on phys.org) that has everything.: mystery, cyborgs, unexpected denizens, and a phenomenon explored for the first time (Note: Links have been removed),

Dig a teaspoon into your nearest clump of soil, and what you’ll emerge with will contain more microorganisms than there are people on Earth. We know this from lab studies that analyse samples of earth scooped from the microbial wild to determine which forms of microscopic life exist in the world beneath our feet.

The problem is, such studies can’t actually tell us how this subterranean kingdom of fungi, flagellates and amoebae operates in the ground. Because they entail the removal of soil from its environment, these studies destroy the delicate structures of mud, water and air in which the soil microbes reside.

This prompted my lab to develop a way to spy on these underground workers, who are indispensable in their role as organic matter recycling agents, without disturbing their micro-habitats.

Our study revealed the dark, dank cities in which soil microbes reside [emphasis mine]. We found labyrinths of tiny highways, skyscrapers, bridges and rivers which are navigated by microorganisms to find food, or to avoid becoming someone’s next meal. This new window into what’s happening underground could help us better appreciate and preserve Earth’s increasingly damaged soils.

Here’s how the soil scientists probed the secrets buried in soil (Note: A link has been removed),

In our study, we developed a new kind of “cyborg soil”, which is half natural and half artificial. It consists of microengineered chips that we either buried in the wild, or surrounded with soil in the lab for enough time for the microbial cities to emerge within the mud.

The chips literally act like windows to the underground. A transparent patch in the otherwise opaque soil, the chip is cut to mimic the pore structures of actual soil, which are often strange and counter-intuitive at the scale that microbes experience them.

Different physical laws become dominant at the micro scale compared to what we’re acquainted to in our macro world. Water clings to surfaces, and resting bacteria get pushed around by the movement of water molecules. Air bubbles form insurmountable barriers for many microorganisms, due to the surface tension of the water around them.

Here’s some of the what they found,

When we excavated our first chips, we were met with the full variety of single-celled organisms, nematodes, tiny arthropods and species of bacteria that exist in our soils. Fungal hyphae, which burrow like plant roots underground, had quickly grown into the depths of our cyborg soil pores, creating a direct living connection between the real soil and our chips.

This meant we could study a phenomenon known only from lab studies: the “fungal highways” along which bacteria “hitchhike” to disperse through soil. Bacteria usually disperse through water, so by making some of our chips air-filled we could watch how bacteria smuggle themselves into new pores by following the groping arms of fungal hyphae.

Unexpectedly, we also found a high number of protists – enigmatic single-celled organisms which are neither animal, plant or fungus – in the spaces around hyphae. Clearly they too hitch a ride on the fungal highway – a so-far completely unexplored phenomenon.

The essay has a number of embedded videos and images illustrating a fascinating world in a ‘teaspoon of soil’.

Here’s a link to and a citation for the study by the researchers at Lund University,

Microfluidic chips provide visual access to in situ soil ecology by Paola Micaela Mafla-Endara, Carlos Arellano-Caicedo, Kristin Aleklett, Milda Pucetaite, Pelle Ohlsson & Edith C. Hammer. Communications Biology volume 4, Article number: 889 (2021) DOI: https://doi.org/10.1038/s42003-021-02379-5 Published: 20 July 2021

This paper is open access.