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Blake pens and edits breaking news, articles and features on a broad range of scientific topics. He earned an honors degree in chemistry from the University of Surrey. Blake also holds an MSc in chemistry from the University of Southampton. His research project focused on the synthesis of novel fluorescent dyes often used as chemical/bio-sensors and as photosensitizers in photodynamic therapy.
The term “lab of the future” refers to the digitally connected and seamlessly integrated technologies being adopted by laboratories in an effort to reduce manual, repetitive tasks. At the heart of this technology lies artificial intelligence (AI) and machine learning (ML).
By leveraging innovative AI and ML solutions researchers hope to open new doors in data analysis, image processing and lab monitoring.
Download this infographic to:
Explore how AI can help draw conclusions from large datasets
Discover how AI is being utilized in a range of applications such as imaging, sequencing and drug discovery
Learn how labs are combining machine learning and robotics in the lab of the future
In the lab of the future researchers will be freed from manual, repetitive tasks allowing them to
focus on interpreting results and answering important scientific questions. The term “lab of the
future” refers to the digitally connected and seamlessly integrated technologies spearheading
this revolution.
At the heart of a lot of this
technology lies artificial
intelligence (AI), the simulation
of human intelligence processes
by machines, and machine
learning (ML), a subset of AI
that uses algorithms that are
“trained” to recognize patterns
and themes in datasets.
of corporate researchers say the impact of AI in
their area will be transformative or significant.
Leveraging innovative AI and ML solutions will open new doors in data
analysis, image processing and lab monitoring. This infographic outlines
a range of lab technologies that will benefit from incorporating AI.
71%
DATA MANAGEMENT
& ANALYSIS
AI-DRIVEN TECHNOLOGIES
IN THE LAB
Lab data output has increased exponentially as experiments have become more complex and
instruments more advanced. AI can help researchers analyze and draw conclusions from these
large datasets, while machine learning can recognize patterns present in datasets and make
predictions based on this.
A LIMS enables a lab to
track data associated with
samples, experiments, lab
workflows and instruments.
Incorporating AI into these
systems allows lab managers
to mine this data and make
informed decisions based on
prescriptive analytics. These
insights range from resource
management tips to maximize
efficiency to providing
predictive maintenance of
laboratory equipment.
Open-source lab software solutions use source code that is freely available to download, modify
and run. Open-source AI software has been developed for several lab applications. For example,
a research paper published in Nature Catalysis introduced RENAISSANCE, an AI-based tool
combining various types of cellular data to accurately depict metabolic states. The model’s code
is publicly available on GitHub, a cloud-based code repository.
AI when used with sensors and
LIMS systems can help monitor
laboratory environments in
real-time, for example, to detect
unusual temperature variations
within ultralow-temperature
freezers.
Predictive analytics approaches
have found use in technologies
such as HPLC, where researchers
have used AI models to make
predictions on the qualitative
properties of an anti-Alzheimer
agent, saving time and resources
that would usually be spent in
method development.
LABORATORY INFORMATION
MANAGEMENT SYSTEMS
(LIMS) REAL-TIME DATA
MONITORING
OPEN-SOURCE AI SOFTWARE
Image processing and analysis can be a laborious and complex task for researchers.
AI can streamline this process with applications spanning live cell analysis to diagnostics.
Deep learning models can
be used to train artificial
neural networks to analyze
microscopy images by
learning patterns and
structures from datasets.
This enables the models
to perform tasks such as
image segmentation, object
detection and classification
with increased precision.
AI-powered analysis
of medical images can
enhance diagnostic
accuracy and enable
clinicians to extract
additional information
from samples.
Real-time live cell analysis
enables the capture of
biological changes as they
occur, offering unique insights
essential to our understanding
of disease. However, analyzing
and interpreting the large
datasets acquired by live cell
analysis can be challenging. AIdriven
analysis can streamline
this workflow and recognize
patterns in data that the human
eye misses.
Researchers have combined X-ray
microcomputed tomography (microCT)
with machine learning segmentation to
digitally deconstruct leaves in 3D. The
method dramatically reduced the time
required to process single-leaf microCT
scans into detailed segmentations.
Boston University researchers created an
AI tool that combines commonly collected
patient data with neuroimaging data to
aid with the diagnosis of dementia. The
AI model was used to determine what
was causing a person’s cognitive decline
resulting in a 26% increase in the accuracy
of a doctor’s diagnosis.
NHS England has set up the NHS AI lab to develop, train and test AI
products for healthcare. This endeavor includes the development
of the National Medical Imaging Platform (NMIP), a centralized UK
database of medical images to support patient diagnostics.
A paper published in Nucleus
described a compendium of AI-based
strategies to analyze the spatial
distribution of nuclear and
chromosomal signals from 3D image
stacks acquired from microscopy.
MICROSCPOPY
MEDICAL IMAGING
LIVE CELL ANALYSIS
IMAGING & DIAGNOSTICS
SEQUENCING TECHNOLOGY
Genomics is a natural candidate for AI and ML
because of the sheer size of the datasets involved.
Whole-genome sequencing analysis is typically
complicated with numerous steps required to
identify genetic variants in a human genome. AI
software has now been developed that can predict
disease-causing genetic mutations.
Researchers have created a large language
model called Geneformer. This model takes
data on gene interactions from a broad
range of human tissues and transfers this
knowledge to predict how disruptions to
these networks may influence disease.
DRUG DISCOVERY
Identifying promising
drug targets and
designing new drug
compounds.
Identifying existing
drugs with the potential
to be repurposed for
other diseases.
Predicting the
absorption and
passage of a drug
through the body in
preclinical models.
Tools powered by AI have the potential to revolutionize drug discovery, particularly in the
screening of millions of potential target compounds. The potential applications of AI-powered
tools in drug discovery are vast and include:
ROBOTIC AUTOMATION
AI and ML are being incorporated into robotic
systems to improve how these robotics interact
with different environments. Using ML methods,
such as supervised learning, reinforcement learning
and generative AI, robots can be taught to perform
unique tasks within laboratory experiments.
AI-driven liquid handlers can adapt protocols based
on historical data and real-time feedback, optimizing
parameters for enhanced efficiency and accuracy.
A “self-driving” laboratory of robotic equipment
powered by a simple machine learning model has
successfully reengineered enzymes to be more
tolerable to heat without human input save for
hardware fixes.
THE FUTURE OF AI IN LAB
TECHNOLOGIES
Continuous improvement in AI models has led to the emergence of unique tools for combatting
a range of laboratory challenges. Organizations such as UK Research and Innovation (UKRI)
continue to invest in new AI research hubs, transforming the way labs utilize AI.
Sponsored by
Sentiments around AI use in the
lab are positive, as highlighted by
Elsevier’s “Insights 2024: Attitudes
toward AI” report. Despite this,
several concerns, such as the need
for skilled personnel to manage
AI systems and questions on how
to best integrate AI with existing
lab infrastructure, still need to be
addressed before AI-powered labs
of the future become commonplace.
of life sciences companies surveyed by the
nonprofit Pistoia Alliance in 2023 said that
AI/ML will be their top technology investment
over the next two years. 60%
Sponsored by
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