How can science benefit from AI?

Publication by the University of Bonn warns of misunderstandings in handling predictive algorithms

University of Bonn

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from Life Science Informatics at the University of Bonn. 

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Researchers from chemistry, biology, and medicine are increasingly turning to AI models to develop new hypotheses. However, it is often unclear on which basis the algorithms come to their conclusions and to what extent they can be generalized. A publication by the University of Bonn now warns of misunderstandings in handling artificial intelligence. At the same time, it highlights the conditions under which researchers can most likely have confidence in the models. The study has now been published in the journal Cell Reports Physical Science.

Adaptive machine learning algorithms are incredibly powerful. Nevertheless, they have a disadvantage: How machine learning models arrive at their predictions is often not apparent from the outside.

Suppose you feed artificial intelligence with photos of several thousand cars. If you now present it with a new image, it can usually identify reliably whether the picture also shows a car or not. But why is that? Has it really learned that a car has four wheels, a windshield, and an exhaust? Or is its decision based on criteria that are actually irrelevant – such as the antenna on the roof? If this were the case, it could also classify a radio as a car.

AI models are black boxes

“AI models are black boxes,” highlights Prof. Dr. Jürgen Bajorath. “As a result, one should not blindly trust their results and draw conclusions from them.” The computational chemistry expert heads the AI in Life Sciences department at the Lamarr Institute for Machine Learning and Artificial Intelligence. He is also in charge of the Life Science Informatics program at the Bonn-Aachen International Center for Information Technology (b-it) at the University of Bonn. In the current publication, he investigated the question of when one can most likely rely on the algorithms. And vice versa: When not.

The concept of “explainability” plays an important role in this context. Metaphorically speaking, this refers to efforts within AI research to drill a peephole into the black box. The algorithm should reveal the criteria that it uses as a basis – the four wheels or the antenna. “Opening the black box currently is a central topic in AI research,” says Bajorath. “ Some AI models are exclusively developed to make the results of others more comprehensible.”

Explainability, however, is only one aspect – the question of which conclusions might be drawn from the decision-making criteria chosen by a model is equally important. If the algorithm indicates that it has based its decision on the antenna, a human being knows immediately that this feature is poorly suited for identifying cars. Despite this, adaptive models are generally used to identify correlations in large data sets that humans might not even notice. We are then like aliens who do not know what makes a car: An alien would be unable to say whether or not an antenna is a good criterion.

Chemical language models suggest new compounds

“There is another question that we always have to ask ourselves when using AI procedures in science,” stresses Bajorath, who is also a member of the Transdisciplinary Research Area (TRA) “Modelling”: “How interpretable are the results?” Chemical language models currently are a hot topic in chemistry and pharmaceutical research. It is possible, for instance, to feed them with many molecules that have a certain biological activity. Based on these input data, the model then learns and ideally suggests a new molecule that also has this activity but a new structure. This is also referred to as generative modeling. However, the model can usually not explain why it comes to this solution. It is often necessary to subsequently apply explainable AI methods.

Nonetheless, Bajorath warns against over-interpreting these explanations, that is, anticipating that features the AI considers important indeed cause the desired activity. “Current AI models understand essentially nothing about chemistry,” he says. “They are purely statistical and correlative in nature and pay attention to any distinguishing features, regardless of whether these features might be chemically or biologically relevant or not.” In spite of this, they may even be right in their assessment – so perhaps the suggested molecule has the desired capabilities. The reasons for this, however, can be completely different from what we would expect based on chemical knowledge or intuition. For evaluating potential causality between features driving predictions and outcomes of corresponding natural processes, experiments are typically required: The researchers must synthesize and test the molecule, as well as other molecules with the structural motif that the AI considers important.

Plausibility checks are important

Such tests are time-consuming and expensive. Bajorath thus warns against over-interpreting the AI results in the search for scientifically plausible causal relationships. In his view, a plausibility check based on a sound scientific rationale is of critical importance: Can the feature suggested by explainable AI actually be responsible for the desired chemical or biological property? Is it worth pursuing the AI’s suggestion? Or is it a likely artifact, a randomly identified correlation such as the car antenna, which is not relevant at all for the actual function?

The scientist emphasizes that the use of adaptive algorithms fundamentally has the potential to substantially advance research in many areas of science. Nevertheless, one must be aware of the strengths of these approaches – and particularly of their weaknesses.

Publication: Jürgen Bajorath: From Scientific Theory to Duality of Predictive Artificial Intelligence Models; Cell Reports Physical Science; DOI: 10.1016/j.xcrp.2025.102516, Internet: https://www.sciencedirect.com/science/article/pii/S2666386425001158

From explaining predictions to capturing causal relationships. 

Credit

Image: Jürgen Bajorath/University of Bonn

Journal

Cell Reports Physical Science

DOI

10.1016/j.xcrp.2025.102516 

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

From Scientific Theory to Duality of Predictive Artificial Intelligence Models

Article Publication Date

3-Apr-2025

 

Energy giants back key CCUS breakthrough research

Heriot-Watt University

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The specialist Hydrate, Flow Assurance and Phase Equilibria (HFAPE) research group at Heriot-Watt University

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Scientists from Heriot-Watt University have secured new funding to investigate the thermodynamic behaviour of typical carbon capture, utilisation, and storage (CCUS) fluids. This research is critical for the safe and efficient processing, transportation, and storage of these fluids.

The two-year project aims to improve thermodynamic models to predict the phase behaviour of CO2 rich mixtures, specifically focusing on volatile organic compounds (VOCs) as the impurities.  The project outcomes will be pivotal in establishing optimum operational conditions throughout the CCUS chain as well as environmental compliance and proper CO2 storage.

In CCUS systems, VOCs are often found in the captured CO2 stream, primarily originating from the source of the CO2. VOCs include, for example, benzene, toluene, xylene (BTX), aldehydes (formaldehyde, acetaldehyde), and various hydrocarbons depending on the fuel source and capture conditions.  

Jointly funded by TotalEnergies and Equinor, the new research project builds on Heriot-Watt University’s long-standing expertise in CCUS research. Since the institution’s first CCUS related joint industry project (JIP) in 2011, led by Professor Antonin Chapoy, a specialist research group has developed advanced laboratories and cutting-edge expertise in experimental and modelling studies of the thermophysical properties of CCUS fluids. Today, the group collaborates with more than ten major CCUS operators worldwide through consultancy and research projects.

Dr Pezhman Ahmadi, project lead, is from the specialist Hydrate, Flow Assurance and Phase Equilibria (HFAPE) research group at Heriot-Watt University. He emphasised the importance of this research:

"For safety and technical reasons, understanding the thermodynamic behaviour of a fluid is key to its successful processing, transportation, and storage. In CCUS projects, where the working fluid is usually a CO2 rich mixture, the presence of impurities significantly influences the behaviour of the fluid in comparison to a pure CO2 stream. While thermodynamic models for pure CO2 are reliable thanks to abundant experimental data, impure CO2 streams, which are common in industry, pose challenges due to limited data and deficiencies in existing models. This project focuses on VOCs as a critical category of impurities so we can better understand the influence of this type of impurities and address this data gap."

Heriot-Watt’s Professor Antonin Chapoy, project co-lead, has extensive experience in leading CCUS projects for the research group. He added: "Our modelling studies, underpinned by experimental capabilities and expertise, provide precise thermodynamic models that improve the safety, technical and economic aspects of CCUS operations. These models help reduce operational risks, such as hydrate or dry ice formation, and minimise costs while enhancing efficiency in the transportation and storage of CO2-rich fluids. Over the years, our work has supported major CCUS operators in achieving safer and more cost-effective operations."

The group's expertise was recently showcased through its involvement in the Northern Lights project, Norway's pioneering carbon storage initiative that opened in September 2024. The technical contributions made by this group of researchers were critical in ensuring the safe transportation and storage of CO2, with the team providing essential data on fluid behaviour under varying conditions.

Professor Chapoy continues: "Our contributions to CCS projects and our extensive expertise underscore the importance of understanding thermodynamic properties of CCUS fluids for the long-term success of decarbonisation projects. With 14 years of focused research on this topic, our team continues to develop practical solutions to accelerate industry’s net-zero transition. This new project exemplifies our commitment to supporting global decarbonisation efforts. We are grateful for the support of TotalEnergies and Equinor in driving this critical research forward."

Ends

CRIMINAL CRYPTO CAPITALI$M

Mathematicians uncover the hidden patterns behind a $3.5 billion cryptocurrency collapse

The study reveals coordinated attack behind TerraUSD crash

Queen Mary University of London

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In a new study published in ACM Transactions on the Web, researchers from Queen Mary University of London have unveiled the intricate mechanisms behind one of the most dramatic collapses in the cryptocurrency world: the downfall of the TerraUSD stablecoin and its associated currency, LUNA. Using advanced mathematical techniques and cutting-edge software, the team has identified suspicious trading patterns that suggest a coordinated attack on the ecosystem, leading to a catastrophic loss of $3.5 billion in value virtually overnight. 

The study, led by Dr Richard Clegg and his team, employs temporal multilayer graph analysis — a sophisticated method for examining complex, interconnected systems over time. This approach allowed the researchers to map the relationships between different cryptocurrencies traded on the Ethereum blockchain, revealing how the TerraUSD stablecoin was destabilised by a series of deliberate, large-scale trades. 

Stablecoins like TerraUSD are designed to maintain a steady value, typically pegged to a fiat currency like the US dollar. However, in May 2022, TerraUSD and its sister currency, LUNA, experienced a catastrophic collapse. Dr Clegg’s research sheds light on how this happened, uncovering evidence of a coordinated attack by traders who were betting against the system, a practice known as "shorting." 

“What we found was extraordinary,” says Dr Clegg. “On the days leading up to the collapse, we observed highly unnatural trading patterns. Instead of the usual spread of transactions across hundreds of traders, we saw a handful of individuals controlling almost the entire market. These patterns are the smoking gun evidencing of a deliberate attempt to destabilise the system.” 

The team’s analysis revealed that on key dates, just five or six traders accounted for nearly all the trading activity, with each controlling almost exactly the same share of the market. This level of coordination is virtually impossible by chance in a normal trading environment and strongly suggests that these individuals were working together to trigger the collapse. 

The research not only provides insights into the TerraUSD collapse but also introduces a powerful new tool for analysing cryptocurrency markets. The team’s software, developed in collaboration with Pometry a spin-out company from Queen Mary University, uses graph network analysis to visualise and interpret complex trading data. This tool could prove invaluable for regulators, investors, and researchers seeking to understand and mitigate risks in the volatile world of cryptocurrency. 

“Cryptocurrencies are often seen as the Wild West of finance, with little oversight and even less accountability,” says Dr Clegg. “Our work shows that by applying rigorous mathematical techniques, we can uncover the hidden patterns and behaviours that drive these markets. This isn’t just about understanding what went wrong in the past — it’s about building a safer, more transparent financial system for the future.” 

The implications of this research extend far beyond the world of cryptocurrency. The methods developed by Dr Clegg and his team could be applied to a wide range of complex systems, from financial markets to social networks. For regulatory agencies, this work offers a new way to monitor and safeguard against systemic risks, protecting both individual investors and the broader economy. 

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Journal

ACM Transactions on the Web

DOI

10.1145/3726869 

Article Title

Investigating the Luna-Terra Collapse through the Temporal Multilayer Graph Structure of the Ethereum Stablecoin Ecosystem

 

ACP’s Best Practice Advice addresses use of cannabis, cannabinoids for chronic noncancer pain

American College of Physicians

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NEW ORLEANS April 4, 2025 – The American College of Physicians (ACP) has issued Best Practice Advice for clinicians whose patients are considering or using cannabis or cannabinoids for management of chronic, noncancer pain. Cannabis or Cannabinoids for the Management of Chronic Noncancer Pain: Best Practice Advice From the American College of Physicians, was published today in Annals of Internal Medicine. 

 

ACP’s Best Practice Advice paper is intended to inform clinicians about the evidence regarding the benefits and harms of cannabis or cannabinoids in the management of chronic noncancer pain and to provide advice for clinicians counseling patients seeking to use cannabis or cannabinoids for chronic noncancer pain. 

 

Cannabis use for medicinal purposes has grown among patients with chronic noncancer pain. When referring to any product derived from the plant, many use the term cannabis, but the term has become interchangeable with colloquial terms such as marijuana, weed, and pot. As of 2024, 24 states in the U.S. and the District of Columbia have legalized cannabis for adult recreational and medical use, and it is legal for medical use only in an additional 14 states. 

 

In its Best Practice Advice ACP says clinicians should: 

 

• Counsel patients about the benefits and harms of cannabis or cannabinoids when patients are considering whether to start or continue to use cannabis or cannabinoids to manage their chronic noncancer pain.  

• Counsel the following subgroups of patients that the harms of cannabis or cannabinoid use for chronic noncancer pain are likely to outweigh the benefits: 

  • Young adult and adolescent patients 

  • Patients with current or past substance use disorders 

  • Patients with serious mental illness  

  • Frail patients and those at risk of falling  

• Advise against starting or continuing to use cannabis or cannabinoids to manage chronic noncancer pain in patients who are pregnant or breastfeeding or actively trying to conceive. 

• Advise patients against the use of inhaled cannabis to manage chronic noncancer pain. 

 

“This Best Practice Advice is important for practicing physicians when counseling our patients on the potential use of cannabis and cannabinoids to treat their chronic noncancer pain,” said Isaac O. Opole, President, ACP. “As the use of cannabis for medicinal purposes grows it’s critical to open that dialogue and review the emerging evidence related to benefits and harms. We need to raise awareness and get the word out to ensure that patients have the information they need to make informed decisions.” 

 

For many patients, evidence suggests that the known harms of cannabis and cannabinoid use outweigh the potentially small degree of benefit to ease chronic noncancer pain. Additionally, cannabis can be addictive, even if being used to manage chronic noncancer pain. It’s also difficult to apply the information from clinical studies to practice in the U.S. because the potency (delta-9 tetrahydrocannabinol or THC content) of products in dispensaries is typically far higher than that used in studies. Another challenge is that in most U.S. states, patients will obtain cannabis for chronic pain through a dispensary with less medical oversight than they would receive for FDA-approved medications.   

Clinicians are best positioned to provide evidence-based information about the benefits and harms most relevant to an individual patients’ needs and comorbidities so that patients can make an informed decision about starting or continuing cannabis or cannabinoid use for chronic noncancer pain.  For most patients, common treatments and analgesic medications should be recommended first given the limited evidence of small benefit and the known harms associated with cannabis and cannabinoid products.     

ACP has also published a position paper where it recommends a public health approach to address the legal, medical, and social complexities of cannabis use. 

 

This Best Practice Advice is based on a review and assessment of scientific work including a living, systematic review on cannabis and cannabinoid treatments for chronic noncancer pain, a series of living systematic reviews, as well as additional evidence from primary studies. 

 

*** 

About the American College of Physicians 
The American College of Physicians is the largest medical specialty organization in the United States with members in more than 172 countries worldwide. ACP membership includes 161,000 internal medicine physicians, related subspecialists, and medical students. Internal medicine physicians are specialists who apply scientific knowledge and clinical expertise to the diagnosis, treatment, and compassionate care of adults across the spectrum from health to complex illness. Follow ACP on X, Facebook, Instagram, Threads, and LinkedIn. 

 

ACP Media Contact: Andrew Hachadorian, (215) 351-2514, AHachadorian@acponline.org 

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Journal

Annals of Internal Medicine

DOI

10.7326/ANNALS-24-03319 

Method of Research

News article

Subject of Research

People

Article Title

Cannabis or Cannabinoids for the Management of Chronic Non-Cancer Pain: Best Practice Advice from the American College of Physicians

Article Publication Date

4-Apr-2025

 

Beyond photorespiration: A systematic approach to unlocking enhanced plant productivity

New research from GAIN4CROPS project provides critical insights into overcoming one of agriculture's most costly inefficiencies.

INsociety

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A groundbreaking study published in Science Advances has revealed promising strategies to significantly improve crop yields by addressing photorespiration, a metabolic process that can reduce productivity by up to 36% in some crops. Researchers from the University of Groningen and Heinrich Heine University Düsseldorf, working as part of the GAIN4CROPS project (gain4crops.eu), have evaluated several alternative pathways that could help overcome this major agricultural bottleneck.

Photorespiration occurs when the enzyme RuBisCO, essential for photosynthesis, reacts with oxygen instead of carbon dioxide, resulting in substantial losses of fixed carbon and energy. This inefficiency costs the global agricultural sector billions in lost crop productivity annually.

"Our work shows that overcoming photorespiration through engineered pathways can provide a dual benefit: increasing carbon fixation while reducing energy losses," said Prof. Heinemann from the University of Groningen, "This has significant implications for the development of crops that are not only more productive but also better adapted to the changing climate and growing global food demands."

The study employed advanced mathematical models to analyze twelve alternative pathways designed to bypass or optimize photorespiration. The researchers classified these pathways based on their carbon-fixing abilities and identified which approaches offer the greatest potential improvements in different environmental conditions.

Key findings include:

• Carbon-fixing alternative pathways showed the most promise, offering up to 20% more carbon export compared to conventional photorespiration
• The TaCo pathway, developed in another EU-funded project called FutureAgriculture and now used in projects such as GAIN4CROPS and CROP4CLIMA, demonstrated substantial potential for yield improvement
• Environmental factors such as light intensity and CO2 availability significantly influence the effectiveness of different pathways
• Carbon-fixing pathways achieve optimal productivity under both high light and CO2-limited conditions

The research also provides new insights that could help explain previous experimental observations and guides future efforts to engineer crops with reduced photorespiration losses.

"With the ability to more rationally engineer alternative photorespiratory pathways into suitable crops and identify their optimal growing conditions, our work will hopefully contribute to realizing the maximum impact of alternative photorespiratory pathways for improving crop yields," noted Prof. Weber, coordinator of the GAIN4CROPS project from the Heinrich Heine University Düsseldorf.

Next steps include further optimization of the alternative pathways and application to crops with the greatest potential for yield improvement. These advancements could play a crucial role in addressing global challenges such as food security and climate change adaptation.

The full study, titled “Alternatives to photorespiration: A system-level analysis reveals mechanisms of enhanced plant productivity” is available in open access in Science Advances (https://www.science.org/doi/10.1126/sciadv.adt9287).

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Journal

Science Advances

DOI

10.1126/sciadv.adt9287 

Subject of Research

Not applicable

Article Title

Alternatives to photorespiration: A system-level analysis reveals mechanisms of enhanced plant productivity