New tool exposes scale of fake research flooding cancer science

Queensland University of Technology

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Professor Adrian Barnett

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Credit: Photo supplied by QUT.

A new machine learning tool has identified more than 250,000 cancer research papers that may have been produced by so-called “paper mills”.

Developed by QUT researcher Professor Adrian Barnett, from the School of Public Health and Social Work and Australian Centre for Health Services and Innovation (AusHSI), and an international team of collaborators, the study, published in The BMJ, analysed 2.6 million cancer studies from 1999 to 2024.

It found more than 250,000 papers with writing patterns similar to articles already retracted for suspected fabrication.

“Paper mills are companies that sell fake or low-quality scientific studies. They are producing ‘research’ on an industrial scale, and our findings suggest the problem in cancer research is far larger than most people realised,” Professor Barnett said.

Selling authorships and entire ready-made research papers, paper mills often use recycled text, awkward phrasing or fabricated data and images.

“Most likely, they’re relying on boilerplate templates which can be detected by large language models that analyse patterns in texts,” Professor Barnett said.

He and his team trained a language model called BERT to recognise the subtle textual “fingerprints” that repeatedly appear across known paper-mill products.

When tested on verified examples, the model correctly identified suspicious papers 91 per cent of the time.

“We’ve essentially built a scientific spam filter,” Professor Barnett said.

“Just like your email system can spot unwanted messages, our tool flags papers that match the writing style and structure we see in retracted, fraudulent work.”

Key findings from the large-scale analysis include:

• Flagged papers have increased dramatically over two decades, rising from around 1 per cent in the early 2000s and peaking at over 16 per cent in 2022.
• The issue affects thousands of journals across major publishers, including high-impact titles.
• The problem is most concentrated in fields such as molecular cancer biology and early-stage laboratory research.
• Some cancer types, including gastric, liver, bone and lung cancer, show especially high rates of suspicious papers.

Three scientific journals are already piloting the tool as part of their editorial screening. It will allow editors to identify potentially fabricated manuscripts before they are sent for peer review.

The team plans to expand the tool to other fields of research and improve the model as more confirmed cases of paper-mill activity become available. They stress the findings are not confirmed cases of research fraud and should be checked by human specialists.

“Cancer research influences clinical trials, drug development and patient care,” Professor Barnett said.

“If fabricated studies make their way into the evidence base, they can mislead real scientists and ultimately slow progress for patients. That’s why it’s vital we get ahead of this problem.”

Read the full paper, Machine Learning-Based Screening of Potential Paper Mill Publications in Cancer Research: Methodological and Cross-Sectional Study, in The BMJ, online.

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Journal

BMJ

DOI

10.1136/bmj-2025-087581 

Article Title

Machine Learning-Based Screening of Potential Paper Mill Publications in Cancer Research: Methodological and Cross-Sectional Study

Article Publication Date

30-Jan-2026

 

Kandahar University highlights global disparities in neurosurgical workforce and access to care

Article outlines workforce shortages, systemic barriers, and policy strategies affecting neurosurgical care worldwide

Chinese Neurosurgical Journal

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Surgeons prepare for a procedure in a hospital operating room, illustrating the clinical workforce central to neurosurgical care.

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Credit: Image credit: U.S. Navy Medicine, via Openverse | Image source link: https://openverse.org/image/38857a24-d882-4553-b5b8-d910556e6f3d

Neurological disorders contribute to nearly nine million deaths globally each year, and an estimated 22.6 million new cases require neurosurgical attention annually, of which approximately 13.8 million require surgical intervention. Despite this burden, access to safe and timely neurosurgical care remains limited for more than two-thirds of the world’s population, particularly in low- and middle-income countries (LMICs). This gap has increasingly been recognized as a major global public health concern.

A new article, published on November 20, 2025, in the print and online versions of the Chinese Neurosurgical Journal, authored by researchers from Kandahar University, led by Dr. Ehsanullah Alokozay,  discusses global neurosurgical workforce shortages, systemic barriers, and policy strategies shaping access to care worldwide.

A central challenge identified is the global shortage of trained neurosurgeons. Current estimates suggest a deficit of approximately 23,300 neurosurgeons worldwide, with the most severe shortages concentrated in Africa and Southeast Asia. Many countries remain below the minimum workforce target of 0.5 neurosurgeons per 100,000 population, a level widely regarded as necessary to meet essential neurosurgical needs. If current trends persist, more than half of LMICs are projected to miss this benchmark.

“The correspondence emphasizes that increasing workforce numbers alone will be insufficient to address these gaps. Structural barriers continue to limit training, retention, and career progression, particularly in LMICs,” highlights Dr. Alokozay. Limited access to advanced training, insufficient funding, lack of structured mentorship, and significant work–life imbalance—reported by approximately 87–90% of early-career neurosurgeons—are commonly cited challenges, particularly in LMICs. These factors contribute to burnout and undermine long-term workforce sustainability.

Beyond structural limitations, persistent inequities related to gender and race further constrain workforce development. Disparities in career advancement highlight the need for more inclusive professional environments that support retention and leadership development. According to the authors, addressing these inequities is essential for building a resilient neurosurgical workforce capable of meeting rising global demand.

To reduce disparities, the authors point to policy-level and system-level strategies that embed neurosurgical care within broader health planning. Integration of neurosurgical services into National Surgical, Obstetric, and Anesthesia Plans is highlighted as a key recommendation, aligned with priorities outlined in the Boston Declaration 2025. Such integration allows workforce development and service delivery to be aligned with long-term national health strategies.

Global policy initiatives, including the World Health Organization’s Intersectoral Global Action Plan on epilepsy and other neurological disorders, further reinforce the importance of integrating neurological and neurosurgical care into primary health systems. Alignment with these frameworks supports coordinated investment, accountability, and evidence-based decision-making.

Telemedicine is also presented as a complementary approach to expanding access to neurosurgical expertise. Remote consultations, virtual training, and postoperative follow-up have shown potential to reduce travel burdens and improve continuity of care. However, the authors note that infrastructure limitations, regulatory challenges, and workforce capacity constraints remain significant barriers in many LMICs.

The correspondence concludes that closing gaps in global neurosurgical care will require sustained investment, evidence-driven policy reform, and coordinated global collaboration. “Strengthening the neurosurgical workforce, addressing systemic barriers, and embedding neurosurgical services within broader health frameworks are identified as critical steps toward achieving equitable access to care worldwide,” concludes Dr. Alokozay.

 

Reference

DOI: 10.1186/s41016-025-00419-1

 

About Kandahar University

Kandahar University is a public higher education institution in Kandahar, Afghanistan, established in 1990 under the Ministry of Higher Education. It offers undergraduate and postgraduate programs across disciplines, including medicine, engineering, agriculture, law, economics, education, and computer science, serving as a key academic hub in southern Afghanistan.

 

About Dr. Ehsanullah Alokozay from Kandahar University

Dr. Ehsanullah Alokozay is a medical academic and researcher affiliated with the Faculty of Medicine, Kandahar University, Afghanistan. His scholarly work focuses on clinical medicine and global public health, with particular attention to healthcare access and workforce disparities in low-resource settings. He has contributed to peer-reviewed international journals, including correspondence and research articles addressing maternal health outcomes and neurosurgical workforce inequities. Through his research, Alokozay highlights structural gaps in healthcare delivery in Afghanistan and comparable regions, aiming to inform policy discussions and strengthen evidence-based medical practice in resource-limited health systems.

 

Funding information

This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

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Journal

Chinese Neurosurgical Journal

DOI

10.1186/s41016-025-00419-1 

Method of Research

Commentary/editorial

Subject of Research

Not applicable

Article Title

Addressing global disparities in neurosurgical workforce and access to care

 

Breathing new life into nanotubes for a cooler planet

Researchers at Skoltech discover a simple, single-step heat treatment that nearly doubles the CO2-trapping power of carbon nanotubes

Biochar Editorial Office, Shenyang Agricultural University

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Single-step thermal treatment of single-walled carbon nanotubes for enhanced CO2 adsorption capacity

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Credit: Amit Kumar Pal, Dmitry V. Krasnikov, Liubov A. Varlamova, Konstantin K. Zamansky, Kseniya A. Litvintseva, Sergei V. Porokhin, Nikita E. Gordeev, Anastasia E. Goldt, Eugene E. Nazarov, Stanislav S. Fedotov, Pavel B. Sorokin & Albert G. Nasibulin

The fight against climate change relies heavily on finding better ways to capture carbon dioxide before it escapes into our atmosphere. While carbon nanotubes have long been seen as a "wonder material" for this task, their internal structures are often locked away like a closed pipe. Now, a research team from the Skolkovo Institute of Science and Technology (Skoltech) has pioneered a deceptively simple way to pop those caps open and supercharge their adsorption capacity.

In a study published in Carbon Research, the team reveals that a straightforward thermal treatment, essentially "baking" single-walled carbon nanotubes (SWCNTs) in ambient air, can dramatically expand their available surface area. By heating the tubes at 400 °C for four hours, the researchers nearly doubled the specific surface area from 448 to 858 m²/g. This breakthrough is led by corresponding authors Dmitry V. Krasnikov and Albert G. Nasibulin, both prominent researchers at Skoltech in Moscow. Their work focuses on making high-performance nanomaterials more practical and scalable for global environmental applications.

"The secret lies in the accessibility of the nanotubes," explains the team. The heat treatment does two critical things: it oxidizes leftover catalyst particles and burns away the carbon "caps" at the ends of the tubes. This exposes the inner channels of the nanotubes, providing extensive surface area for CO2 molecules to settle.

Why This Matters for Carbon Capture:

1. Efficiency Boost: In dynamic breakthrough tests, the thermally treated nanotubes reached a CO2 uptake of 5.0 mmol/g, an 85% improvement over untreated samples.
2. Simplicity is Key: Unlike complex chemical purification processes that can cause nanotubes to clump together (bundling), this single-step thermal method keeps the surface accessible and active.
3. Precision Science: By comparing experimental data with Monte-Carlo and geometric simulations, the researchers were able to pinpoint exactly how CO2 molecules interact with these nano-surfaces, confirming that the "opened" tubes are far more effective at trapping gas.

The Skolkovo Institute of Science and Technology has become a hub for such advanced material science. The work of Krasnikov and Nasibulin underscores the institute's commitment to developing scalable, evidence-based solutions for the ongoing climate crisis. By showing that a simple heating process can transform raw nanocarbon into a high-capacity sponge for greenhouse gases, they have provided a vital tool for the next generation of carbon capture technology. As industries look for cost-effective ways to lower their emissions, this Skoltech-led innovation offers a clear path forward: sometimes, the most effective solution is as simple as turning up the heat.

Corresponding Authors:

Dmitry V. Krasnikov Skolkovo Institute of Science and Technology, Moscow, Russia

Albert G. Nasibulin Skolkovo Institute of Science and Technology, Moscow, Russia

 

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Journal reference:  Pal, A.K., Krasnikov, D.V., Varlamova, L.A. et al. Single-step thermal treatment of single-walled carbon nanotubes for enhanced CO2 adsorption capacity. Carbon Res. 5, 2 (2026).   

https://doi.org/10.1007/s44246-025-00246-0  

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About Carbon Research

The journal Carbon Research is an international multidisciplinary platform for communicating advances in fundamental and applied research on natural and engineered carbonaceous materials that are associated with ecological and environmental functions, energy generation, and global change. It is a fully Open Access (OA) journal and the Article Publishing Charges (APC) are waived until Dec 31, 2025. It is dedicated to serving as an innovative, efficient and professional platform for researchers in the field of carbon functions around the world to deliver findings from this rapidly expanding field of science. The journal is currently indexed by Scopus and Ei Compendex, and as of June 2025, the dynamic CiteScore value is 15.4.

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Journal

Carbon Research

DOI

10.1007/s44246-025-00246-0 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Single-step thermal treatment of single-walled carbon nanotubes for enhanced CO2 adsorption capacity

Article Publication Date

28-Jan-2026