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Electrical signals exist in many places in the human body, and are used for communication from and to the brain. They are employed to e.g. contract a muscle. We use computer simulations in order to better understand how the heart and other organs work, and to develop medical devices for diagnosis of, among others, heart disease. We combine expertise in signal processing and machine-learning method

https://www.bme.lth.se/en/research/biomedical-signal-processing - 2026-06-09

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https://www.bme.lth.se/en/research/nanobiotechnology-and-lab-chip/pelle-ohlsson-group/group-members - 2026-06-09

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https://www.bme.lth.se/en/research/nanobiotechnology-and-lab-chip/pelle-ohlsson-group/publications - 2026-06-09

We invent tomorrow’s microfluidic chips for medical diagnostics, biological research and agriculture, for instance finding bacteria in blood samples using ultrasound or crop pathogens in soil using AI-based image analysis. Finding bacteria in blood for sepsis diagnosticsSepsis is a systemic response to an infection and can be deadly. It is most often caused by bacteria, but concentrations of the c

https://www.bme.lth.se/en/research/nanobiotechnology-and-lab-chip/pelle-ohlsson-group - 2026-06-09

September 21-22 The 2026 edition has a sustainability theme. Join us for two days of talks, activities, and poster presentations. Register here!   Program Monday September 21st10:00 Registration10:30 Welcome Address10:45 Keynote Speaker Martina Kvist Reimer (industry/Region Skåne):Connecting the Dots: A Systems View on Sustainability in Life Science research11:30 Workshop/discussion12:00 Lunch13:3

https://www.bme.lth.se/en/engineering-health-annual-meetingoldnarrow - 2026-06-09

Biological mass spectrometry is an important tool in modern biomedical research, providing detailed insights into the molecular composition of cells, tissues, and biofluids. Through sensitive and large-scale analysis of proteins and small molecules, mass spectrometry (MS) contributes to understanding biological processes and disease mechanisms beyond what can be inferred from genomic data alone. O

https://www.bme.lth.se/en/research/biological-mass-spectrometry - 2026-06-09

LU BildbankLU BoxCANVASEDU-signEPICFU-kurserIA-systemetKalenderdelningKubenLADOKLUCATLUCRISLUPIN/ProceedoPrimulaSupport Center, LUTimeEditVarbiWebmailZoom 

https://www.bme.lth.se/en/internal-link-collection - 2026-06-09

The first clinical application of ultrasound for diagnostic purposes was developed in Lund in 1953, when the physicist Hellmuth Hertz and the cardiologist Inge Edler were the first to analyze the motion of heart valves. Since then, the technology has undergone extensive development and is now the most widely used imaging modality in healthcare. Our group conducts research, develops, and evaluates

https://www.bme.lth.se/en/research/ultrasound/biomedical-ultrasound - 2026-06-09

We develop technology to manipulate and study cells and organisms. These miniaturized tools have a range of applications in cancer diagnostics, blood transfusions, fungal studies, and neurobiology. Many of our activities fall within the research field of acoustofluidics where ultrasound generates forces on cells or nanoparticles inside microchannel networks. These systems can sort out specific sub

https://www.bme.lth.se/en/research/nanobiotechnology-and-lab-chip - 2026-06-09

10 June 2026 09:00 | Thesis defence Edvin Tobias Bokvist Wrammerfors defends his thesis "Exploring Synchrotron and Neutron Techniques for Characterizing Soft Knee Tissues". Link to thesis i LU Research Portal.Osteoarthritis-induced damages can be studied using magnetic resonance imaging (MRI) or histology. However, MRI can introduce noise, and histology is only two-dimensional. Edvin examined thre

https://www.bme.lth.se/en/calendar/thesis-defense-exploring-synchrotron-and-neutron-techniques-characterizing-soft-knee-tissues - 2026-06-09

In the first panel on the left, the patient is scanned in an X-ray machine, generating a two-dimensional image, second panel. Our tool, DXA2FEM, then recreates a three-dimensional image in panel three, which enables accurate fracture assessment.Osteoporosis is defined as low bone mass, and results in a markedly increased risk of skeletal fractures. Development of new drugs to reduce bone loss or i

https://www.bme.lth.se/en/research/biomechanics/dxa2fem - 2026-06-09

Register here!   Program Monday September 21st10:00 Registration10:30 Welcome Address10:45 Keynote Speaker Martina Kvist Reimer (industry/Region Skåne):Connecting the Dots: A Systems View on Sustainability in Life Science research11:30 Workshop/discussion12:00 Lunch13:30 Invited Talks (10 min + 5 min Q&A)14:45 Coffee Break15:15 Pitch presentations (3 Minutes)15:45 Poster Session19:00 Dinner (with

https://www.bme.lth.se/en/engineering-health-annual-meeting-2026 - 2026-06-09

Since the pioneering work of Hellmuth Hertz and Inge Edler, our research groups have carried out research in ultrasound, with applications in medicine and biology. Today we focus on Arterial wall motion, Biosonar, Diagnosis of Hirschsprung’s disease, Magnetomotive ultrasound imaging, Photoacoustic imaging, and Plaque characterization. Researcher Profiles The links will open in the Lund University

https://www.bme.lth.se/en/research/ultrasound - 2026-06-09

Our research is mainly focusing on the following areas: neuromuscular control, neuromuscular modelling, muscle-machine interface, human-machine interfaces, sensors and haptics. We employ machine/deep learning models to create state of the art human machine interfaces based on signals derived from muscles and the brain. We use signal processing techniques to unravel how motor neurons are recruited

https://www.bme.lth.se/en/research/neuroengineering - 2026-06-09

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https://www.bme.lth.se/en/staff - 2026-06-09

The Division of Biomedical Engineering was formed by merging several research groups, all doing engineering research in a multitude of areas related to the biomedical field. We have laboratory and office space in the E-building and in the Biomedical Center. Our Research Areas: BiomechanicsBiomedical Signal ProcessingClinical Protein Science and ImagingNanobiotechnology and Lab-on-a-chipUltrasoundN

https://www.bme.lth.se/en/about - 2026-06-09

The links on this page open in Lund University's Research Portal. Var god vänta...

https://www.bme.lth.se/en/publications - 2026-06-09

Management Head of DivisionChristian Antfolkchristian [dot] antfolk [at] bme [dot] lth [dot] se (christian[dot]antfolk[at]bme[dot]lth[dot]se)+46-46-222 93 70Head of DepartmentIngrid Svenssoningrid [dot] svensson [at] bme [dot] lth [dot] se (ingrid[dot]svensson[at]bme[dot]lth[dot]se)+46-46-222 75 25Director of StudiesLars Wallmanlars [dot] wallman [at] bme [dot] lth [dot] se (lars[dot]wallman[at]bm

https://www.bme.lth.se/en/contact - 2026-06-09

Medicon Bridge is a networking platform within LTH Engineering Health devoted to creating, simplifying, and facilitating collaboration between hospital care, academy, and corporations in order to provide patients with the benefits of novel medical technology. The activities include arranging meetings and participating in national networks. Medicon Bridge was a regional node in the strategic innova

https://www.bme.lth.se/en/medicon-bridge - 2026-06-09

The Division offers infrastructure and assistance within microfluidics, acoustofluidics, and microfabrication. We can design and develop microsystems for processing of body/bodily fluids, cell sorting, immobilization, and neural electrodes. Submissions Submit your project request here. Examples of available technology and past projects: Fabrication Micromilling down to 50 µm. Photolitography down

https://www.bme.lth.se/en/life-science-microfluidics - 2026-06-09