Homogeneous phantoms are solid samples aiming at mimicking the optical properties of biological tissues.

Unveil a realm of possibilities with our selection of homogeneous phantoms – the quintessential tools that drive excellence in referencing, calibration, and device characterization within the field of Biophotonics. Whether it’s for daily routine operations, calibration precision, or troubleshooting accuracy, our range of classical single or set phantoms elevates your biophotonics instrument evaluations to unparalleled heights.

Homogeneous phantoms

Why choose homogeneous phantoms

  • Expertise that Matters: Harness our profound expertise in understanding the optical properties of diverse tissue types. Our team stands ready to craft phantom solutions tailored to your research needs.

  • Diverse Catalogue: Immerse yourself in a wide-ranging catalogue featuring an array of phantoms with varying optical properties, geometries, and sizes. Your perfect phantom is just a click away.

  • Customization Beyond Limits: Didn’t find a phantom that aligns with your precise requirements? Our customization capabilities allow us to create phantoms that precisely match your vision.



Elevate your instrument assessments with the precision and reliability of our phantoms. Step into a realm where customization meets scientific excellence. When your research demands the best, trust in our phantoms to pave the way forward!

KEY FEATURES

Off-the-shelf
selection

Choose from a comprehensive assortment of readily available phantoms, ensuring you have the tools you need without delay.

Geometry and Dimension Variety

Our phantoms come in various geometries and dimensions, accommodating a multitude of experimental setups.

Tailored Wavelength Characterization

With wavelength characterization spanning from 470 to 1050 nm, our phantoms empower you to explore a broad spectrum of optical behavior.

Mechanical
Mimicry

Test the tactile advantage of phantoms specifically designed for softness, enabling them to mimic not just optical properties but also mechanical characteristics of real biological tissues.

Reproducible TDDO Characterization

Experience the freedom of reproducible, coupling-free Time-domain Diffuse Optical (TDDO) characterizations, unlocking consistent and reliable measurements.

Traceability and Benchmarking

Access traceable datasheets that not only enhance your confidence in measurements but also enable you to share and benchmark your research against industry standards.

Unlock the secrets of optical properties, delve into the core of biophotonics, and embark on a journey of scientific excellence with our homogeneous phantoms!

APPLICATIONS

Explore the limitless possibilities of Homogeneous phantoms

Medical Imaging: Elevate the accuracy of medical imaging techniques, enabling precise calibration and referencing for e.g. optical mammography, near-infrared tissue spectroscopy, and many more.

Neurological research: Unlock insights into brain function and neuronal activity with phantoms designed to mimic optical properties, supporting advancements in neuroscience, cognitive studies and brain oximetry.

Skin Health Analysis and Simulation: Revolutionize dermatological diagnostics with phantoms that replicate skin tissue properties, aiding in non-invasive optical assessments for skin health and development of new sophisticated instruments.

Sports Performance Optimization: Gain a deeper understanding of muscle oxygenation and metabolic dynamics during physical activities, enhancing strategies for sports performance optimization.

Biomedical Engineering: Fuel innovation in biomedical engineering by using phantoms to develop and validate optical medical devices, from near-infrared spectroscopy tools to oximeters.

Instrument Calibration and Quality Check:  Achieve impeccable instrument calibration and maintain day-to-day quality assurance with phantoms tailored to ensure the accuracy and reliability of your biophotonics setups.

Educational Research:  Provide a hands-on learning experience for students and researchers, offering a tangible understanding of photon migration principles and applications.