The B2B platform for the best purchasing descision. Identify and compare relevant B2B manufacturers, suppliers and retailers
Filter
Locations
Result types
Type of company
Select company type
Industries
Select industry
Company status
Select company status preset
Number of employees
Min.
Max.
Founding year
Lock keywords
Exclude keywords
Optional keywords
Barcelona, Spain
1-10 Employees
2012
IMPETUX instruments enable unprecedented manipulation and mechanical stimulation of living cells and tissues while simultaneously measuring cell forces and their rheological properties in a direct, absolute and non-invasive way. Our products are built upon cutting-edge technologies, such as optical tweezers (2018 Physics Nobel Prize winning) and our unique force spectroscopy tools. IMPETUX is a key manufacturer and worldwide supplier of turnkey optical tweezers systems for Cell Mechanics studies in living cells and tissues. Our mission is to provide solutions that meet the needs of Cell Mechanics researchers to help them address their current and future challenges that require new approaches to be solved. We are scientists developing tools for scientists and our dedicated team is by their side throughout the process to help them maximize the performance they will get from our instruments. Cell Mechanics is a field of Biophysics that focuses on how the mechanical properties and behavior of living cells regulate -and are regulated by- biological function with the goal to unveil their role in disease. Want to know more about the solutions that we can offer for your specific research needs? SENSOCELL is the only optical trapping platform in the market combining multiple optical traps control at high speed with direct force spectroscopy.
+
Featured
Cell Mechanics optical trapping solutions by IMPETUX
... Have a look at the multiple applications in cell mechanics of our optical tweezers systems integrating direct force spectroscopy. ...
Glattbrugg, Switzerland
11-50 Employees
1998
In addition, we are the only manufacturer to provide continuous support also for older instruments in the field. Of course, we provide the required consumables, such as the unique Isolation Caps, for reliable and efficient excision of tissue areas and single cells. Molecular Machines & Industries (MMI) is the leading provider of microscope based micromanipulation solutions for the life sciences, material sciences, and healthcare. We specialize in single cell handling, laser microdissection, whole slide imaging and optical tweezers for a wide range of clinical and research based applications. MMI is a high value partner for our customers providing worldwide unique competence in microdissection, micromanipulation and imaging. To meet our quality goals we are continually optimizing our processes, the benefits: state-of-the-art instruments, outstanding sales and service support, and highly successful research.” — The MMI Management —. Consequently, the second product line has been developed employing a high-precision laser microdissection technology, which led to the launch of the MMI CellCut in 2001. Today, all three product lines for the precise manipulation as well as selective isolation of cells from tissue and suspension are fully compatible and can thus be implemented into one single platform based on state-of-the-art microscopes.
+
Featured
Your benefits in using the MMI optical tweezers
... Optical Tweezers | Empowering Precision at the Nanoscale ✓ Ultra-precise ✓ Revolutionize your research with technology by MMI ► Learn more here. ...
Amsterdam, Netherlands
51-100 Employees
2014
LUMICKS is a next-generation life science tools company focused on enabling more efficient research, drug development, bioprocessing, bioproduction quality control, and patient treatment. Our products utilize our proprietary dynamic single-molecule (DSM) analysis and cell-binding avidity (CA) analysis technologies. We are an international team exceeding 200 people with more than 30 nationalities. We are proud of our great sense of ownership with the mentality of being open-minded in teamwork. LUMICKS is managed by an experienced team with diverse backgrounds. LUMICKS is the leading supplier of dynamic single-molecule and cell avidity analysis instruments. Our goal is to advance science and improve human health by providing tools that unlock the measurement of forces and interactions in biology to provide unparalleled insight into the fundamental cause of disease and the potential for drug optimization. We designed our instruments to provide rapid, in vitro confirmation of the mode of action and effectiveness of an immunotherapy product, thereby enabling the prediction of efficacy and side-effects in the lab before the product enters in vivo models.
+
Featured
Cookie Policy (US) - LUMICKS
... It combines high-resolution optical tweezers, confocal microscopy, or STED nanoscopy with an advanced microfluidics system in a truly integrated and correlated solution. ...
United Kingdom
11-50 Employees
1975
Biral also develops bespoke products to meet specific customer requirements and has a successful history in collaboration with leading universities. Biral gratefully acknowledges the West of England Combined Authority (WECA) for their support of the Biological Electrodynamic Balance development project through partial grant funding. Biral sensors are in 24/7 use in road and transport networks around the globe. Biral sensors are used in airports throughout the world as part of aviation ground control and meteorological monitoring systems. Bristol Industrial & Research Associates Ltd (Biral) designs, manufactures and distributes high quality meteorological sensors for professional markets, including aviation, offshore platforms and wind energy. The company has a rich history in designing and making innovative products including advanced weather sensors covering precipitation, wind speed and direction, temperature, visibility and thunderstorm detection through to aerosol analysers. As a dedicated member of the scientific community Biral actively participated in European scientific projects such as CRAFT and belongs to the Royal Meteorological Society, HMEI, National Winter Service Research Group (NWSRG) and the Aerosol Society. Based in Portishead, Bristol in the UK, the company was established in 1975 and is privately owned.
+
Featured
AOT-100 Aerosol Optical Tweezers - Biral
... The AOT-100 Aerosol Optical Tweezers Hold particles in an optical trap which enables different parameters to be studied continuously. ...
+
Featured
TH-EDU-OT3 - Portable Optical Tweezers Educational Kit, Imperial – Fosco Connect
... TH-EDU-OT3 - Portable Optical Tweezers ...
+
Featured
Optical Tweezers: Methods and Protocols
... The aim of this volume is to provide a comprehensive overview of optical tweezers setups . both in practical and theoretical terms . to help biophysicists . biochemists . and cell biologists to build and calibrate their own instruments and to perform force measurements on mechanoenzymes both ...
+
Featured
Optical Tweezers: Methods and Protocols
... The aim of this volume is to provide a comprehensive overview of optical tweezers setups . both in practical and theoretical terms . to help biophysicists . biochemists . and cell biologists to build and calibrate their own instruments and to perform force measurements on mechanoenzymes both ...
Netanya, Israel
11-50 Employees
1983
Founded in 1983, ROSH Electroptics has established itself as one of the leading Electro-optic distributor/representative companies in Israel and ISO qualified since 1996. By constantly adapting ourselves to the market we are able to focus our work and bring our customers “State-of-the-art” technologies and products. This allows us to continuously grow together with the Israeli market, thus regularly adding companies and updating our portfolio of products. Starting with optical components and opto-mechanics, the field of expertise of our Founder and General Manager – Ephraim Rubin, we supply today components and instruments in many fields such as: Laser Diodes, Lasers, Crystals, Laser Safety Equipment, Motion systems, Fiber-Optics Components and Equipment, Lab equipment and vacuum components. Recently, we have expanded our field of expertise to include microscopy and the biotechnology field.
+
Featured
Life Science Archives - Rosh ElectrOptics ltd
... Optical Tweezers Microscope ...
London, United Kingdom
5001-10000 Employees
1907
Our vision is to realise a sustainable, zero pollution future. A gift to Imperial can provide vital bursaries, scholarships and a lifeline to a student in financial difficulty. Learn more about Imperial through an Open Day or virtual tour or join us at a variety of events – in-person and online. REF 2021 finds that Imperial has a greater proportion of world-leading research than any other UK university. Imperial ranks first in the UK for research outputs, first in the UK for research environment, and first for research impact among Russell Group universities. Find out how Imperial is organised to tackle quality of life and quality of environment challenges faced by the world today. Imperial offers a wide range of expert help to researchers around funding, contract management, research integrity and governance. As an Imperial alumnus, you are a member of a lifelong community of over 190,000 across the globe.
+
Featured
Micro-Assembly, Imaging and Characterisation | Research groups | Imperial College London
... Multiple Spot Optical Tweezers E3500 Elliot ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Optical Tweezer
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 6 |
| Amount of suitable service providers | 4 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1907 |
| Youngest suiting company | 2014 |
An optical tweezer is a highly focused laser beam that can trap and manipulate microscopic particles, including cells, DNA molecules, and small beads, with great precision. This innovative tool exploits the radiation pressure of light to exert force on objects, allowing for the manipulation of single particles in three-dimensional space without physical contact. Since its invention in the 1980s by Arthur Ashkin, optical tweezers have revolutionized various scientific fields, particularly in biology and physics. In biological research, they are used to study the mechanical properties of cells, the elasticity of DNA, and the forces generated by motor proteins. Optical tweezers have also become indispensable in the study of molecular motors, where they measure the forces and distances over which these tiny molecular machines can operate. In physics, they are employed to trap and study individual atoms, enabling insights into quantum mechanics. The ability of optical tweezers to manipulate particles with precision has led to groundbreaking experiments in both the life sciences and physical sciences, furthering our understanding of the fundamental principles governing biological and physical systems. Their impact extends beyond research; optical tweezers are also applied in medical diagnostics and therapeutics, highlighting their versatility and the significant role they play in advancing technology and science.
1. Precision and Control
Optical tweezers offer unparalleled precision in manipulating microscopic particles. They allow scientists to control objects with nanometer accuracy, enabling the manipulation of single atoms, molecules, and cells without physical contact. This precision far surpasses that of mechanical or electronic tweezers, making optical tweezers ideal for delicate operations in fields like microbiology and quantum computing.
2. Non-invasive Nature
The non-invasive nature of optical tweezers is a significant advantage. They use the force of light to trap and move particles, thereby minimizing physical damage to biological samples. This gentle handling is crucial for studying living cells and organisms, as it preserves their integrity and functionality, which is often compromised by more invasive techniques.
3. Versatility
Optical tweezers are incredibly versatile, capable of manipulating a wide range of materials, from DNA strands to metal nanoparticles. This versatility extends their application across various scientific disciplines, including physics, chemistry, and biology. Unlike traditional tweezers that might be limited by the size, shape, or material of the object they're manipulating, optical tweezers can adapt to virtually any microscopic task.
While evaluating the different suppliers make sure to check the following criteria:
1. Wavelength Range
Ensure the optical tweezer operates within the wavelength range suitable for your specific application, as this can significantly impact its effectiveness in manipulating particles.
2. Trap Stiffness
Evaluate the trap stiffness, which determines the force with which the optical tweezer can hold and manipulate microscopic particles. Higher stiffness is beneficial for more precise control.
3. System Compatibility
Check if the optical tweezer system is compatible with your existing microscopy or spectroscopy setups to ensure seamless integration and operation.
4. Customization Options
Assess the availability of customization options that allow you to tailor the optical tweezer to meet the unique requirements of your research or industrial applications.
5. Support and Warranty
Consider the level of technical support and the warranty period offered by the supplier, as these factors can significantly affect the long-term usability and maintenance of the optical tweezer.
Optical tweezers have revolutionized precision manipulation in the biotech industry, allowing for the handling of cells and biomolecules with unprecedented control. This technology enables researchers to sort cells, study the mechanics of cell membranes, and understand molecular interactions without physical contact, thus reducing contamination and damage risks. In the semiconductor sector, optical tweezers play a crucial role in manipulating tiny components with high precision. This application is invaluable for assembling microchips and nanodevices, where even the slightest error can lead to significant functional discrepancies. By providing a non-contact method of component handling, optical tweezers help maintain the integrity and cleanliness required in semiconductor manufacturing processes. Environmental monitoring also benefits from optical tweezers, especially in the analysis of air and water quality. By trapping and analyzing microscopic particles and pollutants, this technology offers a novel approach to detecting and studying environmental contaminants. This capability is essential for organizations committed to environmental conservation, enabling them to identify and address pollution sources more effectively. In the pharmaceutical industry, optical tweezers contribute to drug development and testing by facilitating the manipulation and examination of individual cells and particles. This precision aids in understanding how drugs interact at a cellular level, allowing for the development of more effective treatments with fewer side effects.
Optical tweezers, a groundbreaking technology that utilizes focused laser beams to manipulate microscopic particles, currently stand at a Technology Readiness Level (TRL) of 6. This classification indicates that the technology has evolved from purely theoretical and laboratory-based experiments (TRL 1-3), through the validation of its functionality in a relevant environment (TRL 4-5), to the demonstration of the system prototype in a relevant operational environment (TRL 6). The progression to TRL 6 is underpinned by several technical advancements and demonstrations of the technology's capability to manipulate not only simple particles but also complex biological organisms, such as bacteria and viruses, without inflicting damage. This level of precision and control is achieved through the sophisticated calibration of laser intensity and direction, allowing for the non-invasive manipulation of objects at the nano and micro scales. Furthermore, the integration of optical tweezers with other technologies, like microscopy, has expanded its application in the fields of biology and physics, showcasing its versatility and potential for broader adoption. However, challenges such as the need for further miniaturization, increased efficiency, and the development of user-friendly interfaces for diverse scientific and medical applications prevent the technology from advancing to later TRLs, where full-scale commercial deployment and widespread market acceptance are achieved.
In the Short-Term, advancements in optical tweezer technology are anticipated to focus on enhancing precision and control. Researchers are likely to develop more sophisticated algorithms that allow for real-time manipulation of nano-sized particles with unprecedented accuracy. This phase will also see the integration of AI to predict and automatically adjust the optical traps, making experiments more efficient and reducing human error. The Mid-Term outlook for optical tweezers involves the expansion of their application beyond biology and physics into new fields such as chemistry and materials science. Innovations are expected to enable the manipulation of not just individual atoms and molecules but also more complex structures like nanotubes and quantum dots. The introduction of multi-beam optical tweezers will allow for the handling of multiple particles simultaneously, paving the way for complex assembly processes at the nano-scale. In the Long-Term, the future of optical tweezers points towards the integration with quantum computing and telecommunications. This phase will likely see optical tweezers being used to control quantum states and facilitate quantum entanglement experiments. The development of portable, miniaturized optical tweezers could revolutionize medical diagnostics by enabling the manipulation of viruses or cells directly inside the human body, opening new avenues for treatment and research at the cellular level.
