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We’re excited to announce the expansion of our sterile syringe filter portfolio with a broader selection of trusted brand options—giving you more flexibility, performance, and compatibility for your filtration needs. Whether you're working in pharmaceutical labs, analytical chemistry, or environmental testing, we now offer a wider range of materials and formats to better suit your specific applications.

Sterlitech is proud to announce our recent feature on the nationally televised series World’s Greatest!, a program that spotlights exceptional organizations and companies making a meaningful impact across industries. This recognition is a significant milestone in our journey and a celebration of the innovation, quality, and dedication that have defined Sterlitech since our founding.

Cell culture workflows demand precision, flexibility, and sustainability. The cellQART® Half Pre-Loaded Well Plates meet these requirements by integrating gamma-sterilized, tissue-culture-treated PET membrane inserts into half of a standard 24-well plate-allowing researchers to load only the wells they need while preserving unused wells for future experiments.  

From rose petals to refined perfume, Sterlitech’s advanced membrane filtration technology is enabling safer, more efficient, and more scalable processes in the essential oil and fragrance industries. By offering alternatives to traditional heat methods, Sterlitech is helping producers preserve the aromatic integrity of botanicals while improving purity, safety, and sustainability.

Selecting the appropriate membrane is a critical step in the development of any product involving filtration, separation, or fluid control. However, with a wide range of materials, pore sizes, and surface treatments available, identifying the optimal solution can be time-consuming and complex, especially during early-stage development. Sterlitech’s membrane sample packs are designed to help R&D teams and engineers streamline the material selection process, reduce risk, and accelerate development timelines. 

Sterlitech’s silver membranes are pushing the boundaries of biomedical research and analytical precision. These membranes can be used to harvest gingival crevicular fluid GCF during orthodontic procedures where accurate metabolic profiling is required. Their inert, porous construction is essential for preventing sample contamination and preserving molecular structure during proton nuclear magnetic resonance ¹H NMR analysis. This allows for the precise identification of a wide range of metabolites associated with bone remodeling inflammation and tissue adaptation.

We’re excited to share that Ammar Hafiz, our Application Engineer for Membrane Process and Development, will be attending the North American Membrane Society (NAMS) 2025 Conference, taking place May 17–21 in Nashville, Tennessee. This annual event brings together leading researchers, students, and industry professionals dedicated to advancing membrane science and technology. 

In any laboratory setting, efficient liquid waste disposal is essential for maintaining a safe and contamination-free workspace. Lab aspiration systems play a crucial role in removing supernatants, culture media, and other liquid waste, but with multiple options available, selecting the right system for your workflow can be challenging. Explore a comparison of lab aspiration systems designed to help you identify the right fit for your needs.

As the world races toward a more sustainable future powered by renewables, we’re faced with a new challenge: what happens to the materials once they’ve served their purpose? 

That’s where the circular economy comes in. And behind the scenes, filtration plays a critical role in making it work.

Inorganic membranes distinguish themselves from polymeric membranes through their superior resistance to organic solvents, high thermal tolerance, and the absence of organic extractables and leachables. Unlike polymer-based materials, inorganic membranes are not composed of carbon-based molecular networks, which enhances their chemical stability. Among these, aluminum oxide (AO) membranes offer additional advantages, including precisely defined pore sizes, low adsorption, and minimal autofluorescence, making them particularly well-suited for high-resolution imaging and microscopy applications.¹