Hamilton 80300 syringe: unrivalled precision for analytical microdispensing
The Hamilton 80300 syringe is part of the renowned 700 series, a benchmark in precision dosing instruments. This series is known for its hand-adjusted components and remarkable finish, ensuring repeatable performance even at the lowest volumes. The 80300 stands out for its ability to deliver a volume of 10 µL with extreme precision, making it ideal for applications such as gas chromatography (GC), microinjection, biochemical testing or laboratory protocols requiring high dosing accuracy.
Its design is based on a cemented needle (N-termination), ensuring perfect sealing and a significant reduction in dead volume, with a standard dead volume of only 0.64 µL. The integrated needle is 26s gauge, with an outer diameter of 0.47 mm and an inner diameter of 0.13 mm, allowing for precise handling of even the most delicate liquids. The type 2 tip, bevelled and curved, is designed for smooth penetration and accurate sampling, even in sensitive or complex matrices.
The syringe body is made of borosilicate glass, known for its chemical and thermal resistance, and stainless steel (SST) internal components to ensure compatibility with a wide range of solvents and reagents. This choice of materials not only guarantees increased durability but also essential chemical inertness in sensitive analytical protocols.
The 80300 syringe is not autoclavable, which limits its use to processes that do not require thermal sterilisation, but it is fully gas sterilisable, making it ideal for laboratory environments that require a high level of hygiene without compromising the integrity of the syringe. With a maximum pressure rating of 2000 psig (137.9 bar) and a temperature range of 10°C to 50°C, it fits perfectly into many analytical environments and automated devices.
Thanks to its cutting-edge technical features, the Hamilton 80300 is the obvious choice for scientists, laboratory technicians and researchers who demand high precision, consistent reliability and ergonomics suited to delicate handling.
