Leeox Technologies

30/06/2020

MicroBio MB1 Bioaerosol Sampler are vital equipment for us in Bioaerosol research, cleanrooms, pharmaceuticals and hospitals where air hygiene is vital. It is the most affordable sampler available in the market. Fully validated as per ISO-14698 requirements and USP 797 guidelines in the USA.

For more details visit us at www.leeox.com

18/04/2020

Stay Safe & Stronger Together !

28/02/2019

Next Generation Microbial Air Sampler !

Exclusive only from Leeox Technologies
(www.leeox.com -- [email protected] -- +91 9987972507)

A technology product in the world of wireless connectivity. Scientifically designed for continuous and online sampling with the possibility to control the environment by a longer time period, therefore the Agar plate will be turned step by step during the sampling process.

14/05/2018

07/11/2017

MICROBIO MB2 & MB2 Hi-Flow (Make Cantium Scientific Ltd. UK)
(Authorized Distributor)

The worlds most economic yet scientifically strong and validated microbial air sampler.

The MicroBio MB2 Microbiology Air Sampler has a host of features making it ideal for use in research, clean rooms, pharmaceutical validation and throughout hospitals. Fully validated under the UK DTI VAM programme. Capable of using both 90mm Petri dishes or 55mm contact plates. The MicroBio MB2 is a very low cost and productive instrument to use.

The MicroBio MB2 is an invaluable device for validating clean rooms to ISO 14698 requirements.

Features / Specifications

Flow rate 100 litres/minute, (MB2)
180 litres/minute, (MB2 Hi-Flow)

220 hole sampling head d50 = 1.7µm

400 hole sampling head d50 = 1.35µm

Sampling Volume 25 to 10,000 litres

6 User Programmable pre-set volumes

Sequential sampling up to 10,000 litre over a 24 hour period.

Programmable delay to start sampling up to 3 hours

Tripod mounting facility

Body is manufactured from ABS for resilience
and is disinfectant, IPA and HPV resistant.

Lightweight (750 g), Portable & Low Noise

Battery powered – rechargeable or alkaline / NiMh (4 × AA)

Sample over 60,000 litres per charge

Audio Alarming after sample completion.

07/11/2017

MICROBIO MB1 (Make:- Canitum Scientific Ltd. UK)
(Leeox Technologies is the Authorized Distributor)

The Affordable Microbial Air Sampler

The MicroBio MB1 Bioaerosol Sampler is the most economical air sampler of its kind. It has been fully validated under the UK DTI VAM programme. Capable of using either with 90 mm Petri dishes or 55 mm contact plates and a wide variety of media makes the MicroBio a very low cost instrument to use. The MicroBio MB1 is an invaluable device for
validating clean rooms to ISO 14698 requirements.

Features / Specifications

Flow rate 100 litres/minute, factory calibrated

220 hole sampling head d50 = 1.7µm

400 hole sampling head d50 = 1.35µm

Delay Mode upto 60 minutes adjustable

Sampling Volume 10 to 2,000 litres

Body is manufactured from ABS for resilience and is disinfectant, IPA and HPV resistant.

Lightweight (750 g) and Portable

Battery powered – rechargeable or alkaline

NiMh (4 × AA) cells and charger supplied

Low battery indication with battery status

Sample up to 60,000 litres air per charge

07/11/2017

Importance of MicroBio Bioaerosol Sampler.

We are often asked ‘how can MicroBio samplers be that good at sampling compared to others costing more than twice as much?’

The simple answer: the impaction velocity of organisms is kept low enough, betwee 9.8 and 11 metres per second for MicroBio sampling heads, so their viability is not compromised when impacting upon sample plates, but not too slow as to flow through the air stream and miss the plate altogether! Our sampler design concentrates on viable bioaerosol collection rather than the aesthetics of the product. What’s important is capturing a viable sample, rather than just looking the part.

The science is more important than the style of the instrument.

By designing an air sampler with emphasis on enabling high viability collection, results can be more meaningful.

By this simple common sense realisation we keep our particle velocity in a range that most organisms will survive impaction and be viable for culturing and counting. This need is also emphasised in ISO-14698 that mentions impaction velocity should be less than 20 metres per second. MicroBio MB2 is designed to meet the sampling requirements of ISO 14698 standard.

How do we achieve the ideal particle velocity? By understanding the mechanics of bioaerosol sampling.

Having developed mathematical models over the years we are able to design sampling heads and predict the particle d50 cut off points and impaction velocity for any combination of sampling head hole count, hole size and volumetric flow. Another aspect in our sampling heads is the way the holes are produced. There should be no sharp edges on the inlet of the holes. Turbulence is created around these points and they can physically damage organisms. We have tried various manufacturing techniques over the years and have found punching the holes produces a smooth form in the surface of the metal for air to flow, while keeping them affordable. Simply drilling a hole creates a sharp entry point to the hole, unless expensive additional machining of each hole is undertaken. We’ve also experimented with etching techniques and laser cutting, but under the microscope the edge finish of such holes is rough and sharp.

07/11/2017

What is a bioaerosol?

Bioaerosols are airborne particles, solid or liquid. They can be large molecules or volatile compounds. They contain living organisms. They will vary in size from a fraction of a micron to around 100 microns. As with inert “dust” particles, all bioaerosols are governed by the laws of gravity and will be affected by air movements being transported by turbulence and diffusion.

Air will often contain micro-organisms such as viruses, bacteria, and fungi. None of these actually live in the air, the atmosphere tends to kill off most of them. However, they are frequently transported attached to other particles, such as skin flakes, soil, dust, or dried residues from water droplets. Aggregation of cells into clumps can enhance the survival
whilst airborne. Bacterial cells when they become airborne normally rapidly die, within a few seconds, due to evaporation of water associated with the particle. Thus with higher humidity, higher bioaerosol levels can prevail. Airborne fungal cells (yeasts, moulds, spores) can remain viable for much longer periods, even at low relative humidity and high or low temperature extremes. These can pose health risks for humans and animals.

Monitoring of Bioaerosols

Although the use of simple settle plates can be used for collection of bacteria and fungal spores, it can never give a quantitative determination. This passive technique will also fail to enumerate very small particles such as bacteria, which will remain suspended. The simplest quantitative method of monitoring is to use impact samplers such as the MicroBio MB1 or MB2 units. These are single stage impactors, which collect bacteria and fungal spores from air flowing at 100 litres / minute through a series of 1 mm diameter air inlets, onto an agar filled 55 mm contact plate or 90 mm Petri dish, up to a volume of 2,000 litres. The MicroBio samplers are lightweight, battery powered self contained units and do not require an external vacuum pump.
The agar media used should be chosen to suit the organisms which are being monitored. For a wide range of bacteria use tryptic soy agar (TSA), casein soy peptone agar (CPSA) and nutrient agar (NA). There are other selective agars for more specific micro-organisms. For fungi (yeasts and moulds) use is made of malt extract agar (MEA) or rose bengal agar (RBA). After sampling with the MicroBio samplers, the agar plates are incubated for specified times and temperatures (typically 1 to 2 days at 25 to 37 deg C) and the colonies which develop are counted. A correction is applied to the count to allow for the possibility that two organisms going through one sampling hole will result in only one colony growth being observed (positive hole correction). This is determined from tables or using the MicroBio analysis spreadsheets available from this website. From the corrected count and the sampling volume used, the number of colony forming units per cubic metre (CFU/m3) can be determined.