Electrospinning functionalized nanofibre membrane for anti-bacterial nanofiltration systems

Conor Keevey (AOS)Garrett Nekic (AOS)Darryl Chai (HCI)Sit Han Zhe (HCI)

Background• Electrospinning is a simple and

versatile process that is used to create nanofibre membranes for a variety of applications.

• Scientists have implemented various chemicals into the polymer solution to create modified mesh.

Background• Copper nanoparticles have shown to

possess antimicrobial properties against bacteria such as Escherichia Coli and Bacillus subtilis (Faheem et al, 2011).

• Past research has also shown that chlorhexidine digluconate could kill both gram positive and gram negative bacteria (Chen et al., 2008).

Rationale Lack of access to drinking water

Current conventional methods have their disadvantages:

• Non-controllable pore size• Lack of ability to control nanofiber

composition/ functionalising agents for desired functions

Great demand for a more efficient and cheaper method of water purification.

Objectives Confirm the effectiveness of

chlorhexidine digluconate and copper nanoparticles electrospun for the log removal of bacteria while integrated in separate nanofibre membranes

Determine the effectiveness of a combination of chlorhexidine digluconate and copper nanoparticles electrospun into the same membrane for water purification

Hypothesis A combination of copper nanoparticles

and chlorhexidine digluconate is more effective than the individual functionalising agents or no functionalising agents when electrospun into nanofibres.

Variables Controlled Variables:Ambient measurements, type and amount of

bacteria and water, spinning parameters, size of mesh, methods used for filtration and measurements

Independent Variable:Type(s) of anti-bacterial agent electrospun with

polymer

Dependent Variable: The total log removal of colony forming units

(CFUs)

Materials Acetic acid (18 M glacial) Formic acid (98% concentration) Nylon 6 ([-NH(CH2)5CO-], Sigma Aldrich) Nutrient agar broth Escherichia coli k-12 (ATTC) Bacillus megaterium (ATTC) Sterilised water Bleach

Apparatus Electrospinning apparatus Petri dishes Sterile Spreaders Micropipettes AA Spectrophotometer Autoclave Beakers Buchner Funnel Flask

Preparation of Copper nanoparticles

•Mix copper(II) sulfate with ethylene glycol

•Centrifuge mixture to obtain copper nanoparticles

•Rinse with distilled water and pat dry with filter paper

Preparation of Nanofibres

•Dissolve nylon 6 in acetic and formic acid

•Mix in antibacterial agent (copper nanoparticles/chlorhexidine digluconate)

•Spin an anti-bacterial mesh

(Daels et al., 2011)

Testing with Bacteria

•Grow the Escherichia coli, and Bacillus megaterium using nutrient broth in separate test tubes

•Measure and adjust optical density

•Mix bacteria with sterilised water

•Deposit 100 µL diluted culture into the agar plates (10 plates)

Testing with Bacteria

•Place mesh on circular plate and fasten to cylinder. Place in funnel

• Pour the 500 mL of water through it

•Deposit 100 µL of diluted culture onto the agar plates (10 plates)

•Place the plates in the incubator

http://image.tutorvista.com/content/organic-compounds/filtration-buchner-funnel.jpeg

Thank You

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