| 1. |
- Lilliehorn, Tobias, et al.
(författare)
-
Bioassays on ultrasonically trapped microbead clusters in microfluidic systems
- 2004
-
Ingår i: Micro Total Analysis Systems 2004. - 0854048960 ; 2, s. 327-329
-
Konferensbidrag (refereegranskat)abstract
- The handling of biochemically functionalised beads or particles is becoming increasingly important in µTAS. Bead-based analysis of e.g. proteins can be made sensitive due to the large active surface area and flexible by chemical design of the bead surface. We have developed a microfluidic device utilising an array of integrated and individually controlled ultrasonic microtransducers for particle trapping [1]. Particles inserted in the device are subjected to acoustic radiation forces [2] confining them at localised trapping sites. We would now, for the first time at an international conference, like to present a technique for performing bioassays on such ultrasonically trapped beads in microfluidic systems. The microfluidic device is shown in Fig. 1, where the piezoceramic ultrasonic transducers can be seen in the channel crossings in the insert. The device is designed as an acoustic resonator, to obtain localised standing acoustic waves at each transducer with essentially one pressure node in the middle of the 72 µm deep channel when operated near 10 MHz. This configuration is chosen to keep trapped particles away from the interior surfaces of the device, thus enabling fast switching of beads with a minimum in carry-over between assays. The fluidic chip, shown in Fig. 2, is designed to allow injection of microbeads, washing fluid and sample to the three trapping sites. It has been shown that the microbead clusters, as shown in Fig. 3, can be trapped at considerably high perfusion rates, up to 10 µl/min, Fig 4. As a model bioassay, 6.7 µm biotin-covered beads (PC-B-6.0, Gerlinde Kisker, Germany) were injected and transported to one tapping site using washing fluid (water). Activating the transducer trapped the beads. A solution of FITC-tagged avidin was perfused over the bead bed at 3 µl/min, using the corresponding orthogonal sample channel. After 100 s the sample flow was turned off and the bead trap was washed by perfusing water at 3 µl/min. The fluorescence response from the trapped bead clusters was monitored during the assay, and the result is shown in Fig. 5. After excess avidin was washed from the bead trap, a measured step response . indicated that avidin had bound to the beads. Finally the possibility of moving trapped microbeads between the individually controlled trapping sites in the device is shown in Fig. 6, where the transducers are activated sequentially while keeping the bead carrying washing fluid at 3 µl/min during the experiment. Work in the near future will be focused on optimising the device with respect to the bioassay performance, and in a longer perspective on expanding the concept to two dimensions to enable a new dynamic mode of generating bioanalytical arrays.
|
|
| 2. |
- Nilsson, Mikael, et al.
(författare)
-
Ultrasonic beadtrapping for bioassays
- 2004
-
Ingår i: ; , s. 149-151
-
Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- This paper proposes a new dynamic mode of generating bioanalytical arrays based on ultrasonic trapping of microbeads in microfluidic systems. As compared to disposable glass slide microarrays, the proposed technology utilises exchangeable microbeads as the solid phase on which bioassays are performed. The use of microbeads in biochemical analysis is advantageous due to the increased surface area and thus the high binding capacity as compared to planar solid surfaces. By the integration of ultrasonic microtransducers in a microfluidic system, we have proved that it is possible to trap and manipulate microbead clusters by making use of acoustic standing wave forces. Functionalised microbeads have been trapped and moved between well-defined positions in a microchannel, thus for the first time showing trapping of microbeads within a flow-through device with individually controlled trapping sites in an array format. A device with three acoustic trapping sites was fabricated and evaluated. The lateral extension of each trapping site was essentially determined by the corresponding microtransducer dimensions, 0.8 x 0.8 mm2. The flow-through volume was approximately 1 µl and the active trapping site volumes about 100 nl each. The strength of trapping was investigated, showing that 50 % of the initially trapped beads were still trapped at a perfusion rate of 10 µl/min. Since the beads determine the chemical functionality in the device a high degree of flexibility is expected. A fluorescence based avidin bioassay was successfully performed on biotin-coated microbeads trapped in the flow-through device, providing a first proof of principle of the proposed dynamic arraying concept. The dynamic arraying is believed to be expandable to two dimensions, thus with a prospect of performing targeted and highly parallel protein analysis in microfluidics.
|
|
| 3. |
- Bengtsson, Monica, et al.
(författare)
-
Samarbete som språngbräda för utveckling : Att se och förstå undervisning - en studie av teoretiska kunskaper i praktiken
- 2001
-
Rapport (övrigt vetenskapligt/konstnärligt)abstract
- Baksidestext: Hur gör man för att se och förstå undervisning? Den här rapporten är ett dynamiskt samarbete mellan två personer från lärarutbildningen på Malmö högskola och ett par lärare på en skola för att utveckla kvaliteter i skolans ”kärna” d.v.s. elevers lärande. Varför är det nödvändigt att utveckla undervisning och hur gör man det? Två lärares tematiska arbete med sina elever har dokumenterats och analyserats. Bl.a. följande frågor har tagits upp: Har en tidigare kompetensutveckling lämnat några spår? Vad hände med teorierna i praktiken? Vad händer när lärarna lämnar undervisningens organisation och i stället koncentrerar sig på innehållet?
|
|
| 4. |
|
|
| 5. |
|
|
| 6. |
|
|
| 7. |
|
|
| 8. |
|
|
| 9. |
|
|
| 10. |
|
|
