Title :
Microfabricated microdialysis microneedles for continuous medical monitoring
Author :
Zahn, Jeffrey D. ; Trebotich, David ; Liepmann, Dorian
Author_Institution :
Sensor & Actuator Center, California Univ., Berkeley, CA, USA
Abstract :
Enzyme based biosensors suffer from loss of activity and sensitivity through a variety of processes. One major reason for the loss is through large molecular weight proteins settling onto the sensor and affecting sensor signal stability and disrupting enzyme function. One way to minimize loss of sensor activity is to filter out large molecular weight compounds before sensing small biochemicals such as glucose. A novel microdialysis microneedle is introduced that is capable of excluding large MW compounds based on size. Preliminary experimental evidence of membrane permeability is shown, as well as diffusion and permeability modeling. Solutions should be able to equilibrate across the microdialysis membrane in a few seconds, as opposed to a few minutes with existing technologies. Microdialysis microneedles present an attractive first step towards decreasing size, patient discomfort and energy consumption of portable medical monitors over existing technologies
Keywords :
biodiffusion; biosensors; patient monitoring; permeability; proteins; continuous medical monitoring; energy consumption; enzyme based biosensors; large molecular weight compounds; large molecular weight proteins; membrane permeability; microdialysis membrane; microfabricated microdialysis microneedles; patient discomfort; permeability modeling; portable medical monitors; sensor activity loss minimization; Biochemistry; Biomedical monitoring; Biomembranes; Biosensors; Needles; Proteins; Sampling methods; Sensor phenomena and characterization; Stability; Sugar;
Conference_Titel :
Microtechnologies in Medicine and Biology, 1st Annual International, Conference On. 2000
Conference_Location :
Lyon
Print_ISBN :
0-7803-6603-4
DOI :
10.1109/MMB.2000.893809
