Toward an Injectable Continuous Osmotic Glucose Sensor

Johannessen, Erik; Krushinitskaya, Olga; Sokolov, Andrey; Häfliger, Philipp; Hoogerwerf, A.; Hinderling, Christian; Kautio, Kari; Lenkkeri, Jaakko; Strömmer, Esko; Kondratyev, V.A.; Tønnessen, Tor Inge; Mollnes, Tom Eirik; Jakobsen, Henrik; Zimmer, Even; Akselsen, B.B.

doi:10.1177/193229681000400417

Cited by 33 publications

(36 citation statements)

References 48 publications

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“…The interference from other substances needs to be addressed for the improvement of this sensor. The selectivity of this sensor may be improved by employing glucose affinity materials, like hydrogel or Concanavalin (Con) A-dextran [26][27][28], in the device instead of a standard solution. The sensing material employed in [27,28] consists of Con A, which possesses an affinity toward glucose, and the equilibrium is perturbed by glucose binding to lectin, triggering a dissociation of dextran that is proportional to the increase in glucose.…”

Section: Resultsmentioning

confidence: 99%

“…The selectivity of this sensor may be improved by employing glucose affinity materials, like hydrogel or Concanavalin (Con) A-dextran [26][27][28], in the device instead of a standard solution. The sensing material employed in [27,28] consists of Con A, which possesses an affinity toward glucose, and the equilibrium is perturbed by glucose binding to lectin, triggering a dissociation of dextran that is proportional to the increase in glucose. In addition to Con A-dextran, one needs a special semi-permeable membrane that allows selective diffusion of glucose across the membrane, but that prevents the transport of larger molecules, such as peptides or proteins, or other potentially interfering molecules, such as lactate or polysaccharide, contained in body fluids [36].…”

Section: Resultsmentioning

confidence: 99%

“…In addition to Con A-dextran, one needs a special semi-permeable membrane that allows selective diffusion of glucose across the membrane, but that prevents the transport of larger molecules, such as peptides or proteins, or other potentially interfering molecules, such as lactate or polysaccharide, contained in body fluids [36]. Generally, cellulose acetate (CA), cellulose ester and polyamide (PA) membranes are used in glucose sensing application based on the osmosis principle [27,28,36,37]. The cellulose membranes present chemical and biological resistances to the body and are not suitable for a long-term implant.…”

Section: Resultsmentioning

confidence: 99%

“…Another glucose sensor based on volume change due to the flow of water across the semi-permeable membrane has been developed [25]; but, the device is large in size, and its accuracy can be improved. In another approach, smart hydrogels are confined inside a pressure sensor to facilitate the measurement of the change in glucose concentration levels [26][27][28]. Though its response time is high, the inclusion of smart hydrogels offers high sensitivity and selectivity.…”

Section: Introductionmentioning

confidence: 99%

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Fabrication and Testing of an Osmotic Pressure Sensor for Glucose Sensing Application

Paily

2014

Micromachines

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This paper presents a chemical reaction-free sensor, based on the osmosis principle, fabricated to measure the change in glucose concentration levels. The sensor consists of a square cavity filled with a known concentration of glucose solution and sealed with a semi-permeable membrane. The volume inside the cavity changes in proportion to the glucose concentration outside the device and introduces the displacement in the silicon (Si) membrane on the top. The main considerations targeted for this sensor are better response time, chemical-free nature, improved lifetime and absence of any mechanical excitations. Moreover, as the size of a system plays a major role, efforts have been taken to reduce the dimension of the presented system. The designed glucose sensor is fabricated by employing a bulk micromachining technology on a SOI (silicon on insulator) substrate. This will allow batch fabrication, as well as the integration of the electronic circuit on the same substrate. The output voltage obtained is varied from −6.7 to 22.7 mV for the corresponding glucose concentrations ranging from 50 to 450 mg/dL, respectively, after a constant osmosis duration of 15 min. The response time obtained for the sensor is 40 min, and it is lesser compared to similar works based on the osmosis principle.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fabrication and Testing of an Osmotic Pressure Sensor for Glucose Sensing Application

Paily

2014

Micromachines

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“…Current applications extend to implantable neuroprosthetic devices [2] such as cochlear implants [3] and neural stimulating electrodes [4][5][6], as well as microfabricated devices targeting temperature, blood pressure, immuno-isolation, drug delivery, and microinjection [7,8]. Still, one critical issue has remained with respect to the power supply since stringent size constraints of the implant have compromised the available space required by batteries.…”

Section: Introductionmentioning

confidence: 99%

Thin film nanoporous electrodes for the selective catalysis of oxygen in abiotically catalysed micro glucose fuel cells

et al. 2016

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Selective reduction of oxygen is an important property of fuel cells designed to operate in a mixed fuel environment containing both oxidizing and reducing reactants. This would be of particular importance in the design of a long lasting energy supply unit powering implantable microsystems and running from exogeneous chemicals that is abundant in the body (such as glucose and oxygen). This paper presents the development of a nanoporous electrode for oxygen reduction in the presence of glucose. The electrode was fabricated by e-beam deposition of palladium thin films on porous ceramic aluminium oxide (AAO) substrates with a pore size of 100 and 200 nm respectively. The porous nature of the electrodes improved the catalytic properties by increasing the real surface area close to 100 times the geometric surface area. At a dissolved physiological oxygen (DO) concentration of 2 ppm, the maximum exchange current density was found to be 2.9×10 −3 ± 0.5×10 −3 µA cm −2 whereas the potential reduction due to the addition of 5 mM glucose was about 20.6 ± 16.1 mV. The Tafel slopes were measured to be about 60 mV per decade. After running for 21 hours in a physiological saline solution with 2 ppm DO and 3 mM glu- cose, the reduction in the electrode operational potential was -0.13 mV h −1 under a load current density of 4.4 µA cm −2 . These results suggest that nanoporous AAO cathodes coated with palladium offers a reasonable catalytic performance with a good selectivity towards oxygen in the presence of glucose.

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Injectable, dispersible polysulfone‐polysulfone core‐shell particles for optical oxygen sensing

Presley

Fan

DiRando

et al. 2021

J of Applied Polymer Sci

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Injectable sensors can significantly improve the volume of critical biomedical information emerging from the human body in response to injury or disease. Optical oxygen sensors with rapid response times can be achieved by incorporating oxygen-sensitive luminescent molecules within polymeric matrices with suitably high surface area to volume ratios. In this work, electrospraying utilizes these advances to produce conveniently injectable, oxygen sensing particles made up of a core-shell polysulfone-polysulfone structure containing a phosphorescent oxygen-sensitive palladium porphyrin species within the core. Particle morphology is highly dependent on solvent identity and electrospraying parameters; DMF offers the best potential for the creation of uniform, sub-micron particles. Total internal reflection fluorescence microscopy confirms the existence of both core-shell structure and oxygen sensitivity. The dissolved oxygen response time is rapid (<0.30 s), ideal for continuous real-time monitoring of oxygen concentration. The incorporation of Pluronic F-127 surfactant enables efficient dispersion; selection of an appropriate electrospraying solvent (DMF) yields particles readily injected even through a < 100 μm diameter needle.

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Toward an Injectable Continuous Osmotic Glucose Sensor

Cited by 33 publications

References 48 publications

Fabrication and Testing of an Osmotic Pressure Sensor for Glucose Sensing Application

Fabrication and Testing of an Osmotic Pressure Sensor for Glucose Sensing Application

Thin film nanoporous electrodes for the selective catalysis of oxygen in abiotically catalysed micro glucose fuel cells

Injectable, dispersible polysulfone‐polysulfone core‐shell particles for optical oxygen sensing

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