Glucose Sensor Membranes for Mitigating the Foreign Body Response

Koh, Ahyeon; Nichols, Scott P.

doi:10.1177/193229681100500505

Cited by 38 publications

(44 citation statements)

References 95 publications

(144 reference statements)

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“…Although outer membranes are typically self-assembled monolayers on top of the existing enzymatic membrane (Nafion or polyurethane) (Moussy et al, 1993;Vaddiraju et al, 2011), the use of hollow microdialysis membranes in in vivo biosensor applications has also been reported (Koh et al, 2011;Leegsma-Vogt et al, 2001. In addition, the use of a membrane on top of the enzyme layer is an effective anti-biofouling strategy .…”

Section: Lactate Biosensorsmentioning

confidence: 98%

In vivo continuous and simultaneous monitoring of brain energy substrates with a multiplex amperometric enzyme-based biosensor device

Cordeiro

Vries

Ngabi

et al. 2015

Biosensors and Bioelectronics

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Section: Lactate Biosensorsmentioning

confidence: 98%

In vivo continuous and simultaneous monitoring of brain energy substrates with a multiplex amperometric enzyme-based biosensor device

Cordeiro

Vries

Ngabi

et al. 2015

Biosensors and Bioelectronics

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“…1,2 Insertion of the sensor damages vascularized tissue and results in a cascade of inflammatory events, many of which negatively impact glucose measurements. 3 For example, the resulting passive adsorption of biomolecules (mainly <15 kDa protein fragments) to the sensor surface initiates an inflammatory response and is responsible for a dramatic decrease in sensor sensitivity (∼50%) following sensor implantation.…”

mentioning

confidence: 99%

In Vivo Analytical Performance of Nitric Oxide-Releasing Glucose Biosensors

Soto

Privett

2014

Anal. Chem.

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The in vivo analytical performance of percutaneously implanted nitric oxide (NO)-releasing amperometric glucose biosensors was evaluated in swine for 10 d. Needle-type glucose biosensors were functionalized with NO-releasing polyurethane coatings designed to release similar total amounts of NO (3.1 μmol cm–2) for rapid (16.0 ± 4.4 h) or slower (>74.6 ± 16.6 h) durations and remain functional as outer glucose sensor membranes. Relative to controls, NO-releasing sensors were characterized with improved numerical accuracy on days 1 and 3. Furthermore, the clinical accuracy and sensitivity of rapid NO-releasing sensors were superior to control and slower NO-releasing sensors at both 1 and 3 d implantation. In contrast, the slower, extended, NO-releasing sensors were characterized by shorter sensor lag times (<4.2 min) in response to intravenous glucose tolerance tests versus burst NO-releasing and control sensors (>5.8 min) at 3, 7, and 10 d. Collectively, these results highlight the potential for NO release to enhance the analytical utility of in vivo glucose biosensors. Initial results also suggest that this analytical performance benefit is dependent on the NO-release duration.

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“…Additional research is occurring to reduce this biofouling by use of special membrane or sensor materials that limit inflammation or using a sensor membrane coated with anti-inflammatory drugs to reduce inflammation at the site of sensor insertion. 95 Also, the invasiveness of the sensors results in skin-related adverse events, and hence research is continuing for a noninvasive CGM using different techniques such as iontophoresis, bioimpedance spectroscopy, near-infrared spectroscopy, reverse iontophoresis, and sonophoresis. 96 Another problem with the current CGMs is that the sensors last up to 7 days.…”

Section: Future Directions In the CL Systemmentioning

confidence: 99%

Closed-Loop System in the Management of Diabetes: Past, Present, and Future

Shah

Shoskes

Tawfik

et al. 2014

Diabetes Technology & Therapeutics

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Intensive insulin therapy (IIT) has been shown to reduce micro- and macrovascular complications in patients with type 1 diabetes mellitus (T1DM). However, IIT is associated with a significant increase in severe hypoglycemic events, resulting in increased morbidity and mortality. Optimization of glycemic control without hypoglycemia (especially nocturnal) should be the next major goal for subjects on insulin treatment. The use of insulin pumps along with continuous glucose monitors (CGMs) has made it easier but requires significant resources and patient education. Research is ongoing to close the loop by integrating the pump and the CGM using different algorithms. The currently available closed-loop system is the threshold suspend. Steps needed to achieve a near-perfect closed-loop are (1) a control-to-range system that will reduce the incidence and/or severity of hyper- and/or hypoglycemia by adjusting the insulin dose and (2) a control-to-target system, a fully automated or hybrid system that sets target glucose levels to individual needs and maintains glucose levels throughout the day using insulin (unihormonal) alone or with other hormones such as glucagon or possibly pramlintide (bihormonal). Future research is also focusing on better insulin delivery devices (pumps), more accurate CGMs, better predictive algorithms, and ultra-rapid-acting insulin analogs to make the closed-loop system as physiological as possible.

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Glucose Sensor Membranes for Mitigating the Foreign Body Response

Cited by 38 publications

References 95 publications

In vivo continuous and simultaneous monitoring of brain energy substrates with a multiplex amperometric enzyme-based biosensor device

In vivo continuous and simultaneous monitoring of brain energy substrates with a multiplex amperometric enzyme-based biosensor device

In Vivo Analytical Performance of Nitric Oxide-Releasing Glucose Biosensors

Closed-Loop System in the Management of Diabetes: Past, Present, and Future

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