CNT and proteins for bioelectronics in personalized medicine

From their discovery, CNTs have increasingly attracted interest because of their peculiar electrical, mechanical, and chemical properties. In 1991, Sumio Iijima first observed and described in detail the atomic arrangement of this new type of carbon structure [1]. By a technique used for fullerene synthesis, he produced needle-like tubes at the cathode of an arc-discharge evaporator. From that time, carbon nanotubes have been used for many applications and represent one of the most typical building blocks used in nanotechnology. Their peculiarities include unique properties of field emission and electronic transport, higher mechanical strength with respect to other materials, and interesting chemical features. The use of CNTs has recently gained momentum in the development of electrochemical biosensors, since their utilization can create devices with enhanced sensitivity and detection limit capable of detecting compounds in concentrations comparable to those present in the human body. This chapter will review the most important features of carbon nanotubes, and present an example in which their application can enhance the detection of drugs and metabolites relevant in personalized medicine: P450 biosensors for therapeutic drug monitoring.

Continuous monitoring of Naproxen by a cytochrome P450-based electrochemical sensor

Camilla Baj-Rossi, Sandro Carrara, Andrea Cavallini, Giovanni De Micheli

This paper reports the characterization of an electrochemical biosensor for the continuous monitoring of Naproxen based on cytochrome P450. The electrochemical biosensor is based on the drop-casting of multi-walled carbon-nanotubes (MWCNTs) and microsomal cytochrome P4501A2 (msCYP1A2) on a graphite screen-printed electrode (SPE). The proposed biosensor was employed to monitor Naproxen (NAP), a well-known anti-inflammatory compound, through cyclic voltammetry. The dynamic linear range for the amperometric detection of NAP had an upper limit of 300 µM with a corresponding limit of detection (LOD) of 16±1 µM (S/N=3), which is included in NAP physiological range (9–300 µM). The MWCNT/msCYP1A2-SPE sensor was also calibrated for NAP detection in mouse serum that was previously extracted from mice, showing a slightly higher LOD (33±18 µM). The stability of the msCYP1A2-based biosensor was assessed by longtime continuous cyclic voltammetric measurements. The ability of the sensor to monitor drug delivery was investigated by using a commercial micro-osmotic pump. Results show that the MWCNT/msCYP1A2-SPE sensor is capable of precisely monitoring the real-time delivery of NAP for 16 h. This work proves that the proposed electrochemical sensor might represent an innovative point-of-care solution for the personalization of drug therapies, as well as for pharmacokinetic studies in both animals and humans.

Elsevier2014

An implantable biosensor array for personalized therapy applications

Andrea Cavallini

At present, most of the tests involved in personalized medicine are complex and must be conducted in specialized centers. The development of appropriate, fast and inexpensive diagnostic technologies can encourage medical personnel in performing preventive tests, providing the driving force to push users, industry and administrations to the adoption of personalized therapy policies. In this respect, the development of new biosensors for various healthcare applications needs may represent a concrete incentive. The objective of this PhD project is the development of a fully implantable biosensor plat- form for personalized therapy applications. The thesis present innovative research on the electrochemical detection of common marketed drugs, drug cocktails, glucose and ATP with biosensors based on cytochromes P450 and different oxidases. The inclusion of carbon nan- otubes provided increased sensitivity and detection limit, enabling the detection of several drugs in their therapeutic range in undiluted human serum. A miniaturized, passive substrate capable to host 5 independent biosensor electrodes, a pH sensor, a temperature sensor as well as an interface for the signal processing electron- ics has been designed, microfabricated and tested. Different and reproducible nano-bio- functionalization for the single electrodes was obtained with high spatial resolution via selec- tive electrodeposition of chitosan/carbon nanotubes/enzyme solutions at the various elec- trodes. The array, completely fabricated with biocompatible materials, was then integrated with a CMOS circuit and a remote powering coil for the realization of a fully implantable device. The assembled system has been packaged with an inner moisture barrier in parylene C, to prevent circuit corrosion and toxic metals leaking, and an external biocompatible silicone shell to improve the host tolerance and reduce the local inflammation. The efficacy of the parylene barrier, as well as the toxicity of carbon nanotubes, has been assessed with in-vitro cytotoxicity tests conform to the ISO-109931 standards. The final packaged device was then implanted in mice to assess its short-term biocompatibility. Comparison between 7 and 30 days in in vivo implantations showed significant reduction of the inflammatory response in time, suggesting normal host recovery.

EPFL2013

Rapid and Digital Detection of Inflammatory Biomarkers Enabled by a Novel Portable Nanoplasmonic Imager

Hatice Altug, Alexander Belushkin, Filiz Yesilköy

New point-of-care diagnostic devices are urgently needed for rapid and accurate diagnosis, particularly in the management of life-threatening infections and sepsis, where immediate treatment is key. Sepsis is a critical condition caused by systemic response to infection, with chances of survival drastically decreasing every hour. A novel portable biosensor based on nanoparticle-enhanced digital plasmonic imaging is reported for rapid and sensitive detection of two sepsis-related inflammatory biomarkers, procalcitonin (PCT) and C-reactive protein (CRP) directly from blood serum. The device achieves outstanding limit of detection of 21.3 pg mL(-1) for PCT and 36 pg mL(-1) for CRP, and dynamic range of at least three orders of magnitude. The portable device is deployed at Vall d'Hebron University Hospital in Spain and tested with a wide range of patient samples with sepsis, noninfectious systemic inflammatory response syndrome (SIRS), and healthy subjects. The results are validated against ultimate clinical diagnosis and currently used immunoassays, and show that the device provides accurate and robust performance equivalent to gold-standard laboratory tests. Importantly, the plasmonic imager can enable identification of PCT levels typical of sepsis and SIRS patients in less than 15 min. The compact and low-cost device is a promising solution for assisting rapid and accurate on-site sepsis diagnosis.

WILEY-V C H VERLAG GMBH2019

An implantable biosensor array for personalized therapy applications

Andrea Cavallini

EPFL2013