Showing total 69 results

1. Modifications of cubic SiC surfaces studied by ab initio simulations: from gas adsorption to organic functionalization.

Author

Alessandra Catellani and Giancarlo Cicero

Subjects

*PAPER, *DETECTORS, *EXPERIMENTS, *SEMICONDUCTORS, *BIOMEDICAL materials

Abstract

The ability to manipulate semiconductor surfaces and interfaces has gained significant attention in the past few years, in particular to design novel routes for the development of sensors and new materials, like intelligent tissues, for bio-physics applications. In this paper, we review some recent results on the atomic manipulation of cubic silicon carbide (SiC) surfaces, as obtained by ab initio simulations, and compare them with the available experimental data. The main focus will be the study of the interaction and adsorption mechanism of simple molecules on SiC surfaces. SiC, and in particular the cubic polytype, is a wide-gap semiconductor, that for its inertness and transparency has been and still is considered a leading candidate material for biocompatible devices. [ABSTRACT FROM AUTHOR]

Published

2007

2. Predictive control of 2D spatial thermal dose delivery in atmospheric pressure plasma jets.

Author

Gidon, Dogan, Graves, David B, and Mesbah, Ali

Subjects

PLASMA jets, ATMOSPHERIC pressure, PLASMA pressure, PLASMA sheaths, MANUFACTURING processes, BIOMEDICAL materials, PSYCHOLOGICAL feedback

Abstract

Atmospheric pressure plasma jets (APPJs) are unique devices for processing of heat and pressure sensitive (bio)materials. However, operational challenges of APPJs such as run-to-run variability in dynamics and sensitivity to disturbances can complicate safe and reliable delivery of the spatially distributed cumulative effects of plasma, or plasma dose, to complex surfaces. This paper presents a hierarchical feedback control strategy based on model predictive control for regulating the spatial thermal dose delivery to a surface. Closed-loop control experiments demonstrate the effectiveness of the proposed control strategy in drastically improving the spatial uniformity of thermal dose delivery in the presence of step changes in the jet tip-to-surface distance as well as abrupt changes in the substrate type. The proposed feedback control strategy shows promise for improving the reliability and effectiveness of spatially uniform treatment of complex surfaces in medical and materials processing applications of APPJs. [ABSTRACT FROM AUTHOR]

Published

2019

3. Synthesis of pure iron magnetic nanoparticles in large quantity.

Author

Tiwary, C S, Kashyap, S, Biswas, K, and Chattopadhyay, K

Subjects

NANOPARTICLES, IRON, MAGNETIZATION, MILLING (Metalwork), COLLOID synthesis, BIOMEDICAL materials

Abstract

Free nanoparticles of iron (Fe) and their colloids with high saturation magnetization are in demand for medical and microfluidic applications. However, the oxide layer that forms during processing has made such synthesis a formidable challenge. Lowering the synthesis temperature decreases rate of oxidation and hence provides a new way of producing pure metallic nanoparticles prone to oxidation in bulk amount (large quantity). In this paper we have proposed a methodology that is designed with the knowledge of thermodynamic imperatives of oxidation to obtain almost oxygen-free iron nanoparticles, with or without any organic capping by controlled milling at low temperatures in a specially designed high-energy ball mill with the possibility of bulk production. The particles can be ultrasonicated to produce colloids and can be bio-capped to produce transparent solution. The magnetic properties of these nanoparticles confirm their superiority for possible biomedical and other applications. [ABSTRACT FROM AUTHOR]

Published

2013

4. Hydrophilic PEO-PDMS for microfluidic applications.

Author

Mingjin Yao and Ji Fang

Subjects

HYDROPHILIC compounds, POLYDIMETHYLSILOXANE, MICROFLUIDIC devices, BIOMEDICAL materials, MICROFABRICATION, BIOENGINEERING, POLYMERIZATION, SURFACE chemistry

Abstract

Polydimethylsiloxane (PDMS) is a popularly used nontoxic and biocompatible material in microfluidic systems, which is relatively cheap and does not break easily like glass. The simple fabrication, optical transparency and elastomeric property make PDMS a handy material to work with. In order to develop different applications of PDMS in microfluidics and bioengineering, it is necessary to modify the PDMS surface nature to improve wetting characteristics, and to have a better control in nonspecific binding of proteins and cells, as well as to increase adhesion. At the moment, the hydrophilic surface modification performance of PDMS is known to recover its hydrophobicity shortly after oxidation modification, which is not stable in the long term (Owen and Smith 1994 J. Adhes. Sci. Technol. 8 1063-75). This paper presents a long-term stable hydrophilic surface modification processing of PDMS. The poly(dimethylsiloxane-ethylene oxide polymeric) (PDMS-b-PEO) is used in this project as a surfactant additive to be added into the PDMS base and the curing agent mixture during polymerization and to create hydrophilic PEO-PDMS. The contact angle can be controlled at 21.5-80.9? with the different mixing ratios and the hydrophilicity will remain stable for two months and then slightly varied later. We also investigate the bonding conditions of the modified PDMS to a silicon wafer and a glass wafer. To demonstrate its applications, we designed a device which consists of microchannels on a silicon wafer, and PEO-PDMS is utilized as a cover sheet. The capillary function was investigated under the different contact angles of PED-PDMS and with different aspect ratios of microchannels. All of the processes and testing data are presented in detail. This easy and cost-effective modified PDMS with a good bonding property can be widely used in the capillary device and systems, and microfluidic devices for fluid flow control of the microchannels in biological, chemical, medical applications [ABSTRACT FROM AUTHOR]

Published

2012

5. Alternated process for the deep etching of titanium.

Author

Tillocher, T, Lefaucheux, P, Boutaud, B, and Dussart, R

Subjects

TITANIUM, SURFACE roughness, CHLORINE, BIOMEMS, BIOMEDICAL materials, ANISOTROPY, BIOCOMPATIBILITY

Abstract

Titanium is increasingly used as a platform material in microdevices dedicated to biological and bio medical applications. Existing processes for titanium deep etching use a chlorine based chemistry. This paper reports on a low reproducibility for such chemistries when titanium samples are glued onto a silicon carrier wafer. In this case, a SiOCl layer redeposits on the chamber walls as well as on the sample surface. This leads to a decrease of the etch rate and the formation of a very high roughness with a similar morphology as black silicon. The alternated process for the deep etching of titanium (APETi) described in this paper has been designed to improve the overall reproducibility by preventing high roughness formation. It is a time-multiplexed process where Cl2/Ar plasma steps are alternated with SF6 plasma steps. The first step aims at etching with vertical walls (anisotropy) while the second aims at reducing the roughness by removing SiOCl from the sample surface. [ABSTRACT FROM AUTHOR]

Published

2014

6. Bonding process using integrated electrothermal actuators for microfluidic circuit fabrication.

Author

Emilio Franco, Francisco Perdigones, Blas Salvador, and José Manuel Quero

Subjects

POLYMETHYLMETHACRYLATE, BIOMEDICAL materials, FURNACE atomic absorption spectroscopy, GLASS transitions, PHASE transitions

Abstract

In this paper, the fabrication of plastic microfluidic circuits using integrated electrothermal actuators is described. The materials used to do this task are aluminium, biocompatible glue and polymethylmethacrylate (PMMA). These materials are processed to integrate electrothermal actuators on transparent and biocompatible PCB-like substrates. The actuators reach a temperature between the glass transition temperature and the melting point of the PMMA in order to perform the bonding. The PCB-like substrate allows the integration of additional circuitry if required. The proposed method of fabrication guarantees transparent devices. To do this task, the facilities are not expensive, and allow industrial production because many devices can be assembled at the same time. Finally, the proposed method is checked. In order to do so, a T-junction microfluidic circuit for bubbles generation is fabricated. The microchannels have a width of m and a height of m. The generation of bubbles was tested with successful results and good correspondence with the theoretical behaviour. Leakages were not observed during experiments, demonstrating the feasibility of the bonding method for fabricating microfluidic devices using thermoplastics materials. [ABSTRACT FROM AUTHOR]

Published

2018

7. Sources of error in tetrapolar impedance measurements on biomaterials and other ionic conductors.

Author

Sverre Grimnes and Ørjan G Martinsen

Subjects

*BIOMEDICAL materials, *BIOELECTRIC impedance, *ELECTRICAL conductors, *ELECTRODES

Abstract

Tetrapolar electrode systems are commonly used for impedance measurements on biomaterials and other ionic conductors. They are generally believed to be immune to the influence from electrode polarization impedance and little can be found in the literature about possible pitfalls or sources of error when using tetrapolar electrode systems. In this paper we show that electrode polarization impedance can indeed influence the measurements and that also other phenomena such as negative sensitivity regions, separate current paths and common-mode signals may seriously spoil the measured data. [ABSTRACT FROM AUTHOR]

Published

2007

8. A study of atmospheric pressure plasma discharges for surface functionalization of PTFE used in biomedical applications.

Author

C Sarra, S Turgeon, D Mantovani, and G Laroche

Subjects

ATMOSPHERIC pressure, ELECTRIC discharges, GLOW discharges, BIOMEDICAL materials

Abstract

Plasma polymer surface modification is widely used in the biomedical field to tailor the surface properties of materials to improve their biocompatibility. Most of these treatments are performed using low pressure plasma systems but recently, filamentary dielectric barrier discharge (FDBD) and atmospheric pressure glow discharge (APGD) have appeared as interesting alternatives. The aim of this paper is to evaluate the potential of surface modifications realized with FDBD and APGD in different atmospheres (N2+ H2and N2+ NH3mixtures) on poly(tetrafluoroethylene) to determine the relative influence of both the discharge regime and the gas nature on the surface transformations. From XPS analysis, it is shown that the discharge regime can have a significant effect on the surface transformation; FDBDs operating in H2/N2lead to a high concentration of amino-groups with high specificity but also important damaging on the surface. Glow discharges in both H2/N2and NH3/N2lead to lower concentrations of amino-groups with lower specificity but lower surface damaging. Therefore, this simple surface treatment seems to be an effective, low cost method for the production of uniform surface modification with amino-groups that can subsequently be used to graft various chemical functionalities used for biomaterial compatibility. [ABSTRACT FROM AUTHOR]

Published

2006

9. High quality factor, protein-based microlasers from self-assembled microcracks.

Author

Nguyen, Tam Trong, Mai, Hanh Hong, Van Pham, Thin, Nguyen, Thau Xuan, and Ta, Van Duong

Subjects

QUALITY factor, WHISPERING gallery modes, BIOMEDICAL materials

Abstract

In the last decade, microlasers with biological origin have shown their great potential in biosensing and bioimaging. Several micro-structures have been developed for high quality (Q) factor biolasers including Fabry–Pérot, distributed feedback and whispering gallery mode cavities. However, the fabrication of these lasers is generally complicated and their operation is strongly affected by cavity defects. In this work, we demonstrate random protein-based microlasers fabricated by a simple one-step self-assembled method. The lasing can be achieved from microcracks with random structures. The lasing threshold is around 14 mJ cm−2 and the quality factor of lasing modes can be up to which are comparable with other conventional biolasers. Our work opens a new possibility for the fabrication of high Q factor microlasers from biocompatible materials, with great potential for biosensing and biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2021

10. Multi-level molecular modelling for plasma medicine.

Author

Annemie Bogaerts, Narjes Khosravian, Jonas Van der Paal, Christof C W Verlackt, Maksudbek Yusupov, Balu Kamaraj, and Erik C Neyts

Subjects

PLASMA gases, MOLECULAR models, DENSITY functional theory, QUANTUM mechanics, CELL membranes, BIOMEDICAL materials

Abstract

Modelling at the molecular or atomic scale can be very useful for obtaining a better insight in plasma medicine. This paper gives an overview of different atomic/molecular scale modelling approaches that can be used to study the direct interaction of plasma species with biomolecules or the consequences of these interactions for the biomolecules on a somewhat longer time-scale. These approaches include density functional theory (DFT), density functional based tight binding (DFTB), classical reactive and non-reactive molecular dynamics (MD) and united-atom or coarse-grained MD, as well as hybrid quantum mechanics/molecular mechanics (QM/MM) methods. Specific examples will be given for three important types of biomolecules, present in human cells, i.e. proteins, DNA and phospholipids found in the cell membrane. The results show that each of these modelling approaches has its specific strengths and limitations, and is particularly useful for certain applications. A multi-level approach is therefore most suitable for obtaining a global picture of the plasma–biomolecule interactions. [ABSTRACT FROM AUTHOR]

Published

2016

11. Fluence-based dosimetry of proton and heavier ion beams using single track detectors.

Author

G Klimpki, H Mescher, M S Akselrod, O Jäkel, and S Greilich

Subjects

RADIATION dosimetry, ION beams, BIOMEDICAL materials, NUCLEAR track detectors, RADIOTHERAPY, HEAVY ions

Abstract

Due to their superior spatial resolution, small and biocompatible fluorescent nuclear track detectors (FNTDs) open up the possibility of characterizing swift heavy charged particle fields on a single track level. Permanently stored spectroscopic information such as energy deposition and particle field composition is of particular importance in heavy ion radiotherapy, since radiation quality is one of the decisive predictors for clinical outcome. Findings presented within this paper aim towards single track reconstruction and fluence-based dosimetry of proton and heavier ion fields. Three-dimensional information on individual ion trajectories through the detector volume is obtained using fully automated image processing software. Angular distributions of multidirectional fields can be measured accurately within  ±2° uncertainty. This translates into less than 5% overall fluence deviation from the chosen irradiation reference. The combination of single ion tracking with an improved energy loss calibration curve based on 90 FNTD irradiations with protons as well as helium, carbon and oxygen ions enables spectroscopic analysis of a detector irradiated in Bragg peak proximity of a 270 MeV u−1 carbon ion field. Fluence-based dosimetry results agree with treatment planning software reference. [ABSTRACT FROM AUTHOR]

Published

2016

12. Biocompatible circuit-breaker chip for thermal management of biomedical microsystems.

Author

Yi Luo, Masoud Dahmardeh, and Kenichi Takahata

Subjects

TEMPERATURE, SHAPE memory alloys, ACTUATORS, ARTIFICIAL implants, MICROELECTROMECHANICAL systems, BIOMEDICAL materials

Abstract

This paper presents a thermoresponsive micro circuit breaker for biomedical applications specifically targeted at electronic intelligent implants. The circuit breaker is micromachined to have a shape-memory-alloy cantilever actuator as a normally closed temperature-sensitive switch to protect the device of interest from overheating, a critical safety feature for smart implants including those that are electrothermally driven with wireless micro heaters. The device is fabricated in a size of 1.5  ×  2.0  ×  0.46 mm3 using biocompatible materials and a chip-based titanium package, exhibiting a nominal cold-state resistance of 14 Ω. The breaker rapidly enters the full open condition when the chip temperature exceeds 63 °C, temporarily breaking the circuit of interest to lower its temperature until chip temperature drops to 51 °C, at which the breaker closes the circuit to allow current to flow through it again, physically limiting the maximum temperature of the circuit. This functionality is tested in combination with a wireless resonant heater powered by radio-frequency electromagnetic radiation, demonstrating self-regulation of heater temperature. The developed circuit-breaker chip operates in a fully passive manner that removes the need for active sensor and circuitry to achieve temperature regulation in a target device, contributing to the miniaturization of biomedical microsystems including electronic smart implants where thermal management is essential. [ABSTRACT FROM AUTHOR]

Published

2015

13. Fabrication of polyimide based microfluidic channels for biosensor devices.

Author

Azeem Zulfiqar, Andrea Pfreundt, Winnie Edith Svendsen, and Maria Dimaki

Subjects

BIOSENSORS, POLYIMIDES, MICROFLUIDIC devices, POINT-of-care testing, BOND strengths, BIOMEDICAL materials

Abstract

The ever-increasing complexity of the fabrication process of Point-of-care (POC) devices, due to high demand of functional versatility, compact size and ease-of-use, emphasizes the need of multifunctional materials that can be used to simplify this process. Polymers, currently in use for the fabrication of the often needed microfluidic channels, have limitations in terms of their physicochemical properties. Therefore, the use of a multipurpose biocompatible material with better resistance to the chemical, thermal and electrical environment, along with capability of forming closed channel microfluidics is inevitable. This paper demonstrates a novel technique of fabricating microfluidic devices using polyimide (PI) which fulfills the aforementioned properties criteria. A fabrication process to pattern microfluidic channels, using partially cured PI, has been developed by using a dry etching method. The etching parameters are optimized and compared to those used for fully cured PI. Moreover, the formation of closed microfluidic channel on wafer level by bonding two partially cured PI layers or a partially cured PI to glass with high bond strength has been demonstrated. The reproducibility in uniformity of PI is also compared to the most commonly used SU8 polymer, which is a near UV sensitive epoxy resin. The potential applications of PI processing are POC and biosensor devices integrated with microelectronics. [ABSTRACT FROM AUTHOR]

Published

2015

14. Recent Advancement in Bio-precursor derived graphene quantum dots: Synthesis, Characterization and Toxicological Perspective.

Author

Tade, Rahul S, Nangare, Sopan N, Patil, Ashwini G, Pandey, Abhieet, Deshmukh, Prashant K, Patil, Dilip R, Agrawal, Tanisha N, Mutalik, Srinivas, Patil, Arun M, More, Mahesh P, Bari, Sanjay B, and Patil, Pravin O

Subjects

QUANTUM dot synthesis, BIOMEDICAL materials, INDUSTRIAL wastes, QUANTUM dots, GRAPHENE synthesis

Abstract

Graphene quantum dots (GQDs), impressive materials with enormous future potential, are reviewed from their inception, including different precursors. Considering the increasing burden of industrial and ecological bio-waste, there is an urgency to develop techniques which will convert biowaste into active moieties of interest. Amongst the various materials explored, we selectively highlight the use of potential carbon containing bioprecursors (e.g. plant-based, amino acids, carbohydrates), and industrial waste and its conversion into GQDs with negligible use of chemicals. This review focuses on the effects of different processing parameters that affect the properties of GQDs, including the surface functionalization, paradigmatic characterization, toxicity and biocompatibility issues of bioprecursor derived GQDs. This review also examines current challenges and s the ongoing exploration of potential bioprecursors for ecofriendly GQD synthesis for future applications. This review sheds further light on the electronic and optical properties of GQDs along with the effects of doping on the same. This review may aid in future design approaches and applications of GQDs in the biomedical and materials design fields. [ABSTRACT FROM AUTHOR]

Published

2020

15. Special cluster issue on tribocorrosion of dental materials.

Author

Mathew, Mathew T and Stack, Margaret M

Subjects

TRIBO-corrosion, DENTAL materials, BIOMEDICAL materials, DENTAL enamel, DENTAL caries, DENTAL implants

Abstract

Tribocorrosion affects all walks of life from oil and gas conversion to biomedical materials. Wear can interact with corrosion to enhance it or impede it; conversely, corrosion can enhance or impede wear. The understanding of the interactions between physical and chemical phenomena has been greatly assisted by electrochemical and microscopic techniques. In dentistry, it is well recognized that erosion due to dissolution (a term physicists use to denote wear) of enamel can result in tooth decay; however, the effects of the oral environment, i.e. pH levels, electrochemical potential and any interactions due to the forces involved in chewing are not well understood. This special cluster issue includes investigations on the fundamentals of wear–corrosion interactions involved in simulated oral environments, including candidate dental implant and veneer materials. The issue commences with a fundamental study of titanium implants and this is followed by an analysis of the behaviour of commonly used temporomandibular devices in a synovial fluid-like environment. The analysis of tribocorrosion mechanisms of Ti6Al4V biomedical alloys in artificial saliva with different pHs is addressed and is followed by a paper on fretting wear, on hydroxyapatite-titanium composites in simulated body fluid, supplemented with protein (bovine serum albumin). The effects of acid treatments on tooth enamel, and as a surface engineering technique for dental implants, are investigated in two further contributions. An analysis of the physiological parameters of intraoral wear is addressed; this is followed by a study of candidate dental materials in common beverages such as tea and coffee with varying acidity and viscosity and the use of wear maps to identify the safety zones for prediction of material degradation in such conditions. Hence, the special cluster issue consists of a range of tribocorrosion contributions involving many aspects of dental tribocorrosion, from analysis of physiological approaches and tissue engineering to studying of the effects of the environments encountered in clinical practice and management which lead to tooth decay. A wide range of analytical techniques and tribocorrosion experimental approaches is used to simulate, assess and model the synergistic interactions of wear and corrosion, many of them leading to new insights. We hope it will lead to increased awareness of tribocorrosion phenomena for researchers and dental clinicians alike and ‘food for thought’ for further studies in this field. [ABSTRACT FROM AUTHOR]

Published

2013

16. Optimal multisine excitation design for broadband electrical impedance spectroscopy.

Author

B Sanchez, G Vandersteen, R Bragos, and J Schoukens

Subjects

ELECTRONIC excitation, IMPEDANCE spectroscopy, CELL culture, BIOMEDICAL materials, BODY composition, CELLULAR therapy, TISSUE engineering

Abstract

Electrical impedance spectroscopy (EIS) can be used to characterize biological materials in applications ranging from cell culture to body composition, including tissue and organ state. The emergence of cell therapy and tissue engineering opens up a new and promising field of application. While in most cases classical measurement techniques based on a frequency sweep can be used, EIS based on broadband excitations enables dynamic biological systems to be characterized when the measuring time and injected energy are a constraint. Myocardial regeneration, cell characterization in micro-fluidic systems and dynamic electrical impedance tomography are all examples of such applications. The weakness of such types of fast EIS measuring techniques resides in their intrinsic loss of accuracy. However, since most of the practical applications have no restriction over the excitation used, the input power spectrum can be appropriately designed to maximize the accuracy obtained from the measurements. This paper deals with the problem of designing the optimal multisine excitation for electrical bioimpedance measurements. The optimal multisine is obtained by the minimization of the Cramer-Rao lower bound, or what is the same, by maximizing the accuracy obtained from the measurements. Furthermore, because no analytical solution exists for global optimization involving time and frequency domains jointly, this paper presents the multisine optimization approach partially in both domains and then combines the results. As regards the frequency domain approach, a novel contribution is made for the multisine amplitude power spectrum. In the time domain, multisine is optimized by reducing its crest factor. Moreover, the impact on the information and accuracy of the impedance spectrum obtained from using different multisine amplitude power spectra is discussed, as well as the number of frequencies and frequency distributions. The theory is supported by a set of validation measurements when exciting with the optimal and flat multisine signals and compared to a single frequency ac impedance analyzer when characterizing an RC circuit. In vivo healthy myocardium tissue electrical impedance measurements show that broadband EIS based on multisine excitations enable the characterization of dynamic biological systems. [ABSTRACT FROM AUTHOR]

Published

2011

17. Plasma nanoscience: setting directions, tackling grand challenges.

Author

Uros Cvelbar and Anthony B Murphy

Subjects

PLASMA gases, NANOSCIENCE, NANOSTRUCTURES, CARBON nanotubes, GRAPHENE, NANODIAMONDS, NANOPARTICLES, BIOMEDICAL materials

Abstract

This review paper presents historical perspectives, recent advances and future directions in the multidisciplinary research field of plasma nanoscience. The current status and future challenges are presented using a three-dimensional framework. The first and the largest dimension covers the most important classes of nanoscale objects (nanostructures, nanofeatures and nanoassemblies/nanoarchitectures) and materials systems, namely carbon nanotubes, nanofibres, graphene, graphene nanoribbons, graphene nanoflakes, nanodiamond and related carbon-based nanostructures; metal, silicon and other inorganic nanoparticles and nanostructures; soft organic nanomaterials; nano-biomaterials; biological objects and nanoscale plasma etching. In the second dimension, we discuss the most common types of plasmas and plasma reactors used in nanoscale plasma synthesis and processing. These include low-temperature non-equilibrium plasmas at low and high pressures, thermal plasmas, high-pressure microplasmas, plasmas in liquids and plasma-liquid interactions, high-energy-density plasmas, and ionized physical vapour deposition as well as some other plasma-enhanced nanofabrication techniques. In the third dimension, we outline some of the 'Grand Science Challenges' and 'Grand Socio-economic Challenges' to which significant contributions from plasma nanoscience-related research can be expected in the near future. The urgent need for a stronger focus on practical, outcome-oriented research to tackle the grand challenges is emphasized and concisely formulated as from controlled complexity to practical simplicity in solving grand challenges. [ABSTRACT FROM AUTHOR]

Published

2011

18. Modelling of atmospheric pressure plasmas for biomedical applications.

Author

H W Lee, G Y Park, Y S Seo, Y H Im, S B Shim, and H J Lee

Subjects

MATHEMATICAL models, ATMOSPHERIC pressure, BIOMEDICAL materials, LOW temperatures, SIMULATION methods & models, PLASMA devices, ELECTRIC potential, SURFACES (Technology)

Abstract

As interest has increased in the interaction between low-temperature plasmas and living cells or organic materials, the role of modelling and simulation of atmospheric pressure plasmas has become important in understanding the effects of charged particles and radicals in biomedical applications. This review paper introduces the general properties of low-temperature atmospheric pressure plasma devices for biomedical applications and explains recently reported simulation results. Control parameters of atmospheric pressure plasmas, such as gas mixture composition, driving frequency and voltage and the function shape of sinusoidal and pulsed power, are considered through both a review of previous findings and new simulation results in order to improve plasma properties for given purposes. Furthermore, the simulation or modelling techniques are explained along with surface interactions of the plasma for the future development of simulation codes to study the interaction of plasmas with living cells. [ABSTRACT FROM AUTHOR]

Published

2011

19. Exchange bias effect in Au-Fe3O4 nanocomposites.

Author

Chandra, Sayan, Huls, N A Frey, Phan, M H, Srinath, S, Garcia, M A, Lee, Youngmin, Wang, Chao, Sun, Shouheng, Iglesias, Òscar, and Srikanth, H

Subjects

NANOCOMPOSITE materials, DIMERS, ANISOTROPIC crystals, MONTE Carlo method, BIOMEDICAL materials, IRON oxides

Abstract

We report exchange bias (EB) effect in the Au-Fe3O4 composite nanoparticle system, where one or more Fe3O4 nanoparticles are attached to an Au seed particle forming ‘dimer’ and ‘cluster’ morphologies, with the clusters showing much stronger EB in comparison with the dimers. The EB effect develops due to the presence of stress at the Au-Fe3O4 interface which leads to the generation of highly disordered, anisotropic surface spins in the Fe3O4 particle. The EB effect is lost with the removal of the interfacial stress. Our atomistic Monte Carlo studies are in excellent agreement with the experimental results. These results show a new path towards tuning EB in nanostructures, namely controllably creating interfacial stress, and opens up the possibility of tuning the anisotropic properties of biocompatible nanoparticles via a controllable exchange coupling mechanism. [ABSTRACT FROM AUTHOR]

Published

2014

20. Wound healing and antibacterial activities of chondroitin sulfate- and acharan sulfate-reduced silver nanoparticles.

Author

Im, A-Rang, Kim, Jee Young, Kim, Hyun-Seok, Cho, Seonho, Park, Youmie, and Kim, Yeong Shik

Subjects

WOUND healing, CHONDROITIN sulfates, SILVER nanoparticles, ANTIBACTERIAL agents, BIOMEDICAL materials, GLYCOSAMINOGLYCANS

Abstract

For topical applications in wound healing, silver nanoparticles (AgNPs) have attracted much attention as antibacterial agents. Herein, we describe a green-synthetic route for the production of biocompatible and crystalline AgNPs using two glycosaminoglycans, chondroitin sulfate (CS) and acharan sulfate (AS), as reducing agents. The synthetic approach avoids the use of toxic chemicals, and the yield of AgNPs formation is found to be 98.1% and 91.1% for the chondroitin sulfate-reduced silver nanoparticles (CS-AgNPs) and the acharan sulfate-reduced silver nanoparticles (AS-AgNPs), respectively. Nanoparticles with mostly spherical and amorphous shapes were observed, with an average diameter of 6.16 ± 2.26 nm for CS-AgNPs and 5.79 ± 3.10 nm for AS-AgNPs. Images of the CS-AgNPs obtained from atomic force microscopy revealed the self-assembled structure of CS was similar to a densely packed woven mat with AgNPs sprinkled on the CS. These nanoparticles were stable under cell culture conditions without any noticeable aggregation. An approximately 128-fold enhancement of the antibacterial activities of the AgNPs was observed against Enterobacter cloacae and Escherichia coli when compared to CS and AS alone. In addition, an in vivo animal model of wound healing activity was tested using mice that were subjected to deep incision wounds. In comparison to the controls, the ointments containing CS-AgNPs and AS-AgNPs stimulated wound closure under histological examination and accelerated the deposition of granulation tissue and collagen in the wound area. The wound healing activity of the ointments containing CS-AgNPs and AS-AgNPs are comparable to that of a commercial formulation of silver sulfadiazine even though the newly prepared ointments contain a lower silver concentration. Therefore, the newly prepared AgNPs demonstrate potential for use as an attractive biocompatible nanocomposite for topical applications in the treatment of wounds. [ABSTRACT FROM AUTHOR]

Published

2013

21. Preparation of non-aggregating aqueous fullerenes in highly saline solutions with a biocompatible non-ionic polymer.

Author

Aich, Nirupam, Boateng, Linkel K, Flora, Joseph R V, and Saleh, Navid B

Subjects

FULLERENES, BIOCOMPATIBILITY, TRANSMISSION electron microscopy, MOLECULAR dynamics, BIOMEDICAL materials, LIGHT scattering

Abstract

Size-tunable stable aqueous fullerenes were prepared with different concentrations of biocompatible block-copolymer pluronic (PA) F-127, ranging from 0.001% to 1% (w/v). Size uniformity increased with the increase in PA concentration, yielding optimum 58.8 ± 5.6 and 61.8 ± 5.6 nm nC60s and nC70s, respectively (0.10%w/v PA), as observed using a dynamic light scattering technique. Fullerene aqueous suspensions also manifested enhanced stability in saline solution, Dulbecco’s modified Eagle medium (DMEM), and Roswell Park Memorial Institute (RPMI) culture medium. Transmission electron microscopy was performed to elaborate on the morphology and size specificity of fullerene clusters. Physicochemical characterizations of the suspended fullerenes were performed through UV–vis spectroscopy and electrophoretic mobility measurements. PA molecules showed size restriction by encasement, as observed via molecular dynamics simulations. Such solubilization with controllable size and non-aggregating behavior can facilitate application enhancement and mechanistic environmental and toxicological studies of size-specific fullerenes. [ABSTRACT FROM AUTHOR]

Published

2013

22. MEMS-based shear characterization of soft hydrated samples.

Author

Higgs, Gadryn C., Simmons, Chelsey S., Yingning Gao, Fried, Andrew T., Sung-Jin Park, Cindy Chung, and Pruitt, Beth L.

Subjects

MICROELECTROMECHANICAL systems, BIOLOGICAL specimen analysis, BIOMATERIALS, POLYETHYLENE glycol, ATOMIC force microscopes, CELL analysis, ACTUATORS, BIOMEDICAL materials

Abstract

We have designed, fabricated, calibrated and tested actuators for shear characterization to assess microscale shear properties of soft substrates. Here, we demonstrate characterization of dry silicone and hydrated polyethylene glycol. Microscale tools, including atomic force microscopes and nanoindenters, often have limited functionality in hydrated environments. While electrostatic comb-drive actuators are particularly susceptible to moisture damage, through chemical vapor deposition of hexamethyldisiloxane, we increase the hydrophobicity of our electrostatic devices to a water contact angle 90 ± 3°. With this technique, we determine the effective shear stiffness of both dry and hydrated samples for a range of soft substrates. Using computational and analytical models, we compare our empirically determined effective shear stiffness with existing characterization methods, rheology, and nanoindentation, for samples with shear moduli ranging from 5-320 kPa. This work introduces a new approach for microscale assessment of synthetic materials that can be used on biological materials for basic and applied biomaterials research. [ABSTRACT FROM AUTHOR]

Published

2013

23. Influence of evanescent waves on the voxel profile in multipulse multiphoton polymerization nanofabrication.

Author

Wei Li, Tianxiang Cao, Zhaohui Zhai, Xuanyi Yu, Xinzheng Zhang, and Jingjun Xu

Subjects

NANOFABRICATION, WAVELENGTHS, DIRECT laser writing, MULTIPHOTON absorption, PHOTONICS, MICROFLUIDICS, BIOMEDICAL materials

Abstract

The relationship between the profile of the structures obtained by multiphoton polymerization and the optical parameters of nanofabrication systems has been studied theoretically for a multipulse scheme. We find that the profile of sub-wavelength structures is greatly affected by the evanescent waves affect. Not only is the photocured polymer voxel affected by the beam profile, but the beam propagation behavior is influenced by the photocured polymer voxel. This gives us a new view of matter-light interactions in multipulse polymerization process, which is useful to the accurate control of the nanofabrication profile and the selection of new nanofabrication materials. [ABSTRACT FROM AUTHOR]

Published

2013

24. Cell growth characterization using multi-electrode bioimpedance spectroscopy.

Author

Lu, Yi-Yu, Huang, Ji-Jer, Huang, Yu-Jie, and Cheng, Kuo-Sheng

Subjects

CELL growth, ELECTRODES, IMPEDANCE spectroscopy, BIOMEDICAL materials, STATISTICAL correlation, BIOLOGICAL monitoring

Abstract

Cell growth characterization during culturing is an important issue in a variety of biomedical applications. In this study an electrical bioimpedance spectroscopy-based multi-electrode culture monitoring system was developed to characterize cell growth. A PC12 cell line was cultured for the cell growth study. The bioimpedance variations for PC12 cell growth within the initial 12 h were measured over a range between 1 kHz and 4 MHz at three different medium concentrations. Within this frequency range, the largest bioimpedance value was 1.9 times the smallest bioimpedance value. The phase angle decreased over the range from 1 to 10 kHz when cells were growing. Then, the phase angle approached a constant over the frequency range between 10 kHz and 2 MHz. Thereafter, the phase angle increased rapidly from 20 to 52 degrees during cell culturing between 8 and 12 h at 4 MHz. The maximum cell number after culturing for 12 h increased by 25.8% for the control sites with poly-D-lysine (PDL) pastes. For the normal growth factor, the cell number increased up to 4.78 times from 8 to 12 h, but only 0.96 and 1.60 times for the other two medium growth factors. The correlation coefficients between impedance and cell number were 0.868 (coating with PDL), and 0.836 (without PDL) for the normal concentration medium. Thus, impedance may be used as an index for cell growth characterization. [ABSTRACT FROM AUTHOR]

Published

2013

25. pH stability and comparative evaluation of ranaspumin-2 foam for application in biochemical reactors.

Author

Hyo-Jick Choi, Ebersbacher, Charles F., Fu-Shi Quan, and Montemagno, Carlo D.

Subjects

BIOREACTORS, HYDROGEN-ion concentration, LIPOSOMES, BIOCHEMICAL engineering, BIOMEDICAL materials

Abstract

Aqueous channels of foam represent a simplified, natural bioreactor on the micro-/nano-scale. Previous studies have demonstrated the feasibility and potential application of foams in replicating cellular process in vitro, but no research has been performed to establish a basis for designing stable and biocompatible foam formulations. Our research has been directed specifically to the evaluation of ranaspumin-2 (RSN-2), a frog foam nest protein. The strong surfactant activity of RSN-2 enabled us to produce foams using low protein concentration (1 mg ml-1) over a wide pH range (pH ≥3). Importantly, the RSN-2 formulation exhibited the best foam stability at a near neutral pH condition, which shows a potential for application to various biosynthesis applications. Model cellular systems such as liposomes and inactivated A/PR/8/34 influenza virus maintained their physicochemical stability and full hemagglutination activity, indicating biocompatibility of RSN-2 with both cellular membranes and proteins both in bulk solution and in foam. Moreover, the addition of RSN-2 did not exert any deteriorative effects on bacterial cell growth kinetics. In contrast, Tween 20, Triton X-100, and BSA did not show satisfactory performance in terms of foamability, foam stability, physicochemcial stability, and biochemical stability. Although our study has been limited to representative formulations composed of only surfactant molecules, a number of unique advantages make RSN-2 a promising candidate for in vitro foam biosynthesis. [ABSTRACT FROM AUTHOR]

Published

2013

26. Torsional electromechanical systems based on carbon nanotubes.

Author

Hall, A. R., Paulson, S., Cui, T., Lu, J. P., Qin, L-C, and Washburn, S.

Subjects

ELECTROMECHANICAL devices, ELECTRIC properties of carbon nanotubes, NANOSTRUCTURED materials, BIOMEDICAL materials, MECHANICAL behavior of materials, BIOMEDICAL engineering

Abstract

Carbon nanotubes (CNTs) are among the most highly studied nanomaterials due to their unique (and intertwined) mechanical and electrical properties. Recent advances in fabrication have allowed devices to be fabricated that are capable of applying a twisting force to individual CNTs while measuring mechanical and electrical response. Here, we review major results from this emerging field of study, revealing new properties of the material itself and opening possibilities for advances in future devices. [ABSTRACT FROM AUTHOR]

Published

2012

27. Semi-confined compression of microfabricated polymerized biomaterial constructs.

Author

Christopher Moraes, Ruogang Zhao, Morakot Likhitpanichkul, Craig A Simmons, and Yu Sun

Subjects

*MICROFABRICATION, *POLYMERIZATION, *BIOMEDICAL materials, *FORCE & energy, *TISSUE engineering, *CELLULAR mechanics, *DEFORMATIONS (Mechanics)

Abstract

Mechanical forces are critical parameters in engineering functional tissue because of their established influence on cellular behaviour. However, identifying ideal combinations of mechanical, biomaterial and chemical stimuli to obtain a desired cellular response requires high-throughput screening technologies, which may be realized through microfabricated systems. This paper reports on the development and characterization of a MEMS device for semi-confined biomaterial compression. An array of these devices would enable studies involving mechanical deformation of three-dimensional biomaterials, an important parameter in creating physiologically relevant microenvironments in vitro. The described device has the ability to simultaneously apply a range of compressive mechanical stimuli to multiple polymerized hydrogel microconstructs. Local micromechanical strains generated within the semi-confined hydrogel cylinders are characterized and compared with those produced in current micro- and macroscale technologies. In contrast to previous work generating unconfined compression in microfabricated devices, the semi-confined compression model used in this work generates uniform regions of strain within the central portion of each hydrogel, demonstrated here to range from 20% to 45% across the array. The uniform strains achieved simplify experimental analysis and improve the utility of the compression platform. Furthermore, the system is compatible with a wide variety of polymerizable biomaterials, enhancing device versatility and usability in tissue engineering and fundamental cell biology studies. [ABSTRACT FROM AUTHOR]

Published

2011

28. Development of a stimuli-responsive polymer nanocomposite toward biologically optimized, MEMS-based neural probes.

Author

A E Hess, J R Capadona, K Shanmuganathan, L Hsu, S J Rowan, C Weder, D J Tyler, and C A Zorman

Subjects

*POLYMERIC composites, *MICROELECTROMECHANICAL systems, *NEURAL stimulation, *MOLECULAR probes, *BIOMEDICAL materials, *CELLULOSE, *POLYVINYL alcohol

Abstract

This paper reports the development of micromachining processes and mechanical evaluation of a stimuli-responsive, mechanically dynamic polymer nanocomposite for biomedical microsystems. This nanocomposite consists of a cellulose nanofiber network encased in a polyvinyl acetate matrix. Micromachined tensile testing structures fabricated from the nanocomposite displayed a reversible and switchable stiffness comparable to bulk samples, with a Young's modulus of 3420 MPa when dry, reducing to [?]20 MPa when wet, and a stiff-to-flexible transition time of [?]300 s. This mechanically dynamic behavior is particularly attractive for the development of adaptive intracortical probes that are sufficiently stiff to insert into the brain without buckling, but become highly compliant upon insertion. Along these lines, a micromachined neural probe incorporating parylene insulating/moisture barrier layers and Ti/Au electrodes was fabricated from the nanocomposite using a fabrication process designed specifically for this chemical- and temperature-sensitive material. It was found that the parylene layers only slightly increased the stiffness of the probe in the wet state in spite of its much higher Young's modulus. Furthermore, the Ti/Au electrodes exhibited impedance comparable to Au electrodes on conventional substrates. Swelling of the nanocomposite was highly anisotropic favoring the thickness dimension by a factor of 8 to 12, leading to excellent adhesion between the nanocomposite and parylene layers and no discernable deformation of the probes when deployed in deionized water. [ABSTRACT FROM AUTHOR]

Published

2011

29. Nanonewton force-controlled manipulation of biological cells using a monolithic MEMS microgripper with two-axis force feedback.

Author

Keekyoung Kim, Xinyu Liu, Yong Zhang, and Yu Sun

Subjects

*CELLS, *CELLULAR mechanics, *BIOMEDICAL materials, *THICKNESS measurement

Abstract

As mechanical end-effectors, microgrippers enable the pick-transport-place of micrometer-sized objects, such as manipulation and positioning of biological cells in an aqueous environment. This paper reports on a monolithic MEMS-based microgripper with integrated force feedback along two axes and presents the first demonstration of force- controlled micro-grasping at the nanonewton force level. The system manipulates highly deformable biomaterials (porcine interstitial cells) in an aqueous environment using a microgripper that integrates a V-beam electrothermal microactuator and two capacitive force sensors, one for contact detection (force resolution: 38.5 nN) and the other for gripping force measurements (force resolution: 19.9 nN). The MEMS-based microgripper and the force control system experimentally demonstrate the capability of rapid contact detection and reliable force-controlled micrograsping to accommodate variations in size and mechanical properties of objects with a high reproducibility. [ABSTRACT FROM AUTHOR]

Published

2008

30. Hybrid laser and reactive ion etching of Parylene-C for deinsulation of a Utah electrode array.

Author

Je-Min Yoo, Jong-In Song, Tathireddy, Prashant, Solzbacher, Florian, and Wrieth, Loren

Subjects

PLASMA etching, BIOMEDICAL materials, XYLENE, ELECTRODES, LASER ablation, SCANNING electron microscopes, X-ray photoelectron spectroscopy, LASER beams

Abstract

Electrodes used for neural interfaces are typically encapsulated by biocompatible materials such as Parylene-C. Tips of a Utah electrode array (UEA) for recording neural action potentials are typically exposed using a reactive ion etching (RIE); however, it has limitations due to the complex 3D geometry of electrode arrays, resulting in nonuniformity of deinsulated area, difficulty in achieving very fine tip exposure, and decrease in selectivity in acquiring the neural signals. The laser ablation technique can be used to deinsulate electrode tips with exposures smaller than 20 &mgr;m. However, the electrode arrays suffer from increased impedance due to redeposition of the carbon debris produced by the ablation of the Parylene-C on the active area of the electrodes. The hybrid laser and plasma etching uses a laser (KrF) ablation followed by an oxygen reactive ion etching process to better control tip exposure, particularly for electrode arrays with more complex geometries, and a lower electrode impedance at the same time. Characterization of the deinsulated electrode surface by scanning electron microscope (SEM), x-ray photoelectron spectroscopy (XPS) and impedance of a Utah electrode array (UEA) suggests that the hybrid laser/RIE method is suitable for deinsulation of UEAs for neural interface applications. [ABSTRACT FROM AUTHOR]

Published

2012

31. Gold nanostars: surfactant-free synthesis, 3D modelling, and two-photon photoluminescence imaging.

Author

Yuan, Hsiangkuo, Khoury, Christopher G., Hwang, Hanjun, Wilson, Christy M., Grant, Gerald A., and Vo-Dinh, Tuan

Subjects

COLLOIDAL gold, SURFACE active agents, PHOTOLUMINESCENCE, CHEMICAL synthesis, BIOMEDICAL materials, PHOTONS, CONTRAST media, ABSORPTION spectra

Abstract

Understanding the control of the optical and plasmonic properties of unique nanosystems‐gold nanostars‐both experimentally and theoretically permits superior design and fabrication for biomedical applications. Here, we present a new, surfactant-free synthesis method of biocompatible gold nanostars with adjustable geometry such that the plasmon band can be tuned into the near-infrared region 'tissue diagnostic window', which is most suitable for in vivo imaging. Theoretical modelling was performed for multiple-branched 3D nanostars and yielded absorption spectra in good agreement with experimental results. The plasmon band shift was attributed to variations in branch aspect ratio, and the plasmon band intensifies with increasing branch number, branch length, and overall star size. Nanostars showed an extremely strong two-photon photoluminescence (TPL) process. The TPL imaging of wheat-germ agglutinin (WGA) functionalized nanostars on BT549 breast cancer cells and of PEGylated nanostars circulating in the vasculature, examined through a dorsal window chamber in vivo in laboratory mouse studies, demonstrated that gold nanostars can serve as an efficient contrast agent for biological imaging applications. [ABSTRACT FROM AUTHOR]

Published

2012

32. Biocompatible micro, soft bellow actuator rapidly manufactured using 3D-printed soluble mold.

Author

Woojun Jung, Yoon Kang, Seungoh Han, and Yongha Hwang

Subjects

SOFT robotics, ACTUATORS, PNEUMATIC actuators, BIOMEDICAL materials, ELASTICITY, 3-D printers

Abstract

A micro, soft bellow actuator, which is fabricated using a biocompatible material (polydimethylsiloxane (PDMS)) and operates in a pneumatic manner that is harmless to the living body, has been experimentally validated using 3D-printed soluble molds and supports. Typical planar microfabrication techniques for flexible pneumatic actuators with complex geometries generally have inherent design limitations owing to the manner in which 2D thin films are stacked and require multiple lithographic and alignment steps. In this study, micro bellow actuators with 3D structures that cannot be fabricated using the existing softlithography techniques were designed by simulating the mechanical behavior of the actuator based on the nonlinear elastic properties of PDMS. The subsequently designed 3D-printed soluble-mold technique was used to fabricate the bellow actuators with a 10 µm resolution, while taking into consideration the printing quality, which depends on the printing direction and layer thickness of the 3D printer. On evaluating the operating performance, the micro bellow actuator showed a displacement of 1540 µm at the applied pneumatic pressure of 60 kPa and can apply a force of 0.14 N. Even after 10 000 repetitive operations, the change in the operating characteristic was less than 0.44%. It was also demonstrated that fast prototyping of actuators within 48 h is possible without any process revision, even with variable design changes or other soft polymer materials. The reported fabrication technique is a superior approach for fabricating 3D, sealed, soft pneumatic actuators for micro, soft robot applications. [ABSTRACT FROM AUTHOR]

Published

2019

33. Edge-effect-mediated microfluidics for fabrication of microporous membrane with well-defined size and shape.

Author

Chengbao Jiang, Xiangming Li, Jinyou Shao, Hongmiao Tian, Xiangmeng Li, and Jihang Zhang

Subjects

ENVIRONMENTAL engineering, PREPOLYMERS, MICROFLUIDICS, BIOMEDICAL materials, MICROFABRICATION

Abstract

Microporous membranes of well-defined porous size, shape, and distribution are significantly important for environmental engineering and biomedical treatment applications, where high-throughput precise filtration is required. However, efficient manufacturing of desired microporous membranes remains a great challenge. In this study, an cost-effective method, based on edge-effect-mediated microfluidics, is proposed for the fabrication of polymeric microsieves with well-defined micropore arrays. This method refers to a lateral spreading of a liquid prepolymer between the protruding parts of a template and the flat surface of a substrate. The edge effect enables the liquid prepolymer to bypass, instead of filling the microholes of the template. Based on the proposed method, two types of monodisperse SiO2 microspheres were separated by solution filtration. [ABSTRACT FROM AUTHOR]

Published

2019

34. Monte Carlo simulation of chemistry following radiolysis with TOPAS-nBio.

Author

J Ramos-Méndez, J Perl, J Schuemann, A McNamara, H Paganetti, and B Faddegon

Subjects

RADIOLYSIS, IONIZING radiation, BIOMEDICAL materials

Abstract

Simulation of water radiolysis and the subsequent chemistry provides important information on the effect of ionizing radiation on biological material. The Geant4 Monte Carlo toolkit has added chemical processes via the Geant4-DNA project. The TOPAS tool simplifies the modeling of complex radiotherapy applications with Geant4 without requiring advanced computational skills, extending the pool of users. Thus, a new extension to TOPAS, TOPAS-nBio, is under development to facilitate the configuration of track-structure simulations as well as water radiolysis simulations with Geant4-DNA for radiobiological studies. In this work, radiolysis simulations were implemented in TOPAS-nBio. Users may now easily add chemical species and their reactions, and set parameters including branching ratios, dissociation schemes, diffusion coefficients, and reaction rates. In addition, parameters for the chemical stage were re-evaluated and updated from those used by default in Geant4-DNA to improve the accuracy of chemical yields. Simulation results of time-dependent and LET-dependent primary yields Gx (chemical species per 100 eV deposited) produced at neutral pH and 25 °C by short track-segments of charged particles were compared to published measurements. The LET range was 0.05–230 keV µm−1. The calculated Gx values for electrons satisfied the material balance equation within 0.3%, similar for protons albeit with long calculation time. A smaller geometry was used to speed up proton and alpha simulations, with an acceptable difference in the balance equation of 1.3%. Available experimental data of time-dependent G-values for agreed with simulated results within 7%  ±  8% over the entire time range; for over the full time range within 3%  ±  4%; for H2O2 from 49%  ±  7% at earliest stages and 3%  ±  12% at saturation. For the LET-dependent Gx, the mean ratios to the experimental data were 1.11  ±  0.98, 1.21  ±  1.11, 1.05  ±  0.52, 1.23  ±  0.59 and 1.49  ±  0.63 (1 standard deviation) for , , H2, H2O2 and , respectively. In conclusion, radiolysis and subsequent chemistry with Geant4-DNA has been successfully incorporated in TOPAS-nBio. Results are in reasonable agreement with published measured and simulated data. [ABSTRACT FROM AUTHOR]

Published

2018

35. Magnetically actuated and controlled colloidal sphere-pair swimmer.

Author

Sijie Ran, Allon Guez, and Gary Friedman

Subjects

MICROSCOPICAL technique, BIOMEDICAL materials, MAGNETIC fields, SWITCHING theory, COLLOIDAL networks, EQUIPMENT & supplies

Abstract

Magnetically actuated swimming of microscopic objects has been attracting attention partly due to its promising applications in the bio-medical field and partly due to interesting physics of swimming in general. While colloidal particles that are free to move in fluid can be an attractive swimming system due it its simplicity and ability to assemble in situ, stability of their dynamics and the possibility of stable swimming behavior in periodically varying magnetic fields has not been considered. Dynamic behavior of two magnetically interacting colloidal particles subjected to rotating magnetic field of switching frequency is analyzed here and is shown to result in stable swimming without any stabilizing feedback. A new mechanism of swimming that relies only on rotations of the particles themselves and of the particle pair axis is found to dominate the swimming dynamics of the colloidal particle pair. Simulation results and analytical arguments demonstrate that this swimming strategy compares favorably to dragging the particles with an external magnetic force when colloidal particle sizes are reduced. [ABSTRACT FROM AUTHOR]

Published

2016

36. Nonlinear response of ultrasound contrast agent microbubbles: From fundamentals to applications.

Author

Xu-Dong Teng, Xia-Sheng Guo, Juan Tu, and Dong Zhang

Subjects

BIOMEDICAL materials, MICROBUBBLES, FLOW cytometry, CAVITATION, CELL-mediated cytotoxicity

Abstract

Modelling and biomedical applications of ultrasound contrast agent (UCA) microbubbles have attracted a great deal of attention. In this review, we summarize a series of researches done in our group, including (i) the development of an all-in-one solution of characterizing coated bubble parameters based on the light scattering technique and flow cytometry; (ii) a novel bubble dynamic model that takes into consideration both nonlinear shell elasticity and viscosity to eliminate the dependences of bubble shell parameters on bubble size; (iii) the evaluation of UCA inertial cavitation threshold and its relationship with shell parameters; and (iv) the investigations of transfection efficiency and the reduction of cytotoxicity in gene delivery facilitated by UCAs excited by ultrasound exposures. [ABSTRACT FROM AUTHOR]

Published

2016

37. Can secondary nucleation exist in ice banding of freezing colloidal suspensions?

Author

Jia-Xue You, Jin-Cheng Wang, Li-Lin Wang, Zhi-Jun Wang, Jun-Jie Li, and Xin Lin

Subjects

NUCLEATION, COLLOIDAL suspensions, SUSPENSIONS (Chemistry), FROST heaving, FROZEN ground, BIOMEDICAL materials

Abstract

The formation mechanism of ice banding in the system of freezing colloidal suspensions, which is of significance in frost heaving, ice-templating porous materials and biological materials, is still a mystery. Recently, the theory of secondary nucleation and growth of ice has been proposed to explain the emergence of a new ice lens. However, this theory has not been quantitatively examined. Here, we quantitatively measure the initial interfacial undercooling of a new ice lens and the nucleation undercoolings of suspensions. We find that the interfacial undercooling cannot satisfy the nucleation undercooling of ice and hence disprove the secondary nucleation mechanism for ice banding. [ABSTRACT FROM AUTHOR]

Published

2016

38. Enhanced proliferation of PC12 neural cells on untreated, nanotextured glass coverslips.

Author

Muhymin Islam, Rahul Atmaramani, Siddhartha Mukherjee, Santaneel Ghosh, and Samir M Iqbal

Subjects

CENTRAL nervous system injuries, BRAIN injuries, BIOMEDICAL materials, GROWTH factors, NEUROBLASTOMA, THERAPEUTICS

Abstract

Traumatic injury to the central nervous system is a significant health problem. There is no effective treatment available partly because of the complexity of the system. Implementation of multifunctional micro- and nano-device based combinatorial therapeutics can provide biocompatible and tunable approaches to perform on-demand release of specific drugs. This can help the damaged cells to improve neuronal survival, regeneration of axons, and their reconnection to appropriate targets. Nano-topological features induced rapid cell growth is especially important towards the design of effective platforms to facilitate damaged neural circuit reconstruction. In this study, for the first time, feasibility of neuron-like PC12 cell growth on untreated and easy to prepare nanotextured surfaces has been carried out. The PC12 neuron-like cells were cultured on micro reactive ion etched nanotextured glass coverslips. The effect of nanotextured topology as physical cue for the growth of PC12 cells was observed exclusively, eliminating the possible influence(s) of the enhanced concentration of coated materials on the surface. The cell density was observed to increase by almost 200% on nanotextured coverslips compared to plain coverslips. The morphology study indicated that PC12 cell attachment and growth on the nanotextured substrates did not launch any apoptotic machinery of the cell. Less than 5% cells deformed and depicted condensed nuclei with apoptotic bodies on nanotextured surfaces which is typical for the normal cell handling and culture. Enhanced PC12 cell proliferation by such novel and easy to prepare substrates is not only attractive for neurite outgrowth and guidance, but may be used to increase the affinity of similar cancerous cells (ex: B35 neuroblastoma) and rapid proliferation thereafter—towards the development of combinatorial theranostics to diagnose and treat aggressive cancers like neuroblastoma. [ABSTRACT FROM AUTHOR]

Published

2016

39. pH-stimuli-responsive near-infrared optical imaging nanoprobe based on poly(γ-glutamic acid)/poly(β-amino ester) nanoparticles.

Author

Park, Hye Sun, Lee, Jung Eun, Cho, Mi Young, Noh, Young-Woock, Sung, Moon Hee, Poo, Haryoung, Hong, Kwan Soo, and Lim, Yong Taik

Subjects

POLYGLUTAMIC acid, NANOPARTICLES, INFRARED imaging, BIOMEDICAL materials, POLYMER research

Abstract

pH-stimuli-responsive near-infrared optical imaging nanoprobes are designed and synthesized in this study in a facile one-step synthesis process based on the use of the biocompatible and biodegradable polymer poly(γ-glutamic acid) (γ-PGA)/poly(β-amino ester) (PBAE). PBAE has good transfection efficiency and promotes degradation properties under acidic conditions. This pH-responsive degradability can be used for the effective release of encapsulating materials after cellular uptake. As an optical imaging probe, indocyanine green (ICG) is an FDA-approved near-infrared fluorescent dye with a quenching property at a high concentration. In this regard, we focus here on the rapid degradation of PBAE in an acidic environment, in which the nanoparticles are disassembled. This allows the ICG dyes to show enhanced fluorescence signals after being releasing from the particles. We demonstrated this principle in cellular uptake experiments. We expect that the developed pH-stimuli-responsive smart nanoprobes can be applied in intracellular delivery signaling applications. [ABSTRACT FROM AUTHOR]

Published

2016

40. High-yield fabrication of 60 nm Permalloy nanodiscs in well-defined magnetic vortex state for biomedical applications.

Author

M Goiriena-Goikoetxea, A García-Arribas, M Rouco, A V Svalov, and J M Barandiaran

Subjects

NANOFABRICATION, AGGLOMERATION (Materials), BIOMEDICAL materials, MAGNETOMECHANICAL effects, SPHEROMAKS, CANCER cells

Abstract

Permalloy disc structures in magnetic vortex state constitute a promising new type of magnetic nanoparticles for biomedical applications. They present high saturation magnetisation and lack of remanence, which ease the remote manipulation of the particles by magnetic fields and avoid the problem of agglomeration, respectively. Importantly, they are also endowed with the capability of low-frequency magneto-mechanical actuation. This effect has already been shown to produce cancer cell destruction using functionalized discs, about 1 μm in diameter, attached to the cell membrane. Here, Permalloy nanodiscs down to 60 nm in diameter are obtained by hole-mask colloidal lithography, which is proved to be a cost-effective method for the uniform patterning of large substrate areas, with a high production yield of nanostructures. The characterisation of the magnetic behaviour of the nanodiscs, complemented with micromagnetic simulations, confirms that they present a very well defined magnetic vortex configuration, unprecedented, to our knowledge, for nanostructures of this size prepared by a high-yield method. The successful detachment of the gold-covered nanodiscs from the substrate is also demonstrated by the use of sacrificial layers. [ABSTRACT FROM AUTHOR]

Published

2016

41. Isolation of circulating tumor cells by a magnesium-embedded filter.

Author

Yang Liu, Tong Xu, Yucheng Xu, Dongyang Kang, Lei Xu, Jungwook Park, Jay Han-Chieh Chang, Xiaoxiao Zhang, Amir Goldkorn, and Yu-Chong Tai

Subjects

CANCER cells, MAGNESIUM films, BIOMARKERS, PARYLENE, BIOMEDICAL materials, FINITE element method

Abstract

Circulating tumor cells (CTCs) are rare cancer cells that are shed by tumors into the bloodstream and that can be valuable biomarkers for various types of cancers. However, CTCs captured on the filter could not be released easily using the existing CTC analysis platforms based on size. To address this limitation, we have developed a novel magnesium (Mg)-embedded cell filter for capture, release and isolation of CTCs. The CTC-filter consists of a thin Ebeam-deposited Mg layer embedded between two parylene-C (PA-C) layers with designed slots for filtration and CTC capture. Thin Mg film has proved highly biocompatible and can be etched in saline, PBS and Dulbecco’s modified eagle medium (DMEM) etc, properties that are of great benefit to help dissociate the filter and thus release the cells. The finite element method (FEM) analysis was performed on the Mg etching process in DMEM for the structure design. After the filtration process, the filter was submerged in DMEM to facilitate Mg etching. The top PA-C filter pieces break apart from the bottom after Mg completely dissolves, enabling captured CTCs to detach. The released CTC can be easily aspirated into a micropipette for further analysis. Thus, the Mg-embedded cell filter provides a new and effective approach for CTCs isolation from the filter, making this a promising new strategy for cancer detection. [ABSTRACT FROM AUTHOR]

Published

2015

42. Heart beat detection in multimodal data using automatic relevant signal detection.

Author

Thomas De Cooman, Griet Goovaerts, Carolina Varon, Devy Widjaja, Tim Willemen, and Sabine Van Huffel

Subjects

ELECTROCARDIOGRAPHY, BIOMEDICAL materials, ELECTRODES, BLOOD pressure, ALGORITHMS

Abstract

Accurate R peak detection in the electrocardiogram (ECG) is a well-known and highly explored problem in biomedical signal processing. Although a lot of progress has been made in this area, current methods are still insufficient in the presence of extreme noise and/or artifacts such as loose electrodes. Often, however, not only the ECG is recorded, but multiple signals are simultaneously acquired from the patient. Several of these signals, such as blood pressure, can help to improve the heart beat detection. These signals of interest can be detected automatically by analyzing their power spectral density or by using the available signal type identifiers. Individual peaks from the signals of interest are combined using majority voting, heart beat location estimation and Hjorth’s mobility of the resulting RR intervals. Both multimodal algorithms showed significant increases in performance of up to 8.65% for noisy multimodal datasets compared to when only the ECG signal is used. A maximal performance of 90.02% was obtained on the hidden test set of the Physionet/Computing in Cardiology Challenge 2014: Robust Detection of Heart Beats in Multimodal Data. [ABSTRACT FROM AUTHOR]

Published

2015

43. Application of extremely non-equilibrium plasmas in the processing of nano and biomedical materials.

Author

Miran Mozetič, Gregor Primc, Alenka Vesel, Rok Zaplotnik, Martina Modic, Ita Junkar, Nina Recek, Marta Klanjšek-Gunde, Lukus Guhy, Mahendra K Sunkara, Maria C Assensio, Slobodan Milošević, Marian Lehocky, Vladimir Sedlarik, Marija Gorjanc, Kinga Kutasi, and Karin Stana-Kleinschek

Subjects

OXYGEN plasmas, BIOMEDICAL materials, NONEQUILIBRIUM plasmas, IONIZATION (Atomic physics), SURFACE morphology

Abstract

Some applications of extremely non-equilibrium oxygen plasma for tailoring the surface properties of organic as well as inorganic materials are presented. Plasma of low or moderate ionization fraction and very high dissociation fraction is created by high frequency electrodeless discharges created in chambers made from a material of low recombination coefficient. The O atom density often exceeds 1021 m−3 which allows for rapid functionalization of carbon-containing materials. Surface saturation with polar oxygen-rich groups is achieved in a fraction of a second and further exposure leads to etching. The etching is often non-uniform and results in nano-structuring of surface morphology. A combination of rich morphology and saturation with polar functional groups allows for a super-hydrophilic character of originally hydrophobic materials. Polymer composites are etched selectively so the polymer component is removed from the sample surface, leading to modified surface properties. Furthermore, such a treatment allows for distinguishing the distribution and orientation of fillers inside the polymer matrix. The exposure of inorganic materials to non-equilibrium oxygen plasma causes one-dimensional growth of metal oxide nanoparticles, thus representing a unique technique for the rapid catalyser-free growth of nanowires. [ABSTRACT FROM AUTHOR]

Published

2015

44. Construction of programmable interconnected 3D microfluidic networks.

Author

Marc P Wolf, Xueya Wang, Bei Zhang, Stephan Marsch, Patrick R Hunziker, and Georgette B Salieb-Beugelaar

Subjects

MICROFLUIDICS, POLYDIMETHYLSILOXANE, BIOMEDICAL materials, PHOTOLITHOGRAPHY, MICROFLUIDIC analytical techniques

Abstract

Microfluidic systems represent a key-enabling platform for novel diagnostic tools for use at the point-of-care in clinical contexts as well as for evolving single cell diagnostics. The design of 3D microfluidic systems is an active field of development, but construction of true interconnected 3D microfluidic networks is still a challenge, in particular when the goal is rapid prototyping, accurate design and flexibility. We report a novel approach for the construction of programmable 3D microfluidic systems consisting of modular 3D template casting of interconnected threads to allow user-programmable flow paths and examine its structural characteristics and its modular function. To overcome problems with thread template casting reported in the literature, low-surface-energy polymer threads were used, that allow solvent-free production. Connected circular channels with excellent roundness and low diameter variability were created. Variable channel termination allowed programming a flow path on-the-fly, thus rendering the resulting 3D microfluidic systems highly customizable even after production. Thus, construction of programmable/reprogrammable fully 3D microfluidic systems by template casting of a network of interconnecting threads is feasible, leads to high-quality and highly reproducible, complex 3D geometries. [ABSTRACT FROM AUTHOR]

Published

2015

45. LIF and fast imaging plasma jet characterization relevant for NTP biomedical applications.

Author

Riès, D, Dilecce, G, Robert, E, Ambrico, P F, Dozias, S, and Pouvesle, J-M

Subjects

LASER-induced fluorescence, PLASMA jets, BIOCOMPATIBILITY, HYDROXYL group, ELASTIC wave propagation, BIOMEDICAL materials

Abstract

In the field of biomedical application, many publications report on non-thermal plasma jet potentialities for cell behaviour modifications in cancer treatment, wound healing or sterilization. However most previous plasma jet characterizations were performed when jets expend freely in air. Only recently has the influence of the targeted surface been properly considered. In this work, modifications induced by various types of targets, mimicking the biological samples, in the plasma propagation and production of hydroxyl radicals are evidenced through time-resolved intensified charge-coupled device imaging and laser-induced fluorescence (LIF) measurements. A LIF model, also specifically dedicated to estimate air and water penetration inside the jet, is used and proves to be well adapted to characterize the plasma jet under biomedical application conditions. It is shown that the plasma produced by the plasma gun counter-propagates after impinging the surface which, for the same operating parameters, leads to an increase of almost one order of magnitude in the maximum OH density (from ∼2 × 1013 cm−3 for open-air propagation to ∼1 × 1014 cm−3 for a grounded metal target). The nature of the target, especially its electrical conductivity, as well as gas flow rate and voltage amplitude are playing a key role in the production of hydroxyl radicals. The strong interplay between gas flow dynamics and plasma propagation is here confirmed by air and water distribution measurements. The need for a multi-diagnostic approach, as well as great care in setting up the in situ characterization of plasma jets, is here emphasized. Special attention must not only be paid to voltage amplitude and gas flow rate but also to the nature, humidity and conductivity of the target. [ABSTRACT FROM AUTHOR]

Published

2014

46. Facile synthesis and characterization of highly fluorescent and biocompatible N-acetyl-l-cysteine capped CdTe/CdS/ZnS core/shell/shell quantum dots in aqueous phase.

Author

Xiao, Qi, Huang, Shan, Su, Wei, Chan, W. H., and Liu, Yi

Subjects

CADMIUM telluride, CADMIUM sulfide, ZINC sulfide, QUANTUM dots, BIOMEDICAL materials

Abstract

The synthesis of water-soluble quantum dots (QDs) in aqueous phase has received much attention recently. To date various kinds of QDs such as CdTe, CdSe, CdTe/CdS and CdSe/ZnS have been synthesized by aqueous methods. However, generally poor-quality QDs (photoluminescent quantum yield (PLQY) lower than 30%) are obtained via this method and the 3-mercaptopropionic acid stabilizer is notorious for its toxicity and awful odor. Here we introduce a novel thiol ligand, N-acetyl-l-cysteine, as an ideal stabilizer that is successfully employed to synthesize high-quality CdTe/CdS/ZnS QDs via a simple aqueous phase. The core/shell/shell structures of the CdTe/CdS/ZnS QDs were verified by x-ray photoelectron spectroscopy, energy dispersive x-ray spectroscopy, x-ray powder diffraction and transmission electron microscopy. These QDs not only possess a high PLQY but also have excellent photostability and favorable biocompatibility, which is vital for many biological applications. This type of water-dispersed QD is a promising candidate for fluorescent probes in biological and medical fields. [ABSTRACT FROM AUTHOR]

Published

2012

47. Nanoscale tipped microwire arrays enhance electrical trap and depth injection of nanoparticles.

Author

Goryu, Akihiro, Numano, Rika, Ikedo, Akihito, Ishida, Makoto, and Kawano, Takeshi

Subjects

NANOWIRES, NANOMEDICINE, NANOELECTROMECHANICAL systems, METAL coating, BIOMEDICAL materials

Abstract

Nanoscale devices have the potential to measure biological tissues as well as individual cells/neurons. However, three-dimensional (3D) multi-site probing remains problematic because only planar-type device designs are applicable to sample surfaces. Herein we report 3D nanoscale electrode tipped microwire arrays with high aspect ratios. A nanoscale tipped wire is formed by isotropic silicon etching to the tip of a vapor–liquid–solid grown silicon microwire. After coating the wire with a metal (e.g., Pt and Au), only the nanotip section can be exposed from the surrounding outer shell (e.g., SiO2 and parylene) by photoresist spray coating and subsequent cycled photoresist etchings. As a promising device application, we demonstrate the trapping of polystyrene nanoparticles in a solution using a fabricated Au-nanotip wire array. The sharpened nanotip has a 150 nm curvature radius and a 4.2 μm2 electrode area. The nanotip wires exhibit a locally enhanced trapping performance with a low trapping voltage of 20 mV. Moreover, these trapped nanoparticles can be injected into a soft material (gelatin), demonstrating a multi-site wide-area batch depth injection and an assembly of nanoparticles. Such nanotip wire arrays should be applicable to trap numerous particles, including DNA/molecules attached to Au particles, and may realize injection into biological tissues and individual cells/neurons. [ABSTRACT FROM AUTHOR]

Published

2012

48. Graphene nanocomposite for biomedical applications: fabrication, antimicrobial and cytotoxic investigations.

Author

Santos, Catherine M., Mangadlao, Joey, Ahmed, Farid, Leon, Alex, Advincula, Rigoberto C., and Rodrigues, Debora F.

Subjects

GRAPHENE, NANOCOMPOSITE materials, BIOMEDICAL materials, ANTI-infective agents, CELL-mediated cytotoxicity, BIOCOMPATIBILITY

Abstract

Materials possessing excellent bacterial toxicity, while presenting low cytotoxicity to human cells, are strong candidates for biomaterials applications. In this study, we present the fabrication of a nanocomposite containing poly(N-vinylcarbazole) (PVK) and graphene (G) in solutions and thin films. Highly dispersed PVK–G (97-3 w/w%) solutions in various organic and aqueous solvents were prepared by solution mixing and sonication methods. The thermal properties and morphology of the new composite were analyzed using thermal gravimetry analysis (TGA) and atomic force microscopy (AFM), respectively. PVK–G films were immobilized onto indium tin oxide (ITO) substrates via electrodeposition. AFM was used to characterize the resulting topography of the nanocomposite thin films, while cyclic voltammetry and UV–vis were used to monitor their successful electrodeposition. The antimicrobial properties of the electrodeposited PVK–G films and solution-based PVK–G were investigated against Escherichia coli (E. coli) and Bacillus subtilis (B. subtilis). Microbial growth after exposure to the nanocomposite, metabolic assay and live–dead assay of the bacterial solutions exposed to PVK–G presented fewer viable and active bacteria than those exposed to pure PVK or pure graphene solutions. The PVK–G film inhibited about 80% of biofilm surface coverage whereas the PVK- and G-modified surfaces allowed biofilm formation over almost the whole coated surface (i.e. > 80%). The biocompatibility of the prepared PVK–G solutions on NIH 3T3 cells was evaluated using the MTS cell proliferation assay. A 24 h exposure of the PVK–G nanocomposite to the NIH 3T3 cells presented ∼80% cell survival. [ABSTRACT FROM AUTHOR]

Published

2012

49. Design of double-walled carbon nanotubes for biomedical applications.

Author

Neves, V., Heister, E., Costa, S., Tîlmaciu, C., Flahaut, E., Soula, B., Coley, H. M., McFadden, J., and Silva, S. R. P.

Subjects

DOUBLE walled carbon nanotubes, BIOMEDICAL materials, CHEMICAL vapor deposition, SMALL interfering RNA, MEDICAL research, DRUG development, CANCER cells

Abstract

Double-walled carbon nanotubes (DWNTs) prepared by catalytic chemical vapour deposition were functionalized in such a way that they were optimally designed as a nano-vector for the delivery of small interfering RNA (siRNA), which is of great interest for biomedical research and drug development. DWNTs were initially oxidized and coated with a polypeptide (Poly(Lys:Phe)), which was then conjugated to thiol-modified siRNA using a heterobifunctional cross-linker. The obtained oxDWNT–siRNA was characterized by Raman spectroscopy inside and outside a biological environment (mammalian cells). Uptake of the custom-designed nanotubes was not associated with detectable biochemical perturbations in cultured cells, but transfection of cells with DWNTs loaded with siRNA targeting the green fluorescent protein (GFP) gene, serving as a model system, as well as with therapeutic siRNA targeting the survivin gene, led to a significant gene silencing effect, and in the latter case a resulting apoptotic effect in cancer cells. [ABSTRACT FROM AUTHOR]

Published

2012

50. Rapid microwave-assisted synthesis of dextran-coated iron oxide nanoparticles for magnetic resonance imaging.

Author

Atkins, Tonya M., Kauzlarich, Susan M., Osborne, Elizabeth A., Louie, Angelique Y., Gilbert, Dustin A., and Liu, Kai

Subjects

IRON oxide nanoparticles, MAGNETIC resonance imaging, CONTRAST media, BIOMEDICAL materials, SUPERPARAMAGNETIC materials, DEXTRAN

Abstract

Currently, magnetic iron oxide nanoparticles are the only nanosized magnetic resonance imaging (MRI) contrast agents approved for clinical use, yet commercial manufacturing of these agents has been limited or discontinued. Though there is still widespread demand for these particles both for clinical use and research, they are difficult to obtain commercially, and complicated syntheses make in-house preparation unfeasible for most biological research labs or clinics. To make commercial production viable and increase accessibility of these products, it is crucial to develop simple, rapid and reproducible preparations of biocompatible iron oxide nanoparticles. Here, we report a rapid, straightforward microwave-assisted synthesis of superparamagnetic dextran-coated iron oxide nanoparticles. The nanoparticles were produced in two hydrodynamic sizes with differing core morphologies by varying the synthetic method as either a two-step or single-step process. A striking benefit of these methods is the ability to obtain swift and consistent results without the necessity for air-, pH- or temperature-sensitive techniques; therefore, reaction times and complex manufacturing processes are greatly reduced as compared to conventional synthetic methods. This is a great benefit for cost-effective translation to commercial production. The nanoparticles are found to be superparamagnetic and exhibit properties consistent for use in MRI. In addition, the dextran coating imparts the water solubility and biocompatibility necessary for in vivo utilization. [ABSTRACT FROM AUTHOR]

Published

2012