Your search keyword '"Optical Tweezers"' showing total 19,328 results

151. Optofluidic-based cell multi-axis controllable rotation and 3D surface imaging.

Author

Mao, Yuxin, Li, Songlin, Wang, Zixin, Shao, Meng, Wang, Peng, Tan, Xinyuan, Lu, Fengya, Wang, Yi, Wei, Xunbin, Zhong, Zhensheng, and Zhou, Jinhua

Subjects

*THREE-dimensional imaging, *ROTATIONAL motion, *ERYTHROCYTES, *OPTICAL tweezers, *CELL analysis

Abstract

The controlled rotation of individual cells plays a crucial role in enabling three-dimensional multi-angle observation of cellular structure, function, and dynamic processes. Reported cell rotation techniques often struggle to strike a balance between high precision and simple control, and they exhibit limited control flexibility, typically achieving only uniaxial cell rotation. In this study, we propose a cell rotation technique in three dimensions based on optofluidics, which utilizes optical tweezers to immobilize the cell and exploits the asymmetry of the surrounding flow to drive cell rotation. By adjusting the focal position of the optical tweezers, cells can be positioned within various flow profiles, enabling control of the rotation speed, rotation direction, and rotation axis of cells. This approach simplifies the manipulation procedure, achieving desirable control precision and greater rotation flexibility. Using our approach, multi-angle surface imaging projections of target cells can be rapidly obtained, followed by capturing the cell contour data from the images. By combining the cell contour data with corresponding angular position information, we have reconstructed the 3D surface of the target cell. We have employed this technique in experiments for the analysis of red blood cell morphology. Based on the constructed 3D surface images of diverse-shaped red blood cells, we quantified structural parameters including cell surface area, volume, sphericity, and surface roughness, which demonstrates the potential application of this cell rotation technique for cellular morphological analysis. [ABSTRACT FROM AUTHOR]

Published

2023

152. Optically Programmable Living Microrouter in Vivo.

Author

Liu, Xiaoshuai, Wu, Huaying, Wu, Shuai, Qin, Haifeng, Zhang, Tiange, Lin, Yufeng, Zheng, Xianchuang, and Li, Baojun

Subjects

*LEUCOCYTES, *OPTICAL tweezers, *BLOOD cells, *BIOLOGICAL transport, *CELL separation, *INSECT societies

Abstract

With high reconfigurability and swarming intelligence, programmable medical micromachines (PMMs) represent a revolution in microrobots for executing complex coordinated tasks, especially for dynamic routing of various targets along their respective routes. However, it is difficult to achieve a biocompatible implantation into the body due to their exogenous building blocks. Herein, a living microrouter based on an organic integration of endogenous red blood cells (RBCs), programmable scanning optical tweezers and flexible optofluidic strategy is reported. By harvesting energy from a designed optical force landscape, five RBCs are optically rotated in a controlled velocity and direction, under which, a specific actuation flow is achieved to exert the well‐defined hydrodynamic forces on various biological targets, thus enabling a selective routing by integrating three successive functions, i.e., dynamic input, inner processing, and controlled output. Benefited from the optofluidic manipulation, various blood cells, such as the platelets and white blood cells, are transported toward the damaged vessel and cell debris for the dynamic hemostasis and targeted clearance, respectively. Moreover, the microrouter enables a precise transport of nanodrugs for active and targeted delivery in a large quantity. The proposed RBC microrouter might provide a biocompatible medical platform for cell separation, drug delivery, and immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2023

153. Technical note: Characterization of a single-beam gradient force aerosol optical tweezer for droplet trapping, phase transitions monitoring, and morphology studies.

Author

Pei, Xiangyu, Meng, Yikan, Chen, Yueling, Liu, Huichao, Song, Yao, Xu, Zhengning, Zhang, Fei, Preston, Thomas C., and Wang, Zhibin

Subjects

PHASE transitions, OPTICAL tweezers, WHISPERING gallery modes, AEROSOLS, MIE scattering, LIGHT scattering, ESSENTIAL oils, TROPOSPHERIC aerosols

Abstract

Single particle analysis is essential for a better understanding of the particle transformation process and predicting its environmental impact. In this study, we developed an aerosol optical tweezer (AOT)-Raman spectroscopy system to investigate the phase state and morphology of suspended aerosol droplets in real time. The system comprises four modules: optical trapping, reaction, illumination and imaging, as well as detection. The optical trapping module utilizes a 532 nm laser and a 100x oil immersion objective to stably trap aerosol droplets within 30 seconds. The reaction module allows us to adjust relative humidity (RH) and introduce reaction gases into the droplet levitation chamber, facilitating experiments to study liquid-liquid phase transitions. The illumination and imaging module employs a high-speed camera to monitor the trapped droplets, while the detector module records Raman scattering light. We trapped sodium chloride (NaCl) and 3-methyl glutaric acid (3-MGA) mixed droplets to examine RH-dependent morphology changes. Liquid-liquid phase separation (LLPS) occurred when RH was decreased. Additionally, we introduced ozone and limonene/α-pinene to generate secondary organic aerosol (SOA) particles in situ, which collided with the trapped droplet and dissolve in it. To determine the trapped droplet's characteristics, we utilized an open-source program which based on Mie theory to retrieve diameter and refractive index from the observed whispering gallery modes (WGMs) in Raman spectra. It is found that mixed droplets formed core-shell morphology when RH was decreased, and the RH dependence of the droplets phase transitions generated by different SOA precursors varied. Our AOT system serves as an essential experimental platform for in-situ assessment of morphology and phase state during dynamic atmospheric processes. [ABSTRACT FROM AUTHOR]

Published

2023

154. Temperature Measurement of Trapped, Thermally Sensitive Single Particles in an Optical Trap Using Raman Spectroscopy.

Author

Ai, Yukai, Pan, Yong-Le, Videen, Gorden, and Wang, Chuji

Subjects

*RAMAN spectroscopy, *TEMPERATURE measurements, *OPTICAL tweezers, *TEMPERATURE distribution, *THERMAL conductivity, *ELECTRON traps, *LASER beams, *CARBON nanotubes

Abstract

Single particles trapped in an optical trap may experience temperature elevation, yet direct measurement of temperature and its distribution inside the optical trap of several to hundreds of microns in size remains a big challenge. We introduce a method that can measure the temperature inside a universal optical trap (UOT) using Raman spectroscopy of single trapped particles of high thermal conductivity. We measured temperature and temperature distributions inside the UOT using Raman shifts of single-walled carbon nanotubes (SWCNTs) and micron-sized diamonds (MSDs), which are heated by trapping laser beams directly or indirectly, depending on the location of the particle in the trap. We show that the temperature at the center of the UOT is much lower than the temperature along the hollow beams that form a hollow, cage-shaped UOT. In the range of the trapping laser power of 200–2950 mW, the surface temperature of particles trapped at the center of a UOT changes from 322 K to 830 K, correspondingly. This result gives a heating rate as a high thermal-absorbing particle trapped in the center of the UOT with 18.3 ± 0.4 °C/100 mW. In addition, the temperature gradient outside the UOT was also characterized by trapping SWCNT particles outside the UOT. Results show that when a light-absorbing particle is trapped for the study of material property, phase transitions, surface equilibrium process, chemical reactions, etc., this method can be used to measure temperature distribution and its variations in the trap and its surroundings. Graphical Abstract This is a visual representation of the abstract. [ABSTRACT FROM AUTHOR]

Published

2023

155. Pressure Pulsatility Links Cardio-Respiratory and Brain Rhythmicity.

Author

Hamill, Owen P.

Subjects

*ATOMIC force microscopy, *INTRACRANIAL pressure, *OPTICAL tweezers, *PHASE oscillations, *MICROSCOPY

Abstract

This article presents evidence indicating that intracranial pressure (ICP) pulsatility, associated with the heartbeat and breathing, is not just a source of mechanical artefact in electrical recordings, but is "sensed" and plays a role in the brain's information processing. Patch-clamp recording of pressure-activated channels, and detection of Piezo2-protein channel expression in brain neurons, suggest that these channels provide neurons with an intrinsic resonance to ICP pulsatility, which acts to synchronize remote neural networks. Direct measurements in human patients indicate that heartbeat and breathing rhythms generate intracranial forces of tens of millinewtons, exceeding by orders of magnitude the localized forces shown by atomic force microscopy and optical tweezers to activate Piezo channels in isolated neocortical and hippocampal neurons. Additionally, many human touch and proprioceptors, which are also transduced by Piezo channels, show spiking that is phase-locked to heartbeat- and breathing-induced extracranial pressure pulsations. Finally, based on the observation that low-frequency oscillations modulate the phase and amplitude of high-frequency oscillations, body and brain oscillations are proposed to form a single hierarchical system in which the heartbeat is the basic frequency and scaling factor for all other oscillations. Together, these results support the idea that ICP pulsatility may be elemental in modulating the brain's electrical rhythmicity. [ABSTRACT FROM AUTHOR]

Published

2023

156. Optical Forces on Multipoles Induced by the Belinfante Spin Momentum.

Author

Zhou, Yuan, Zhang, Yanan, Xu, Xiaohao, Nieto‐Vesperinas, Manuel, Yan, Shaohui, Li, Manman, Gao, Wenyu, Zhang, Yao, and Yao, Baoli

Subjects

*ELECTROMAGNETIC fields, *OPTOMECHANICS, *OPTICAL tweezers, *MIE scattering, *SPIN-orbit interactions

Abstract

The Belinfante spin momentum (BSM) is a fundamental yet enigmatic quantity of electromagnetic fields. It vanishes from the global momentum of the field, but can be detected locally, manifesting itself as an optical force on small particles. Hitherto, however, the BSM force is a concept well established only within the dipole approximation, and there is no explicit experimental evidence for its action on multipoles. Here, a theoretical model for multipolar BSM forces, exerted on generic Mie particles supporting multipoles of arbitrary order, is developed. This multipolar mechanical action is observed experimentally from a structured light field, which suppresses the effect of spin–orbit coupling. It can also selectively enhance the multipolar BSM forces, while restraining the dipolar component on a probe particle (Au sphere). These results constitute a distinct chapter in the physics of high‐order interactions in light–matter systems and can facilitate additional progress in optomechanics, optical manipulation, and Mie‐tronics. [ABSTRACT FROM AUTHOR]

Published

2023

157. Acoustic driven circulation around cylindrical obstructions in microchannels.

Author

Miah, Md. Abdul Karim, Zeller, Peter, Olsen, Michael G., and Juárez, Jaime J.

Subjects

*PARTICLE image velocimetry, *DEGREES of freedom, *HIGH voltages, *PIEZOELECTRIC transducers, *CHANNEL flow, *MICROCHANNEL flow, *OPTICAL tweezers

Abstract

We introduce an approach to generate direction-controlled circulation around cylindrical obstructions in channels using a piezoelectric transducer embedded porous-channel device fabricated by photolithography. To transmit acoustic signals into the channel, a single piezoelectric transducer was attached, operating at voltage levels of 5, 10, 15, and 20 V. Microscopic particle image velocimetry was employed to analyze the flow patterns in the channels. The analysis revealed two opposing circulation tendencies around the pillars located at two opposite sides of the channel in the longitudinal direction. The strength of circulation was found to be minimal in the middle of the channel and increased gradually toward the two ends of the channels. Furthermore, we observed that the circulation strength was maximum near the axial centerline and minimum at the boundaries along the width of the channels. Comparing the voltage levels, the higher voltage signals produced a higher strength of circulation than the lower voltage signals in all cases. Additionally, we found that the strength of circulation increased almost linearly and then decayed exponentially in the radial direction from the surfaces of the pillars. The observed velocity fields around individual cylinders matched well with the Görtler vortex model. The reported circulation phenomenon around pillars can be applied in non-contact fluid stirring and mixing in bio-chemical systems and lab-on-a-chip systems and may also provide additional degrees of freedom in object tweezing, trapping, and levitation. [ABSTRACT FROM AUTHOR]

Published

2023

158. Single particle investigation of triolein digestion using optical manipulation, polarized video microscopy, and SAXS.

Author

Manca, Marco, Zhang, Chi, Vasconcelos de Melo Freire, Rafael, Scheffold, Frank, and Salentinig, Stefan

Subjects

*VIDEO microscopy, *FOOD emulsions, *LIPASES, *SMALL-angle X-ray scattering, *OPTICAL tweezers, *MICROSCOPY, *DIGESTION

Abstract

Hypothesis: Understanding how soft colloids, such as food emulsion droplets, transform based on their environment is critical for various applications, including drug and nutrient delivery and biotechnology. However, the mechanisms behind colloidal transformations within individual oil droplets still need to be better understood. Experiments: This study employs optical micromanipulation with microfluidics and polarized optical video microscopy to investigate the pancreatic lipase- and pH-triggered colloidal transformations in a single triolein droplet. Small-angle X-ray scattering (SAXS) provides complementary statistical insights and allows for detailed structural assignment. Findings: Optical video microscopy recorded the transformation of individual triolein emulsion droplets, with the smooth surface of these spherical particles becoming rough and the entire volume eventually being affected. The polarized microscopy revealed the coexistence of at least two distinct structures in a single particle during digestion, with their ratio and distribution altered by pH. The SAXS analysis assigned the optical anisotropy to emulsified inverse hexagonal- and multilamellar phases, coexisting with isotropic structures such as the micellar cubic phase. These results can help understand the phase transformations inside an emulsion droplet during triglyceride digestion and guide the design of advanced food emulsions. When pancreatic lipase is added to a triolein emulsion, it adsorbs at the oil/water interface and hydrolyses the triolein ester bonds. The final products are monoolein and oleic acid. These molecules are surface active and self-assemble with water inside the digesting emulsion droplet into various structures based on the composition and the pH. Polarized video microscopy monitors the self-assembly process and the presence of anisotropic liquid crystalline structures in a single oil droplet. A custom-built holographic optical tweezers setup monitors individual droplets' structural response to the pH, and small-angle X-ray scattering links the optical information to distinct nanostructures. [ABSTRACT FROM AUTHOR]

Published

2023

159. Fluctuation-mediated orbital rotation of microparticles in non-coaxially counter-propagating optical tweezers.

Author

Setoura, Kenji, kakimoto, Takayasu, Miyasaka, Hiroshi, and Ito, Syoji

Subjects

*OPTICAL tweezers, *BROWNIAN motion, *LASER beams, *ROTATIONAL motion, *SYMMETRY breaking, *WATER temperature

Abstract

We have demonstrated in the present report that dielectric microparticles exhibited orbital rotation in the light field of non-coaxially configured two counter-propagating laser beams both in numerical simulations and experiments. A series of computational simulations indicated that when irradiated with two non-coaxially counter-propagating parallel laser beams with the same intensity distributions in the absence of thermal (Brownian) motion, a microparticle did not exhibit orbital rotation due to the symmetry of the optical field. However, the computations predicted that a microparticle exhibited one directional orbital rotation in the presence of thermal motion because of the symmetry breaking of the optical force acting on the particle. This spontaneous orbital rotation was experimentally demonstrated for 1-µm dielectric particles in water at room temperature. [ABSTRACT FROM AUTHOR]

Published

2023

160. Special Issue on Light Control and Particle Manipulation: An Overview.

Author

Shen, Zhe

Subjects

OPTICAL tweezers, OPTICAL materials, PHOTONICS, BUSHINGS, LIGHT, PHYSICS

Abstract

This document is a summary of a special issue of the journal Photonics titled "Light Control and Particle Manipulation: An Overview." The issue focuses on the use of optical tweezers and structured light in various fields such as chemistry, biomedicine, and physics. The articles in the issue cover topics such as the interaction between light and particles, techniques for optical trapping, the generation and manipulation of structured light, and the use of structured materials in optical manipulation. The document highlights the importance of these research areas and their potential for future advancements. [Extracted from the article]

Published

2023

161. Two-Photon Laser Excitation of Rb Rydberg Atoms in the Magneto-Optical Trap and Vapor Cell.

Author

Tretyakov, Denis B., Entin, Vasily M., Beterov, Ilya I., Yakshina, Elena A., Pechersky, Yury Ya., Gol'dort, Veniamin G., and Ryabtsev, Igor I.

Subjects

RYDBERG states, ATOM trapping, LASERS, QUANTUM information science, VAPORS, OPTICAL tweezers, ATOMIC clocks

Abstract

We present our experimental results of two-photon laser excitation 5S1/2→5P3/2→nS1/2 of Rb atoms to Rydberg nS1/2 states with a homemade 480 nm laser in the second excitation step. In an experiment with cold Rb atoms, we excited the 42S1/2 state and detected Rydberg atoms with a selective-field-ionization (SFI) detector that provides single-atom resolution. The resonance line shapes well agreed with numerical simulations in a three-level theoretical model. We also studied the multiatom spectra of Rydberg excitation of mesoscopic atom ensembles which are of interest to quantum information processing. In the experiment with hot Rb atoms, we first excited the 30S1/2 state and observed a narrow Rydberg EIT resonance. Its line shape also agreed well with theory. Then, we performed a similar experiment with the higher 41S1/2 state and observed the Autler–Townes splitting of the EIT resonance in the presence of a microwave field, which was in resonance with the microwave transition 41S→41P3/2. This allowed us to measure the average strength of the microwave field and, thus, demonstrate the operation of a Rydberg microwave sensor. We may conclude that the developed homemade laser at 480 nm substantially extends our capabilities for further experiments on quantum information and quantum sensing with Rydberg atoms. [ABSTRACT FROM AUTHOR]

Published

2023

162. The Histone Chaperones SET/TAF-1β and NPM1 Exhibit Conserved Functionality in Nucleosome Remodeling and Histone Eviction in a Cytochrome c-Dependent Manner.

Author

Buzón, Pedro, Velázquez-Cruz, Alejandro, Corrales-Guerrero, Laura, Díaz-Quintana, Antonio, Díaz-Moreno, Irene, and Roos, Wouter H.

Subjects

*NUCLEIC acid hybridization, *HISTONES, *EVICTION, *MOLECULAR chaperones, *BASE pairs, *GENE expression, *CONFOCAL fluorescence microscopy

Abstract

Chromatin homeostasis mediates essential processes in eukaryotes, where histone chaperones have emerged as major regulatory factors during DNA replication, repair, and transcription. The dynamic nature of these processes, however, has severely impeded their characterization at the molecular level. Here, fluorescence optical tweezers are applied to follow histone chaperone dynamics in real time. The molecular action of SET/template-activating factor-l/β and nucleophosmin 1-representing the two most common histone chaperone folds-are examined using both nucleosomes and isolated histones. It is shown that these chaperones present binding specificity for fully dismantled nucleosomes and are able to recognize and disrupt non-native histone-DNA interactions. Furthermore, the histone eviction process and its modulation by cytochrome c are scrutinized. This approach shows that despite the different structures of these chaperones, they present conserved modes of action mediating nucleosome remodeling. [ABSTRACT FROM AUTHOR]

Published

2023

163. Creating tunable lateral optical forces through multipolar interplay in single nanowires.

Author

Nan, Fan, Rodríguez-Fortuño, Francisco J., Yan, Shaohui, Kingsley-Smith, Jack J., Ng, Jack, Yao, Baoli, Yan, Zijie, and Xu, Xiaohao

Subjects

LATERAL loads, OPTICAL tweezers, NANOWIRES, PLANE wavefronts, LINEAR polarization, NANOPARTICLES, HOLOGRAPHIC gratings

Abstract

The concept of lateral optical force (LOF) is of general interest in optical manipulation as it releases the constraint of intensity gradient in tightly focused light, yet such a force is normally limited to exotic materials and/or complex light fields. Here, we report a general and controllable LOF in a nonchiral elongated nanoparticle illuminated by an obliquely incident plane wave. Through computational analysis, we reveal that the sign and magnitude of LOF can be tuned by multiple parameters of the particle (aspect ratio, material) and light (incident angle, direction of linear polarization, wavelength). The underlying physics is attributed to the multipolar interplay in the particle, leading to a reduction in symmetry. Direct experimental evidence of switchable LOF is captured by polarization-angle-controlled manipulation of single Ag nanowires using holographic optical tweezers. This work provides a minimalist paradigm to achieve interface-free LOF for optomechanical applications, such as optical sorting and light-driven micro/nanomotors. It is a significant challenge to create an interface-free lateral optical force under the illumination of a single polarized plane wave. Here, the authors provide a minimalist paradigm to address this challenge by exploiting multipolar interplay in a single elongated particle. [ABSTRACT FROM AUTHOR]

Published

2023

164. Colloidal Manipulation through Plasmonic and Non‐plasmonic Laser‐Assisted Heating.

Author

K, Monisha, K, Suresh, and George, Sajan D.

Subjects

*MATERIALS science, *MARANGONI effect, *LIFE sciences, *PHOTOTHERMAL effect, *LIGHT sources, *OPTICAL tweezers, *MICROFLUIDICS, *NANOFLUIDICS

Abstract

In spite of the long‐term awareness of the conversion of light to heat even in materials with low absorption coefficient via the photothermal effect and consequent usage of the effect to evaluate thermo‐optic properties of the materials, only recently has the thermal field created via photon‐to‐phonon conversion been exploited for manipulation of colloidal objects as well as living cells. As compared to conventional direct photon‐assisted manipulation via optical tweezers, the optothermal manipulation technique employs much lower optical source power and can manipulate particles over a long range. In this review, the working mechanisms, concepts, and applications of a series of recently established optothermal techniques are discussed for the manipulation of diverse species including micro/nanoparticles, biological cells, molecules, and micelles in various fluidic environments. The physical mechanism of the optical manipulation that relies on the coordinated action of thermal convection, Marangoni convection, thermophoresis, thermoelectricity, depletion attraction, and thermo‐osmotic flow is discussed in detail. With their low‐power operation, diverse functionalities, and simple optics employed, optothermal manipulation techniques are increasingly finding a wide range of applications in colloidal science, life sciences, materials science, and nanoscience, as well as in the developments of colloidal functional devices and nanomedicine. [ABSTRACT FROM AUTHOR]

Published

2023

165. Anomalous Lateral Optical Force as a Manifestation of the Optical Transverse Spin.

Author

Yu, Xinning, Li, Yaxin, Xu, Bijun, Wang, Xiaogang, Zhang, Lei, Chen, Jun, Lin, Zhifang, and Chan, Che Ting

Subjects

*LATERAL loads, *SPIN Hall effect, *GEOMETRIC quantum phases

Abstract

Interacting with an evanescent wave, an achiral particle can experience a lateral optical force (LOF) in a direction which is perpendicular to that of the illuminating photon momentum while the system apparently has the left–right symmetry. Here, using the Cartesian multipole expansion theory, a general relationship between LOF and spin and momentum is established. Most importantly, it is demonstrated that an anomalous LOF exerted on an isotropic achiral particle of arbitrary size and composition is proportional to the optical transverse spin in the incident evanescent wave that carries pure transverse spin associated with spin‐momentum locking. Manifesting itself as a mechanical consequence of the Berry phase effect, this anomalous LOF suggests a direct detectability of the transverse spin of light, as well as mimicking the transverse shift of light in the spin Hall effect of photons. [ABSTRACT FROM AUTHOR]

Published

2023

166. Manipulating Laser Modes in Diffusive Disordered Systems by Precisely Designing the Boundary of the Local Pump.

Author

Shi, Xiaoyu, Song, Wanting, Liang, Ningning, Guo, Dan, Shen, Kaiyue, and Zhai, Tianrui

Subjects

*LASERS, *CONTINUOUS distributions, *SQUARE root, *OPTICAL tweezers

Abstract

Manipulating laser modes in diffusive random systems is crucial to understanding the optical physics of disordered structures. However, the laser modes in diffusive random lasers are highly extended and correlated, making their manipulation difficult. Herein, this work reveals the critical role of the pump boundary on the governing mode interaction and emission characteristics of diffusive random lasers (RLs). By increasing the ratio between the square root of the pump area and the circumference of the pump region, the strongly correlated nonresonant laser mode with a continuous spectral distribution is transformed into an independent resonant laser mode with a discrete frequency distribution. A critical ratio of 5.76 is demonstrated as the transition point for pump spots with arbitrary shapes. This pump strategy provides a universal guideline for regulating laser modes in diffusive RL systems that can be applied to multifunctional lasers to clarify the behavior of light in disordered structures. [ABSTRACT FROM AUTHOR]

Published

2023

167. Fast backward steps and detachment of single kinesin molecules measured under a wide range of loads.

Author

Kondo, Yuichi, Sasaki, Kazuo, and Higuchi, Hideo

Subjects

*SINGLE molecules, *OPTICAL tweezers, *MOLECULAR motor proteins

Abstract

To understand force generation under a wide range of loads, the stepping of single kinesin molecules was measured at loads from −20 to 42 pN by optical tweezers with high temporal resolution. The optical trap has been improved to halve positional noise and increase bandwidth by using 200‐nm beads. The step size of the forward and backward steps was 8.2 nm even over a wide range of loads. Histograms of the dwell times of backward steps and detachment fit well to two independent exponential equations with fast (~0.4 ms) and slow (>3 ms) time constants, indicating the existence of a fast step in addition to the conventional slow step. The dwell times of the fast steps were almost independent of the load and ATP concentration, while those of the slow backward steps and detachment depended on those. We constructed the kinetic model to explain the fast and slow steps under a wide range of loads. [ABSTRACT FROM AUTHOR]

Published

2023

168. Self-organized multi-target trapping of swarm robots with density-based interaction.

Author

Lei, Xiaokang, Zhang, Shuai, Xiang, Yalun, and Duan, Mengyuan

Subjects

ROBOTS, ANODIC oxidation of metals, DENSITY, OPTICAL tweezers, COMPUTER simulation

Abstract

The task of multi-target trapping in swarm robots can often be solved by global shape planning and target assignment, but it still remains a challenge to achieve fully self-organized multi-target trapping behavior based on local information. In this paper, inspired by the concept of spatial density in physics and biology, we proposed a novel density-based method to enable the swarm robots to entrap multiple targets with either single-ring, multi-ring or multi-subgroup formation in a distributed and self-organized way while neither communication among robots nor encirclement function is required. Each robot's local spatial density is considered as the main clue for the individual's motion decision-making and the enclosed configurations emerge from such individual-level interactions rather than being explicitly designed. Numerical simulations and real robotic experiments are conducted to validate the effectiveness of the proposed method. The results show that the proposed self-organized trapping method allows a swarm of robots to entrap multiple moving targets in a stable, flexible, noise-tolerate and size-scalable fashion. [ABSTRACT FROM AUTHOR]

Published

2023

169. Capture Dynamics of Dielectric Microparticles in Hollow-Core-Fiber-Based Optical Traps.

Author

Li, Kun, Wang, Rui, Shao, Shuangyun, Xie, Fang, Jiang, Yi, and Xie, Shangran

Subjects

OPTICAL tweezers, PARTICLE dynamics, NUMERICAL apertures, EQUATIONS of motion, DIELECTRICS, PARTICLE motion, ELECTRORHEOLOGY

Abstract

Optical traps formed in hollow-core fibers (HCFs) can overcome several limitations of conventional free-space optical tweezers. One of the key issues is to load particles from free space into the hollow core with high efficiency, in which process the capture dynamics of the particles in front of the HCF endface plays an important role. In this work, a comprehensive model of the trapping and capture process of the dielectric particles in front of HCF is established by taking into account the features of the fiber modes and the motional parameters of the particles. Stable capture positions are predicted based on analytical calculations of optical forces, and the dependencies of the equilibrium axial trapping position on the beam numerical aperture, the fiber core and particle diameters are provided. In addition, the trajectories and the capture dynamics of the particles are studied by solving the equation of motion for the particles under the impact of optical forces, predicting feasible parameter ranges of the initial amplitude and direction of particle launch velocity for achieving successful particle capture in front of HCF. The results can provide guidance for further improving the particle-loading efficiencies of the HCF-based optical traps, which may find applications of flying particle sensors and long-range particle binding in HCFs. [ABSTRACT FROM AUTHOR]

Published

2023

170. Measuring and modeling forces generated by microtubules.

Author

Gudimchuk, Nikita B. and Alexandrova, Veronika V.

Abstract

Tubulins are essential proteins, which are conserved across all eukaryotic species. They polymerize to form microtubules, cytoskeletal components of paramount importance for cellular mechanics. The microtubules combine an extraordinarily high flexural rigidity and a non-equilibrium behavior, manifested in their intermittent assembly and disassembly. These chemically fueled dynamics allow microtubules to generate significant pushing and pulling forces at their ends to reposition intracellular organelles, remodel membranes, bear compressive forces, and transport chromosomes during cell division. In this article, we review classical and recent studies, which have allowed the quantification of microtubule-generated forces. The measurements, to which we owe most of the quantitative information about microtubule forces, were carried out in biochemically reconstituted systems in vitro. We also discuss how mathematical and computational modeling has contributed to the interpretations of these results and shaped our understanding of the mechanisms of force production by tubulin polymerization and depolymerization. [ABSTRACT FROM AUTHOR]

Published

2023

171. Opto-electronic transport properties of resonant tunneling diodes with type-I and II postwells.

Author

Krüger, S., Pfenning, A., Jabeen, F., Hartmann, F., and Höfling, S.

Subjects

*TUNNEL diodes, *RESONANT tunneling, *HIGH temperatures, *QUANTUM wells, *INDIUM gallium arsenide, *AUDITING standards, *OPTICAL tweezers

Abstract

We investigate the opto-electronic transport properties of AlGaAs/GaAs double-barrier resonant tunneling diodes (RTDs) with GaAs1−xSbx type-II postwells and compare these to RTDs with InxGa1−xAs type-I postwells. Samples grown with Sb containing type-II postwells show a significant photocurrent enhancement for x = 24% compared to 5.5% and 34%, respectively, which is attributed to an efficient hole trapping based on the large hole trapping barrier of 396 meV. By contrasting the RTDs with type-I InGaAs quantum well RTDs, we observe an increased photoresponsivity by one order of magnitude. Our finding allows realizing RTD with efficient hole trapping in the vicinity of the active region of the double barrier structure with confinement energies well above the thermal energy at room temperature, which may allow the observation of single charge configurations even at elevated temperatures. [ABSTRACT FROM AUTHOR]

Published

2023

172. Twisted moiré photonic crystal enabled optical vortex generation through bound states in the continuum.

Author

Zhang, Tiancheng, Dong, Kaichen, Li, Jiachen, Meng, Fanhao, Li, Jingang, Munagavalasa, Sai, Grigoropoulos, Costas P., Wu, Junqiao, and Yao, Jie

Subjects

PHOTONIC crystals, BOUND states, OPTICAL vortices, VECTOR beams, OPTICAL information processing, OPTICAL tweezers, ANGULAR momentum (Mechanics)

Abstract

The twisted stacking of two layered crystals has led to the emerging moiré physics as well as intriguing chiral phenomena such as chiral phonon and photon generation. In this work, we identified and theoretically formulated a non-trivial twist-enabled coupling mechanism in twisted bilayer photonic crystal (TBPC), which connects the bound state in the continuum (BIC) mode to the free space through the twist-enabled channel. Moreover, the radiation from TBPC hosts an optical vortex in the far field with both odd and even topological orders. We quantitatively analyzed the twist-enabled coupling between the BIC mode and other non-local modes in the photonic crystals, giving rise to radiation carrying orbital angular momentum. The optical vortex generation is robust against geometric disturbance, making TBPC a promising platform for well-defined vortex generation. As a result, TBPCs not only provide a new approach to manipulating the angular momentum of photons, but may also enable novel applications in integrated optical information processing and optical tweezers. Our work broadens the field of moiré photonics and paves the way toward the novel application of moiré physics. The Authors in this work predict the radiation of twisted bilayer photonic crystals to host an optical vortex in the far field, which is enabled by connecting BIC modes in photonic crystals with the free space through a 'moiré channel'. [ABSTRACT FROM AUTHOR]

Published

2023

173. Probing mechanical interaction of immune receptors and cytoskeleton by membrane nanotube extraction.

Author

Manca, Fabio, Eich, Gautier, N'Dao, Omar, Normand, Lucie, Sengupta, Kheya, Limozin, Laurent, and Puech, Pierre-Henri

Subjects

*CELLULAR recognition, *T cell receptors, *CYTOSKELETON, *OPTICAL tweezers, *INTEGRINS, *IMMUNE recognition, *T cells

Abstract

The role of force application in immune cell recognition is now well established, the force being transmitted between the actin cytoskeleton to the anchoring ligands through receptors such as integrins. In this chain, the mechanics of the cytoskeleton to receptor link, though clearly crucial, remains poorly understood. To probe this link, we combine mechanical extraction of membrane tubes from T cells using optical tweezers, and fitting of the resulting force curves with a viscoelastic model taking into account the cell and relevant molecules. We solicit this link using four different antibodies against various membrane bound receptors: antiCD3 to target the T Cell Receptor (TCR) complex, antiCD45 for the long sugar CD45, and two clones of antiCD11 targeting open or closed conformation of LFA1 integrins. Upon disruption of the cytoskeleton, the stiffness of the link changes for two of the receptors, exposing the existence of a receptor to cytoskeleton link—namely TCR-complex and open LFA1, and does not change for the other two where a weaker link was expected. Our integrated approach allows us to probe, for the first time, the mechanics of the intracellular receptor–cytoskeleton link in immune cells. [ABSTRACT FROM AUTHOR]

Published

2023

174. Mass and shape determination of optically levitated nanoparticles.

Author

Schellenberg, Bart, Behbahani, Mina Morshed, Balasubramanian, Nithesh, Fikkers, Ties H., and Hoekstra, Steven

Subjects

*SILICA nanoparticles, *OPTICAL tweezers, *NANOPARTICLES, *SHAPE measurement, *MASS measurement

Abstract

When introducing a nanoparticle into an optical trap, its mass and shape are not immediately apparent. We combine a charge-based mass measurement with a shape determination method based on light scattering and an analysis of the damping rate anisotropy, all on the same set of silica nanoparticles, trapped using optical tweezers in vacuum. These methods have previously only been used separately, and the mass determination method has not been applied to asymmetric particles before. We demonstrate that the combination of these classification techniques is required to distinguish particles with similar mass but different shape, and vice versa. The ability to identify these parameters is a key step for a range of experiments on precision measurements and sensing using optically levitated nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2023

175. Trap characterization of high-growth-rate laser-assisted MOCVD GaN.

Author

Li, Wenbo, Zhang, Yuxuan, Chen, Zhaoying, Zhao, Hongping, Ringel, Steven A., and Arehart, Aaron R.

Subjects

*GALLIUM nitride, *CHEMICAL vapor deposition, *OPTICAL spectroscopy, *PITFALL traps, *POINT defects, *OPTICAL tweezers, *ELECTRON traps, *GALLIUM

Abstract

A detailed study comparing defect incorporation between laser-assisted metal-organic chemical vapor deposition (MOCVD)-grown GaN and conventional low- and high-growth-rate MOCVD GaN was conducted. Using deep-level transient and optical spectroscopy, traps throughout the bandgap were characterized where traps were found at EC-0.25 eV, EC-0.57 eV, EC-0.72 eV, EC-0.9 eV, EC-1.35 eV, EC-2.6 eV, and EC-3.28 eV in all three samples. This indicates no new traps were observed in the laser-assisted MOCVD GaN sample. Overall, the trap concentrations in the laser-assisted MOCVD sample were ∼2× higher than the optimal low-growth-rate sample, but this is primarily due to the increase in gallium vacancy EC-2.6 eV and carbon-related EC-3.28 eV trap concentrations. The EC-0.9 eV trap concentration was ∼2× higher in the laser-assisted sample, so proton irradiation experiments were conducted to identify the physical source of this level. The results indicated this was a native point defect likely related to gallium interstitials. Overall, this study shows that the laser-assisted MOCVD growth method is promising for future thick, high-quality GaN epilayers after further growth optimizations. [ABSTRACT FROM AUTHOR]

Published

2023

176. Classification of formalin-fixed bladder cancer cells with laser tweezer Raman spectroscopy.

Author

Tang, Nga Tsing, Robinson, Richard, Snook, Richard D., Brown, Mick, Clarke, Noel, and Gardner, Peter

Subjects

*RAMAN spectroscopy, *BLADDER cancer, *RAMAN lasers, *CANCER cells, *EARLY detection of cancer, *PREGNANCY tests, *OPTICAL tweezers

Abstract

Bladder cancer is a common cancer that is relatively hard to detect at an early stage because of its non-obvious symptoms. It is known that bladder cells can be found in urine samples which potentially could be used for early detection of bladder cancer. Raman spectroscopy is a powerful non-invasive tool for accessing biochemical information of cells. Combined with laser tweezers, to allow isolation of single cells, Raman spectroscopy has been used to characterise a number of bladder cells that might be found in a urine sample. Using principal component-canonical variates analysis (PC-CVA) and k-fold validation, the results shows that the invasive bladder cancer cells can be identified with accuracy greater than 87%. This demonstrates the potential of developing an early detection method that identifies the invasive bladder cancer cells in urine samples. [ABSTRACT FROM AUTHOR]

Published

2023

177. Interplay between particle trapping and heterogeneity in anomalous diffusion.

Author

Ribeiro, Haroldo V., Tateishi, Angel A., Lenzi, Ervin K., Magin, Richard L., and Perc, Matjaž

Subjects

*HETEROGENEITY, *LANGEVIN equations, *DIFFUSION coefficients, *OPTICAL tweezers

Abstract

Heterogeneous media diffusion is often described using position-dependent diffusion coefficients and estimated indirectly through mean squared displacement in experiments. This approach may overlook other mechanisms and their interaction with position-dependent diffusion, potentially leading to erroneous conclusions. Here, we introduce a hybrid diffusion model that merges a position-dependent diffusion coefficient with the trapping mechanism of the comb model. We derive exact solutions for position distributions and mean squared displacements, validated through simulations of Langevin equations. Our model shows that the trapping mechanism attenuates the impact of media heterogeneity. Superdiffusion occurs when the position-dependent coefficient increases superlinearly, while subdiffusion occurs for sublinear and inverse power-law relations. This nontrivial interplay between heterogeneity and state-independent mechanisms also leads to anomalous yet Brownian, and non-Brownian yet Gaussian regimes. These findings emphasize the need for cautious interpretations of experiments and highlight the limitations of relying solely on mean squared displacements or position distributions for diffusion characterization. Position dependent diffusion coefficients are often estimated indirectly through mean square displacement. The authors propose a diffusion model merging position-dependent coefficients and comb-like trapping mechanisms, revealing that particle trapping mitigates the impact of media heterogeneity and that thus caution is needed in experimental interpretations. [ABSTRACT FROM AUTHOR]

Published

2023

178. Magnetic‐Electric Metamirror and Polarizing Beam Splitter Composed of Anisotropic Nanoparticles.

Author

Tuz, Vladimir R., Prokhorov, Alexei V., Shesterikov, Alexander V., Volkov, Valentyn S., Chichkov, Boris N., and Evlyukhin, Andrey B.

Subjects

*OPTICAL polarization, *ANISOTROPIC crystals, *OPTICAL mirrors, *OPTICAL properties, *MAGNETIC dipoles, *BIREFRINGENCE, *BEAM splitters, *OPTICAL tweezers

Abstract

The emergence of new materials and fabrication techniques provides progress in the development of advanced photonic and communication devices. Transition metal dichalcogenides (e.g., molybdenum disulfide, MoS2) are novel materials possessing unique physical and chemical properties promising for optical applications. In this paper, a metasurface composed of particles made of bulk MoS2 is proposed and numerically studied considering its operation in the near‐infrared range. In the bulk configuration, MoS2 has a layered structure being a uniaxial anisotropic crystal demonstrating an optical birefringence property. It is supposed that the large‐scale and uniform MoS2 layers are synthesized in a vertical‐standing morphology, and then they are patterned into a regular 2D array of disks to form a metasurface. The natural anisotropy of MoS2 is utilized to realize the splitting of electric and magnetic dipole modes of the disks while optimizing their geometric parameters to bring the desired modes into overlap. At the corresponding resonant frequencies, the metasurface behaves as either an electric or a magnetic mirror, depending on the polarization of incident light. Based on the extraordinary reflection characteristics of the proposed metasurface, it can be considered an alternative to traditional mirrors and optical splitters when designing compact and highly efficient metadevices, which provide polarization and phase manipulation of electromagnetic waves on a subwavelength scale. [ABSTRACT FROM AUTHOR]

Published

2023

179. Optimized hologram generation method for real-time spontaneous manipulation.

Author

Qu, Zhelin, Liu, Shuo, Fan, Xudong, Fang, Changfeng, Wang, Jun-Lei, and Zhao, Xian

Subjects

*HOLOGRAPHY, *OBJECT manipulation, *OPTICAL tweezers, *MICRURGY, *PARALLEL algorithms

Abstract

Aided by computer generated holography, holographic optical tweezers enable manipulation of particles and objects with exceptional versatility. The responsiveness of the manipulation is often hindered by the speed of holograph generation, especially when the number of manipulated objects is high. Here, we propose an optimized hologram generation method with an improved iterative algorithm utilizing parallel computation with graphic processing units. The algorithm requires fewer iterations to produce high-quality holograms than established methods, such as weighted Gerchberg–Saxton algorithm, leading to a responsive and stable micromanipulation. This method expands the capabilities of holographic optical tweezers and provides more responsive traps in micro-manipulation. [ABSTRACT FROM AUTHOR]

Published

2023

180. The adenylate cyclase toxin RTX domain follows a series templated folding mechanism with implications for toxin activity.

Author

Guojun Chen, Han Wang, Bumba, Ladislav, Masin, Jiri, Sebo, Peter, and Hongbin Li

Subjects

*ADENYLATE cyclase, *WHOOPING cough, *BORDETELLA pertussis, *SINGLE molecules, *OPTICAL tweezers, *TOXINS, *PITUITARY adenylate cyclase activating polypeptide

Abstract

Folding of the Repeats-in-toxin (RTX) domain of the bacterial adenylate cyclase toxin-hemolysin (CyaA) is critical to its toxin activities and the virulence of the whooping cough agent Bordetella pertussis. The RTX domain (RD) contains five RTX blocks (RTX-i to RTX-v) and their folding is driven by the binding of calcium. However, the detailed molecular mechanism via which the folding signal transmits within the five RTX blocks remains unknown. By combining single molecule optical tweezers, protein engineering, and toxin activity assays, here we demonstrate that the folding of the RD follows a strict hierarchy, with the folding starting from its C-terminal block RTXv and proceeding towards the N-terminal RTX-i block sequentially. Our results reveal a strict series, templated folding mechanism, where the folding signal is transmitted along the RD in a series fashion from its C terminus continuously to the N terminus. Due to the series nature of this folding signal transmission pathway, the folding of RD can be disrupted at any given RTX block, rendering the RTX blocks located N-terminally to the disruption site and the acylation region of CyaA unfolded and abolishing CyaA’s toxin activities. Our results reveal key mechanistic insights into the secretion and folding process of CyaA and may open up new potential avenues towards designing new therapeutics to abolish toxin activity of CyaA and combat B. pertussis. [ABSTRACT FROM AUTHOR]

Published

2023

181. An optical tweezer-based microdroplet imaging technology.

Author

Zhai, Cong, Hong, Yujian, Lin, Zuzeng, Chen, Yulu, Wang, Han, Guo, Tong, and Hu, Chunguang

Subjects

OPTICAL tweezers, LIFE sciences, MICROSPHERES

Abstract

Microspheres can break the diffraction limit and magnify nano-structure imaging, and with its advantages of low cost and label-free operation, microsphere-assisted imaging has become an irreplaceable tool in the life sciences and for precision measurements. However, the tiny size and limited imaging field of traditional solid microspheres cause difficulties when imaging large sample areas. Alternatively, droplets have similar properties to those of microspheres, with large surface curvature and refractive-index difference from the surrounding environment, and they can also serve as lenses to focus light for observation and imaging. Previous work has shown that droplets with controllable size can be generated using an optical tweezer system and can be driven by optical traps to move precisely like solid microspheres. Here, a novel microdroplet-assisted imaging technology based on optical tweezers is proposed that better integrates the generation, manipulation, and utilization of droplets. ARTICLE HIGHLIGHTS: •Controllable droplet generation in an optical tweezer system by using photogenerated droplets. •The generated droplets can aid imaging in the same way as can solid microspheres but with larger field of view and higher imaging quality. •Droplets can be cleaned easily from flexible samples without causing mechanical damage. [ABSTRACT FROM AUTHOR]

Published

2023

182. Influence of acidity on liquid–liquid phase transitions of mixed secondary organic aerosol (SOA) proxy–inorganic aerosol droplets.

Author

Chen, Yueling, Pei, Xiangyu, Liu, Huichao, Meng, Yikan, Xu, Zhengning, Zhang, Fei, Xiong, Chun, Preston, Thomas C., and Wang, Zhibin

Subjects

PHASE transitions, AEROSOLS, ATMOSPHERIC aerosols, PHASE separation, ACIDITY, OPTICAL tweezers

Abstract

The phase state and morphology of aerosol particles play a critical role in determining their effect on climate. While aerosol acidity has been identified as a key factor affecting multiphase chemistry and phase transitions, the impact of acidity on the phase transition of multicomponent aerosol particles has not been extensively studied in situ. In this work, we employed aerosol optical tweezers (AOT) to probe the impact of acidity on the phase transition behavior of levitated aerosol particles. Our results revealed that higher acidity decreases the separation relative humidity (SRH) of aerosol droplets mixed with ammonium sulfate (AS) and secondary organic aerosol (SOA) proxy, such as 3-methylglutaric acid (3-MGA), 1,2,6-hexanetriol (HEXT) and 2,5-hexanediol (HEXD) across aerosol pH in atmospheric conditions. Phase separation of organic acids was more sensitive to acidity compared to organic alcohols. We found the mixing relative humidity (MRH) was consistently higher than the SRH in several systems. Phase-separating systems, including 3-MGA / AS, HEXT / AS and HEXD / AS, exhibited oxygen-to-carbon ratios (O:C) of 0.67, 0.50 and 0.33, respectively. In contrast, liquid–liquid phase separation (LLPS) did not occur in the high- O:C system of glycerol / AS, which had an O:C ratio of 1.00. Additionally, the morphology of 42 out of the 46 aerosol particles that underwent LLPS was observed to be a core–shell structure. Our findings provide a comprehensive understanding of the pH-dependent LLPS in individual suspended aerosol droplets and pave the way for future research on phase separation of atmospheric aerosol particles. [ABSTRACT FROM AUTHOR]

Published

2023

183. Fast Wide‐Field Quantum Sensor Based on Solid‐State Spins Integrated with a SPAD Array.

Author

Wang, Guoqing, Madonini, Francesca, Li, Boning, Li, Changhao, Xiang, Jinggang, Villa, Federica, and Cappellaro, Paola

Subjects

ATOMIC physics, AVALANCHE diodes, RARE earth ions, DETECTORS, OPTICAL tweezers, HUMAN information processing

Abstract

Achieving fast, sensitive, and parallel measurement of a large number of quantum particles is an essential task in building large‐scale quantum platforms for different quantum information processing applications such as sensing, computation, simulation, and communication. Current quantum platforms in experimental atomic and optical physics based on CMOS sensors and charged coupled device cameras are limited by either low sensitivity or slow operational speed. Here an array of single‐photon avalanche diodes is integrated with solid‐state spin defects in diamond to build a fast wide‐field quantum sensor, achieving a frame rate up to 100 kHz. The design of the experimental setup to perform spatially resolved imaging of quantum systems is presented. A few exemplary applications, including sensing DC and AC magnetic fields, temperature, strain, local spin density, and charge dynamics, are experimentally demonstrated using a nitrogen‐vacancy ensemble diamond sample. The developed photon detection array is broadly applicable to other platforms such as atom arrays trapped in optical tweezers, optical lattices, donors in silicon, and rare earth ions in solids. [ABSTRACT FROM AUTHOR]

Published

2023

184. Arrays of NdFeB Clusters in PDMS Background Used to Levitate T47D Human Cells.

Author

Tiep, N. H., Tu, B. D., and Cuong, L. V.

Subjects

MAGNETIC structure, MAGNETISM, CYTOLOGY, CELL anatomy, MAGNETIC properties, OPTICAL tweezers

Abstract

Sorting and trapping cells play an important role in fundamental cellular and biology research that enables the study of single-cell behaviors, which are different in comparison with a cluster of cells. Contactless handling techniques using different optical, mechanical, or magnetic phenomena have been studied for single-cell trapping. Among them, the diamagnetic force created by magnetic structures on cells is significant and stable both in time and in space. In this work, arrays of hard magnetic clusters in the PDMS background (hereafter called magnetic structure) were successfully fabricated using the magnetic imprinting method. The magnetic structure shows a proper magnetic property and the possibility to sort and trap T47D single cells via the diamagnetic levitation phenomenon at defined positions, which are both experimentally observed and theoretically calculated. The obtained results show the promise of developing a simple way to separate directly living cells. [ [ABSTRACT FROM AUTHOR]

Published

2023

185. Ultra-enhanced optical tweezers: design and optimization based on plasmonic coaxial triple-nanoaperture.

Author

Radman, Hadiseh, Mobini, Alireza, Kamirkhani, Arash, and Nazari, Fakhroddin

Abstract

In this work, we present an enhanced nano-optical tweezers based on the new triple-nanoaperture structure for trapping nanoparticles using low power laser. Different structures with a single, double and triple-nanoaperture with nanometer gap created in 65 nm gold film, are examined. The results show there is a several times enhancement in transmission coefficient for proposed triple-nanoaperture based design. Considering this structure, the geometrical parameters like radius (R), center-to-center distance (D) and configuration of aperture have been manipulated to achieve optimum design. Using optimized parameters both transmission and optical force calculated and compared with the original structure which uses a single aperture. The results show total optical force inserted to 30 nm nanoparticle, enhanced up to 20 times as compared with the original structure. This structure and related results can be used to design new enhanced nano-optical tweezers with high accuracy for different applications. [ABSTRACT FROM AUTHOR]

Published

2023

186. Experimental Study of the Drift Motion of SF6 Molecules under the Action of CO2-Laser Radiation

Author

Voskoboev, A. A., Kuz’menko, V. A., Mezhevov, V. S., and Sautin, A. R.

Published

2024

187. Beam manipulation and force estimation in a dynamic holographic optical tweezers

Author

Singh, Shilpa and Boruah, Bosanta R.

Published

2024

188. Corrugated Gold Tip as Optical Tweezers to Apply Force on Zinc Sulphide Quantum Dot Nanoparticle

Author

Khosravi, Ali Azam, Zohrabi, Mehdi, Mowlavi, Mahdi, Far, Mohhamad Reza Mohebbi, Gazizov, Almaz, and Salakhov, Myakzum

Published

2024

189. Isolating and enhancing single-photon emitters for 1550 nm quantum light sources using double nanohole optical tweezers.

Author

Sharifi, Zohreh, Dobinson, Michael, Hajisalem, Ghazal, Shariatdoust, Mirali Seyed, Frencken, Adriaan L., van Veggel, Frank C. J. M., and Gordon, Reuven

Subjects

*OPTICAL tweezers, *PHOTONS, *ERBIUM, *NANOCRYSTALS, *WAVELENGTHS, *PHOTON emission

Abstract

Single-photon sources are required for quantum technologies and can be created from individual atoms and atom-like defects. Erbium ions produce single photons at low-loss fiber optic wavelengths, but they have low emission rates, making them challenging to isolate reliably. Here, we tune the size of gold double nanoholes (DNHs) to enhance the emission of single erbium emitters, achieving 50× enhancement over rectangular apertures previously demonstrated. This produces enough enhancement to show emission from single nanocrystals at wavelengths not seen in our previous work, i.e., 400 and 1550 nm. We observe discrete levels of emission for nanocrystals with low numbers of emitters and demonstrate isolating single emitters. We describe how the trapping time is proportional to the enhancement factor for a given DNH structure, giving us an independent way to measure the enhancement. This shows a promising path to achieving single emitter sources at 1550 nm. [ABSTRACT FROM AUTHOR]

Published

2021

190. Estimating transition path times and shapes from single-molecule photon trajectories: A simulation analysis.

Author

Taumoefolau, Grace H. and Best, Robert B.

Subjects

*FLUORESCENCE resonance energy transfer, *OPTICAL tweezers, *PHOTONS, *PUBLIC transit

Abstract

In a two-state molecular system, transition paths comprise the portions of trajectories during which the system transits from one stable state to the other. Because of their low population, it is essentially impossible to obtain information on transition paths from experiments on a large sample of molecules. However, single-molecule experiments such as laser optical tweezers or Förster resonance energy transfer (FRET) spectroscopy have allowed transition-path durations to be estimated. Here, we use molecular simulations to test the methodology for obtaining information on transition paths in single-molecule FRET by generating photon trajectories from the distance trajectories obtained in the simulation. Encouragingly, we find that this maximum likelihood analysis yields transition-path times within a factor of 2–4 of the values estimated using a good coordinate for folding, but tends to systematically underestimate them. The underestimation can be attributed partly to the fact that the large changes in the end–end distance occur mostly early in a folding trajectory. However, even if the transfer efficiency is a good reaction coordinate for folding, the assumption that the transition-path shape is a step function still leads to an underestimation of the transition-path time as defined here. We find that allowing more flexibility in the form of the transition path model allows more accurate transition-path times to be extracted and points the way toward further improvements in methods for estimating transition-path time and transition-path shape. [ABSTRACT FROM AUTHOR]

Published

2021

191. Editorial: Optical Trapping (Laser Tweezers) and Nanosurgery (Laser Scissors)

Author

Berns, Michael W, Rubinsztein-Dunlop, Halina, Preece, Daryl, and Ritsch-Marte, Monika

Subjects

laser, optics, optical tweezers, trap, laser scissors, cell, tissue, Mathematical sciences, Physical sciences

Published

2021

192. Ion flow and membrane tension studies with optical tweezers and nanopipettes

Author

McHugh, Jeffrey and Keyser, Ulrich

Subjects

Optical tweezers, Nanopipettes, Electroosmotic flow, Nanofluidics, Cell membrane tension, Cell mechanics, Electrophysiology, Biophysics

Abstract

This thesis presents a discussion of a novel combination of state-of-the-art experimental techniques into a single microscope setup and the studies this has enabled. Optical tweezers, nanopipettes, and fluorescence were all combined to study the effect of salt species on nanoscale voltage driven flows, the mechanical behaviour of cell membranes, and the electrical activity from various cells. Voltage driven, or electroosmotic, flow was quantified by measuring the piconewton forces of the flow field outside nanopipettes in diff erent salt conditions using optical tweezers. Changing salt conditions revealed new flow behaviour, with flow reversing in CsCl compared to other salts. The role of substrate sti ness in cell membrane tension was investigated using optical tweezers. Optical tweezers were used to trap colloidal particles and then adhere them to the membranes of xenopus laevis retinal ganglion cell axons and NIH 3T3 fibroblasts to pull lipid tethers. Pulling these tethers allowed the e ffective cell membrane tension of these samples to be investigated. These tethers were pulled from cells plated on glass and hydrogels with di fferent elastic moduli. The force response was the same across hydrogels but di fferent on glass, for both neurons and fibroblasts. Fluorescence microscopy was used in-situ to confirm the presence of lipid tethers. Work towards a nanopipette electrophysiology platform was performed, with successful recordings of spontaneous activity taken from rat and mice neuron and astrocyte cultures for longer than 1 hour achieved. Recordings were attempted in brain tissue slices and also performed simultaneously with micro-electrode array recordings for comparison with network activity. Electrophysiological recordings from unmodified escherichia coli bacteria are also demonstrated. The outcome of this work is the advancement of a combined approach using tools from nanoscience to advance the toolset of biophysics. Biophysics concerns itself with complex phenomena, and our findings and demonstrations of method advancement have implications and applications in the understanding of nanoscale transport, cell mechanics, and electrophysiology.

Published

2020

193. Broadband rheological characterisation of soft functional materials

Author

Stoev, Iliya and Eiser, Erika

Subjects

microrheology, viscoelasticity, optical tweezers, dynamic light scattering, complex fluids, hydrogels, DNA nanotechnology

Abstract

Conventional bulk rheology presents a well-established technique for the mechanical characterisation of soft materials, ranging from liquid suspensions and emulsions to tenuous or even stiff gels. Probing the internal microstructure and understanding the relaxation of such materials has always been of great interest to industries, where the flow behaviour and stress response are of paramount importance in quality control for achieving high product performance. However, although generally reliable, bulk rheology suffers from certain limitations related to the frequency range and measurement sensitivity, which do not allow probing fast processes occurring on the microscale in complex viscoelastic fluids. This has sparked the search for an alternative method of extracting the high-frequency response and has led to a significant rise in the use of microrheology, where tracer particles provide indirect information about the viscoelasticity of the fluid, in which they are embedded. Recent advances in the fields of optics and electronics paved the way for using laser trapping and light scattering beyond their standard applications. In this thesis, I combine mechanical and optical measurements applied on newly emerging materials in order to extract their viscoelasticity over a broad frequency range in an attempt to gain better understanding of their internal self-organisation. In particular, I concentrate on DNA-based and clay-based hydrogels, which exhibit strong degree of swelling when dispersed in an aqueous solvent. These soft transient networks represent intriguing thermoresponsive and time-dependent systems, where the flexibility in the design opens up new exciting avenues within the field of nanotechnology.

Published

2020

194. Cationic Residues of the HIV-1 Nucleocapsid Protein Enable DNA Condensation to Maintain Viral Core Particle Stability during Reverse Transcription

Author

Helena Gien, Michael Morse, Micah J. McCauley, Ioulia Rouzina, Robert J. Gorelick, and Mark C. Williams

Subjects

DNA condensation, optical tweezers, atomic force microscopy, capsid uncoating, HIV-1 nucleocapsid protein, Microbiology, QR1-502

Abstract

The HIV-1 nucleocapsid protein (NC) is a multifunctional viral protein necessary for HIV-1 replication. Recent studies have demonstrated that reverse transcription (RT) completes in the intact viral capsid, and the timing of RT and uncoating are correlated. How the small viral core stably contains the ~10 kbp double stranded (ds) DNA product of RT, and the role of NC in this process, are not well understood. We showed previously that NC binds and saturates dsDNA in a non-specific electrostatic binding mode that triggers uniform DNA self-attraction, condensing dsDNA into a tight globule against extending forces up to 10 pN. In this study, we use optical tweezers and atomic force microscopy to characterize the role of NC’s basic residues in dsDNA condensation. Basic residue mutations of NC lead to defective interaction with the dsDNA substrate, with the constant force plateau condensation observed with wild-type (WT) NC missing or diminished. These results suggest that NC’s high positive charge is essential to its dsDNA condensing activity, and electrostatic interactions involving NC’s basic residues are responsible in large part for the conformation, size, and stability of the dsDNA-protein complex inside the viral core. We observe DNA re-solubilization and charge reversal in the presence of excess NC, consistent with the electrostatic nature of NC-induced DNA condensation. Previous studies of HIV-1 replication in the presence of the same cationic residue mutations in NC showed significant defects in both single- and multiple-round viral infectivity. Although NC participates in many stages of viral replication, our results are consistent with the hypothesis that cationic residue mutations inhibit genomic DNA condensation, resulting in increased premature capsid uncoating and contributing to viral replication defects.

Published

2024

195. Focused acoustic vortex generated by a circular array of planar sector transducers using an acoustic lens, and its application in object manipulation.

Author

Zhou, Chenchen, Wang, Qingdong, Pu, Shifu, Li, Yuzhi, Guo, Gepu, Chu, Hongyan, Ma, Qingyu, Tu, Juan, and Zhang, Dong

Subjects

*OBJECT manipulation, *ACOUSTIC transducers, *HIGH-intensity focused ultrasound, *ENERGY consumption, *TREATMENT effectiveness, *OPTICAL tweezers, *TRANSDUCERS

Abstract

For enhanced energy utilization with improved flexibility and capability for object manipulation, a focused acoustic vortex (FAV) is devised by installing a spherical acoustic lens on a circular array of planar sector transducers. Based on the acoustic refraction of a concave spherical acoustic lens, numerical simulations show that an FAV with considerable pressure gain and strengthened acoustic gradient force (AGF) can be produced by the effective concentration of acoustic waves. The performance of rotational object trapping is shown by the axial and radial distributions of the AGF for FAVs of different orders. Elastic objects of nanometer, micrometer, millimeter, and even larger-than-wavelength size can be captured with the trapping radius determined by the topological charge. With the established 16-channel experimental system, FAVs of different orders are verified by their clear pressure circles and phase spirals. The trapping radius and rotation speed of object capture are demonstrated using polyethylene particles of various sizes and FAVs of different orders. The favorable results provide an experimentally applicable method of FAV generation using the simplified circular transducer array to accomplish more accurate, stable, and flexible object manipulations with strengthened AGFs. Also, FAVs could offer an efficient means of high-intensity focused ultrasound therapy to improve the therapeutic effect of tumor treatments by accumulating drug particles, thereby enabling more potential applications in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2020

196. Detection of single DNA mismatches by force spectroscopy in short DNA hairpins.

Author

Landuzzi, F., Viader-Godoy, X., Cleri, F., Pastor, I., and Ritort, F.

Subjects

*DNA, *OPTICAL spectroscopy, *HAIRPIN (Genetics), *OPTICAL tweezers, *MOLECULAR dynamics, *DNA structure, *DNA replication, *BASE pairs

Abstract

Identification of defective DNA structures is a difficult task, since small differences in base-pair bonding are hidden in the local structural variability of a generally random base-pair sequence. Defects, such as base mismatches, missing bases, crosslinks, and so on, occur in DNA with high frequency and must be efficiently identified and repaired to avoid dire consequences such as genetic mutations. Here, we focus on the detection of base mismatches, which is local deviations from the ideal Watson–Crick pairing rule, which may typically originate from DNA replication process, foreign chemical attack, or ionizing radiation. Experimental detection of a mismatch defect demands the ability to measure slight deviations in the free energy and molecular structure. We introduce different mismatches in short DNA hairpins (10 or 20 base pairs plus a 4-base loop) sandwiched between dsDNA handles to be used in single-molecule force spectroscopy with optical tweezers. We perform both hopping and force-pulling experiments to measure the excess free energies and deduce the characteristic kinetic signatures of the mismatch from the force–distance curves. All-atom molecular dynamics simulations lend support to the detailed interpretation of the experimental data. Such measurements, at the lowest sensitivity limits of this experimental technique, demonstrate the capability of identifying the presence of mismatches in a random complementary dsDNA sequence and provide lower bounds for the ability to distinguish different structural defects. [ABSTRACT FROM AUTHOR]

Published

2020

197. Optically Programmable Living Microrouter in Vivo

Author

Xiaoshuai Liu, Huaying Wu, Shuai Wu, Haifeng Qin, Tiange Zhang, Yufeng Lin, Xianchuang Zheng, and Baojun Li

Subjects

drug delivery, nanotherapeutics, optical tweezers, programmable medical micromachines, red blood cells, Science

Abstract

Abstract With high reconfigurability and swarming intelligence, programmable medical micromachines (PMMs) represent a revolution in microrobots for executing complex coordinated tasks, especially for dynamic routing of various targets along their respective routes. However, it is difficult to achieve a biocompatible implantation into the body due to their exogenous building blocks. Herein, a living microrouter based on an organic integration of endogenous red blood cells (RBCs), programmable scanning optical tweezers and flexible optofluidic strategy is reported. By harvesting energy from a designed optical force landscape, five RBCs are optically rotated in a controlled velocity and direction, under which, a specific actuation flow is achieved to exert the well‐defined hydrodynamic forces on various biological targets, thus enabling a selective routing by integrating three successive functions, i.e., dynamic input, inner processing, and controlled output. Benefited from the optofluidic manipulation, various blood cells, such as the platelets and white blood cells, are transported toward the damaged vessel and cell debris for the dynamic hemostasis and targeted clearance, respectively. Moreover, the microrouter enables a precise transport of nanodrugs for active and targeted delivery in a large quantity. The proposed RBC microrouter might provide a biocompatible medical platform for cell separation, drug delivery, and immunotherapy.

Published

2023

198. The Histone Chaperones SET/TAF‐1β and NPM1 Exhibit Conserved Functionality in Nucleosome Remodeling and Histone Eviction in a Cytochrome c‐Dependent Manner

Author

Pedro Buzón, Alejandro Velázquez‐Cruz, Laura Corrales‐Guerrero, Antonio Díaz‐Quintana, Irene Díaz‐Moreno, and Wouter H. Roos

Subjects

fluorescence microscopy, nucleophosmin 1, optical tweezers, SET/template‐activating factor‐Iβ, single‐molecule methods, Science

Abstract

Abstract Chromatin homeostasis mediates essential processes in eukaryotes, where histone chaperones have emerged as major regulatory factors during DNA replication, repair, and transcription. The dynamic nature of these processes, however, has severely impeded their characterization at the molecular level. Here, fluorescence optical tweezers are applied to follow histone chaperone dynamics in real time. The molecular action of SET/template‐activating factor‐Iβ and nucleophosmin 1—representing the two most common histone chaperone folds—are examined using both nucleosomes and isolated histones. It is shown that these chaperones present binding specificity for fully dismantled nucleosomes and are able to recognize and disrupt non‐native histone‐DNA interactions. Furthermore, the histone eviction process and its modulation by cytochrome c are scrutinized. This approach shows that despite the different structures of these chaperones, they present conserved modes of action mediating nucleosome remodeling.

Published

2023

199. Comparison of the human’s and camel’s red blood cell deformability by optical tweezers and Raman spectroscopy

Author

Tuna Pesen, Mete Haydaroglu, Simal Capar, Ugur Parlatan, and Mehmet Burcin Unlu

Subjects

Red blood cells, Cell mechanics, Raman spectroscopy, Optical tweezers, Biology (General), QH301-705.5, Biochemistry, QD415-436

Abstract

Red blood cells of vertebrates have undergone evolutionary changes over time, leading to the diversification of morphological and mechanical properties of red blood cells (RBCs). Among the vertebrates, camelids have the most different RBC characteristics. As a result of adaptation to the desert environment, camelid RBCs can expand twice as much of their total volume in the case of rapid hydration yet are almost undeformable under mechanical stress. In this work, the mechanical and chemical differences in the RBC properties of the human and camelid species were examined using optical tweezers and Raman spectroscopy. We measured the deformability of camel and human RBCs at the single-cell level using optical tweezers. We found that the deformability index (DI) of the camel and the human RBCs were 0.024 ± 0.019 and 0.215 ± 0.061, respectively. To investigate the chemical properties of these cells, we measured the Raman spectra of the whole blood samples. The result of our study indicated that some of the Raman peaks observed on the camel’s blood spectrum were absent in the human blood’s spectrum, which further points to the difference in chemical contents of these two species’ RBCs.

Published

2023

200. Effects of quantum fluctuations on macroscopic quantum tunneling and self-trapping of a BEC in a double-well trap.

Author

Kh Abdullaev, Fatkhulla, Galimzyanov, Ravil M, and Shermakhmatov, Akbar M

Subjects

*QUANTUM tunneling, *QUANTUM fluctuations, *BOSE-Einstein condensation, *FREQUENCIES of oscillating systems, *OPTICAL tweezers

Abstract

In this paper, we study the influence of quantum fluctuations (QFs) on the macroscopic quantum tunneling and self-trapping (ST) of a two-component Bose–Einstein condensate in a double-well trap. QFs are described by the Lee–Huang–Yang (LHY) term in the modified Gross–Pitaevskii (GP) equation. Employing the modified GP equation in a scalar approximation, we derive a dimer model using a two-mode approximation. The frequencies of Josephson oscillations and ST conditions under QFs are found analytically and proven by numerical simulations of the modified GP equation. The tunneling and localization phenomena are also investigated for the case of the LHY fluid loaded in a double-well potential. [ABSTRACT FROM AUTHOR]

Published

2023