Your search keyword '"Santoyo, F."' showing total 12 results

1. Fish swim water bulk displacement visualization with digital holographic interferometry.

Author

De la Torre I MH, Frausto-Rea GDR, Mendoza-Santoyo F, and Del S Hernandez Montes M

Subjects

Animals, Equipment Design, Goldfish physiology, Holography methods, Interferometry methods, Poecilia physiology, Swimming physiology, Water metabolism

Abstract

A collimated transmission beam interferometer is used to measure the water motion provoked by the fish swimming through it. An indirect measurement of the fish motion impact in the water contained in a home-type aquarium is detected. Measurements of the whole aquarium are possible due to a large diameter collimated laser beam in the interferometer's object arm. This beam goes through the aquarium, and any perturbation inside it deflects the collimated beam. The interferometer detects a phase difference, i.e., the beam through the disturbed water undergoes different optical paths. This optical phase change was first demonstrated by means of a simple test using spherical steel marbles placed in a cuvette. For this, the small water movements for a single steel marble are detected with the acquired optical phase. Next, the aquarium optical phase results show water movements according to the fishes' size and swimming speed. It is worth mentioning that no additives were added to the aquarium's fresh water during the tests, so the water was crystal clear.

Published

2021

2. Measurement of morphology thickness and refractive index in a melanoma A375 cell line using digital holographic microscopy.

Author

Palacios-Ortega N, Hernández-Montes MDS, Mendoza-Santoyo F, and Flores-Moreno JM

Subjects

Cell Line, Tumor, Cell Shape, Cell Size, Holography methods, Humans, Microscopy methods, Optical Imaging, Refractometry, Signal Processing, Computer-Assisted, Holography instrumentation, Melanoma diagnostic imaging, Microscopy instrumentation

Abstract

Digital holographic microscopy (DHM) is a technique that has high potential for analyzing biological samples and has been successfully applied to the study of cells and cell lines providing information about important parameters such as refractive index, morphology, and dry mass, among others; it has also found applicability to study the effects of therapeutic treatments. Finding the size and shape of cells is important since they tend to change in the presence of some pathologies. In this research work, we obtain the morphology thickness and refractive index of the A375 melanoma cell line through a slight tilting of the cell in a DHM setup. Further, the development of a novel mathematical expression based on this tilt and in the optical phase difference is presented. We show images of melanoma cells with the refractive index information included, and their morphology thickness as rendered from the holographic phase maps recorded with DHM.

Published

2021

3. Morphology visualization of irregular shape bacteria by electron holography and tomography.

Author

Ortega E, Cantu-Valle J, Plascencia-Villa G, Vergara S, Mendoza-Santoyo F, Londono-Calderon A, Santiago U, and Ponce A

Subjects

Electrons, Gold, Metal Nanoparticles chemistry, Microscopy, Electron, Scanning Transmission, Electron Microscope Tomography methods, Holography methods, Imaging, Three-Dimensional methods, Staphylococcus aureus ultrastructure

Abstract

In the current work, irregular morphology of Staphylococcus aureus bacteria has been visualized by phase retrieval employing off-axis electron holography (EH) and 3D reconstruction electron tomography using high-angle annular dark field scanning transmission electron microscopy (HAADF-STEM). Bacteria interacting with gold nanoparticles (AuNP) acquired a shrunken or irregular shape due to air dehydration processing. STEM imaging shows the attachment of AuNP on the surface of cells and suggests an irregular 3D morphology of the specimen. The phase reconstruction demonstrates that off-axis electron holography can reveal with a single hologram the morphology of the specimen and the distribution of the functionalized AuNPs. In addition, EH reduces significantly the acquisition time and the cumulative radiation damage (in three orders of magnitude) over biological samples in comparison with multiple tilted electron expositions intrinsic to electron tomography, as well as the processing time and the reconstruction artifacts that may arise during tomogram reconstruction., (© 2017 Wiley Periodicals, Inc.)

Published

2017

4. Surface structural damage study in cortical bone due to medical drilling.

Author

Tavera R CG, De la Torre-I MH, Flores-M JM, Hernandez M MDS, Mendoza-Santoyo F, Briones-R MJ, and Sanchez-P J

Subjects

Animals, Cortical Bone chemistry, Fracture Healing physiology, Interferometry, Swine, Weight-Bearing, Bone Screws adverse effects, Cortical Bone injuries, Femur injuries, Holography instrumentation, Imaging, Three-Dimensional methods

Abstract

A bone's fracture could be produced by an excessive, repetitive, or sudden load. A regular medical practice to heal it is to fix it in two possible ways: external immobilization, using a ferule, or an internal fixation, using a prosthetic device commonly attached to the bone by means of surgical screws. The bone's volume loss due to this drilling modifies its structure either in the presence or absence of a fracture. To observe the bone's surface behavior caused by the drilling effects, a digital holographic interferometer is used to analyze the displacement surface's variations in nonfractured post-mortem porcine femoral bones. Several nondrilled post-mortem bones are compressed and compared to a set of post-mortem bones with a different number of cortical drillings. During each compression test, a series of digital interferometric holograms were recorded using a high-speed CMOS camera. The results are presented as pseudo 3D mesh displacement maps for comparisons in the physiological range of load (30 and 50 lbs) and beyond (100, 200, and 400 lbs). The high resolution of the optical phase gives a better understanding about the bone's microstructural modifications. Finally, a relationship between compression load and bone volume loss due to the drilling was observed. The results prove that digital holographic interferometry is a viable technique to study the conditions that avoid the surgical screw from loosening in medical procedures of this kind.

Published

2017

5. Calibration for medium resolution off-axis electron holography using a flexible dual-lens imaging system in a JEOL ARM 200F microscope.

Author

Cantu-Valle J, Ruiz-Zepeda F, Mendoza-Santoyo F, Jose-Yacaman M, and Ponce A

Subjects

Calibration, Nanotechnology methods, Holography methods, Microscopy, Electron, Transmission methods

Abstract

In this work the calibration of a medium resolution off-axis electron holography using a dual-lens imaging system in a JEOL ARM 200F is shown. The objective dual-lens configuration allows adjusting the field of view from 35nm to 2.5μm. Subsequently, the parameters used in phase shift reconstruction were calibrated considering biprism voltage versus fringe spacing (σ) and versus fringe width (W). The reliability of the transmission electron microscope performance using these parameters was achieved using gold nanoparticles of known size and adjusting the excitation voltage of the lenses., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

6. Holographic otoscope using dual-shot-acquisition for the study of eardrum biomechanical displacements.

Author

Flores-Moreno JM, Mendoza Santoyo F, and Estrada Rico JC

Subjects

Algorithms, Animals, Chinchilla, Equipment Design, Equipment Failure Analysis, Otoscopy methods, Tympanic Membrane anatomy & histology, Vibration, Holography instrumentation, Holography methods, Image Interpretation, Computer-Assisted instrumentation, Image Interpretation, Computer-Assisted methods, Movement physiology, Otoscopes, Tympanic Membrane physiology

Abstract

Recently an optoelectronic holography system was deployed in the clinic with the purpose of quantifying the tympanic membrane (TM) displacements of various mammal species, the objective being the understanding of their middle ear biomechanics. The optoelectronic holography system has an in-line configuration where the data gathered is decoded using lensless digital holography with the Fresnel approximation. This paper presents quantitative data obtained from an acoustically excited postmortem chinchilla's TM. To achieve this we used a robust customized windowed unwrapping method to unwrap the noisy optical phase obtained by subtracting phase maps of two recorded holograms and the results were compared with those obtained when using the unwrapping branch-cut algorithm. Additionally, phase maps obtained by the phase-stepping technique were compared applying both unwrapping methods. For in vivo applications particular emphasis is made on post-processing dual-shot-acquisition of holograms as one of various acquisition strategies and algorithms to diminish measurement error due to heartbeat, breathing, and patient's head motion as well as environment induced mechanical disturbances present in a noncontrolled environment, such as in a clinic. By recording only two holograms representing a stationary and deformed state of eardrum, respectively, we can increase the acquisition speed of the camera used to record faster events happening on the TM surface.

Published

2013

7. 3D displacement measurements of the tympanic membrane with digital holographic interferometry.

Author

Solís SM, Santoyo FM, and Hernández-Montes Mdel S

Subjects

Animals, Cats, Elastic Modulus, Equipment Design, Equipment Failure Analysis, Signal Processing, Computer-Assisted instrumentation, Tympanic Membrane anatomy & histology, Vibration, Acoustic Stimulation methods, Elasticity Imaging Techniques instrumentation, Holography instrumentation, Imaging, Three-Dimensional instrumentation, Imaging, Three-Dimensional methods, Interferometry instrumentation, Tympanic Membrane physiology

Abstract

A digital holographic interferometry (DHI) system with three object-illumination beams is used for the first time to measure micro-deformations along the x, y and z axes (3D) on the tympanic membrane (TM) surface of a post-mortem cat. In order to completely and accurately measure the TM surface displacements its shape is required to map on it the x, y and z micro-deformations. The surface contour is obtained by applying small shifts to the object illumination source position. A cw laser in stroboscopic mode and a CCD camera were used and synchronized to the acoustic excitation wave that produces a resonant vibration mode on the tympanic membrane surface. This research work reports on the 3D full field of view response of the TM to sound pressure, and has as its main goal the presentation of DHI as an alternative technique to study the TM real displacement behavior when subjected to sound waves, so it can be used as a diagnostic tool to prevent and treat TM diseases.

Published

2012

8. Holographic otoscope for nanodisplacement measurements of surfaces under dynamic excitation.

Author

Flores-Moreno JM, Furlong C, Rosowski JJ, Harrington E, Cheng JT, Scarpino C, and Santoyo FM

Subjects

Acoustics, Animals, Chinchilla, Electronics, Medical methods, Equipment Design, Otolaryngology methods, Sensitivity and Specificity, Vibration, Electronics, Medical instrumentation, Holography methods, Image Processing, Computer-Assisted methods, Otoscopes statistics & numerical data, Tympanic Membrane physiology

Abstract

We describe a novel holographic otoscope system for measuring nanodisplacements of objects subjected to dynamic excitation. Such measurements are necessary to quantify the mechanical deformation of surfaces in mechanics, acoustics, electronics, biology, and many other fields. In particular, we are interested in measuring the sound-induced motion of biological samples, such as an eardrum. Our holographic otoscope system consists of laser illumination delivery (IS), optical head (OH), and image processing computer (IP) systems. The IS delivers the object beam (OB) and the reference beam (RB) to the OH. The backscattered light coming from the object illuminated by the OB interferes with the RB at the camera sensor plane to be digitally recorded as a hologram. The hologram is processed by the IP using the Fresnel numerical reconstruction algorithm, where the focal plane can be selected freely. Our holographic otoscope system is currently deployed in a clinic, and is packaged in a custom design. It is mounted in a mechatronic positioning system to increase its maneuverability degrees to be conveniently positioned in front of the object to be measured. We present representative results highlighting the versatility of our system to measure deformations of complex elastic surfaces in the wavelength scale including a copper foil membrane and postmortem tympanic membrane. SCANNING 33: 342-352, 2011. © 2011 Wiley Periodicals, Inc., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2011

9. Digital holographic interferometer using simultaneously three lasers and a single monochrome sensor for 3D displacement measurements.

Author

Saucedo-A T, De la Torre-Ibarra MH, Santoyo FM, and Moreno I

Subjects

Color, Equipment Design, Equipment Failure Analysis, Holography methods, Imaging, Three-Dimensional instrumentation, Interferometry instrumentation, Lasers, Transducers

Abstract

The use of digital holographic interferometry for 3D measurements using simultaneously three illumination directions was demonstrated by Saucedo et al. (Optics Express 14(4) 2006). The technique records two consecutive images where each one contains three holograms in it, e.g., one before the deformation and one after the deformation. A short coherence length laser must be used to obtain the simultaneous 3D information from the same laser source. In this manuscript we present an extension of this technique now illuminating simultaneously with three different lasers at 458, 532 and 633 nm, and using only one high resolution monochrome CMOS sensor. This new configuration gives the opportunity to use long coherence length lasers allowing the measurement of large object areas. A series of digital holographic interferograms are recorded and the information corresponding to each laser is isolated in the Fourier spectral domain where the corresponding phase difference is calculated. Experimental results render the orthogonal displacement components u, v and w during a simple load deformation.

Published

2010

10. Insect wing deformation measurements using high speed digital holographic interferometry.

Author

Aguayo DD, Mendoza Santoyo F, De la Torre-I MH, Salas-Araiza MD, Caloca-Mendez C, and Gutierrez Hernandez DA

Subjects

Animals, Elastic Modulus physiology, Equipment Design, Equipment Failure Analysis, Image Enhancement instrumentation, Butterflies physiology, Flight, Animal physiology, Holography instrumentation, Interferometry instrumentation, Signal Processing, Computer-Assisted instrumentation, Video Recording instrumentation, Wings, Animal physiology

Abstract

An out-of-plane digital holographic interferometry system is used to detect and measure insect's wing micro deformations. The in-vivo phenomenon of the flapping is registered using a high power cw laser and a high speed camera. A series of digital holograms with the deformation encoded are obtained. Full field deformation maps are presented for an eastern tiger swallowtail butterfly (Pterourus multicaudata). Results show no uniform or symmetrical deformations between wings. These deformations are in the order of hundreds of nanometers over the entire surface. Out-of-plane deformation maps are presented using the unwrapped phase maps.

Published

2010

11. Multimode vibration analysis with high-speed TV holography and a spatiotemporal 3D Fourier transform method.

Author

Trillo C, Doval AF, Mendoza-Santoyo F, Pérez-López C, de la Torre-Ibarra M, and Deán JL

Subjects

Fourier Analysis, Vibration, Holography methods, Image Interpretation, Computer-Assisted methods, Imaging, Three-Dimensional methods, Materials Testing methods, Membranes, Artificial, Television, Video Recording methods

Abstract

The combination of a high-speed TV holography system and a 3D Fourier-transform data processing is proposed for the analysis of multimode vibrations in plates. The out-of-plane displacement of the object under generic vibrational excitation is resolved in time by the fast acquisition rate of a high-speed camera, and recorded in a sequence of interferograms with spatial carrier. A full-field temporal history of the multimode vibration is thus obtained. The optical phase of the interferograms is extracted and subtracted from the phase of a reference state to yield a sequence of optical phase-change maps. Each map represents the change undergone by the object between any given state and the reference state. The sequence of maps is a 3D array of data (two spatial dimensions plus time) that is processed with a 3D Fourier-transform algorithm. The individual vibration modes are separated in the 3D frequency space due to their different vibration frequencies and, to a lesser extent, to the different spatial frequencies of the mode shapes. The contribution of each individual mode (or indeed the superposition of several modes) to the dynamic behaviour of the object can then be separated by means of a bandpass filter (or filters). The final output is a sequence of complex-valued maps that contain the full-field temporal history of the selected mode (or modes) in terms of its mechanical amplitude and phase. The proof-of-principle of the technique is demonstrated with a rectangular, fully clamped, thin metal plate vibrating simultaneously in several of its natural resonant frequencies under white-noise excitation.

Published

2009

12. Detection Systems for Scanning Laser Tomoholographic Acoustic Microscopy.

Author

Meyyappan, A., Isakson, S., Mendoza-Santoyo, F., Duarte, R.A., Sahagun, L.R., and Wade, G.

Subjects

IMAGING systems, ACOUSTIC microscopy, ULTRASONIC waves, SOUND waves, INTERFEROMETRY, HOLOGRAPHY

Abstract

A new microscope, called the scanning laser tomoholographic acoustic microscope, will employ three insonifying transducers to obtain holographic projections from three different directions for use in reconstructing tomograms of microscopic objects. To do this, the detection system should detect with equal sensitivity in all directions of propagation the traveling ultrasonic waves that emerge from the object with the image information. Two such laser-beam detectors, the heterodyne detector and the time-delay interferometric detector, have been examined to find the one best suited for rapid data acquisition and direction-insensitive optical computing. Although each has its own advantages and disadvantages, we find the latter more suitable for our purpose. [ABSTRACT FROM AUTHOR]

Published

1996