James Germann scite author profile

We report high sensitivity detection and tracking of a single fluorescent nanoparticle in solution by use of four alternately pulsed laser diodes for fluorescence excitation in a confocal microscope. Slight offsets between the centers of the overlapping laser foci together with time-resolved photon counting enable sub-micron precision position measurements. Real-time correction for diffusional motion with a xyz-piezo stage then enables tracking of a nanoparticle with diffusivity up to ~12 μm(2) s(-1). Fluorescence correlation spectroscopy and calibration measurements indicate a net fluorescence photon detection efficiency of ~6-9%, comparable to that of an optimized single-molecule microscope.

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Multi-meridian corneal imaging of air-puff induced deformation for improved detection of biomechanical abnormalities

Curatolo¹,

Birkenfeld²,

Martinez-Enriquez³

et al. 2020

Biomed. Opt. Express

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Corneal biomechanics play a fundamental role in the genesis and progression of corneal pathologies, such as keratoconus; in corneal remodeling after corneal surgery; and in affecting the measurement accuracy of glaucoma biomarkers, such as the intraocular pressure (IOP). Air-puff induced corneal deformation imaging reveals information highlighting normal and pathological corneal response to a non-contact mechanical excitation. However, current commercial systems are limited to monitoring corneal deformation only on one corneal meridian. Here, we present a novel custom-developed swept-source optical coherence tomography (SSOCT) system, coupled with a collinear air-puff excitation, capable of acquiring dynamic corneal deformation on multiple meridians. Backed by numerical simulations of corneal deformations, we propose two different scan patterns, aided by low coil impedance galvanometric scan mirrors that permit an appropriate compromise between temporal and spatial sampling of the corneal deformation profiles. We customized the air-puff module to provide an unobstructed SSOCT field of view and different peak pressures, air-puff durations, and distances to the eye. We acquired multi-meridian corneal deformation profiles (a) in healthy human eyes in vivo, (b) in porcine eyes ex vivo under varying controlled IOP, and (c) in a keratoconus-mimicking porcine eye ex vivo. We detected deformation asymmetries, as predicted by numerical simulations, otherwise missed on a single meridian that will substantially aid in corneal biomechanics diagnostics and pathology screening.

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Quantization of collagen organization in the stroma with a new order coefficient

Germann¹,

Martinez-Enriquez²,

Marcos³

2017

Biomed. Opt. Express

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Many optical and biomechanical properties of the cornea, specifically the transparency of the stroma and its stiffness, can be traced to the degree of order and direction of the constituent collagen fibers. To measure the degree of order inside the cornea, a new metric, the order coefficient, was introduced to quantify the organization of the collagen fibers from images of the stroma produced with a custom-developed second harmonic generation microscope. The order coefficient method gave a quantitative assessment of the differences in stromal collagen arrangement across the cornea depths and between untreated stroma and cross-linked stroma.

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Corneal Collagen Ordering After In Vivo Rose Bengal and Riboflavin Cross-Linking

Germann

Martinez-Enriquez

Martínez‐García

et al. 2020

Invest. Ophthalmol. Vis. Sci.

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Photoactivated cornea collagen cross-linking (CXL) increases corneal stiffness by initiating formation of covalent bonds between stromal proteins. Because CXL depends on diffusion to distribute the photoinitiator, a gradient of CXL efficiency with depth is expected that may affect the degree of stromal collagen organization. We used second harmonic generation (SHG) microscopy to investigate the differences in stromal collagen organization in rabbit eyes after corneal CXL in vivo as a function of depth and time after surgery. METHODS. Rabbit corneas were treated in vivo with either riboflavin/UV radiation (UVX) or Rose Bengal/green light (RGX) and evaluated 1 and 2 months after CXL. Collagen fibers were imaged with a custom-built SHG scanning microscope through the central cornea (350 μm depth, 225 × 225 μm en face images). The order coefficient (OC), a metric for collagen organization, and total SHG signal were computed for each depth and compared between treatments. RESULTS. OC values of CXL-treated corneas were larger than untreated corneas by 27% and 20% after 1 month and 38% and 33% after 2 months for the RGX and UVX, respectively. RGX OC values were larger than UVX OC values by 3% and 5% at 1 and 2 months. The SHG signal was higher in CXL corneas than untreated corneas, both at 1 and 2 months after surgery, by 18% and 26% and 1% and 10% for RGX and UVX, respectively. CONCLUSIONS. Increased OC corresponded with increased collagen fiber organization in CXL corneas. Changes in collagen organization parallel reported temporal changes in cornea stiffness after CXL and also, surprisingly, are detected deeper in the stroma than the regions stiffened by collagen cross-links.

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Design and ex situ performance of a shape-changing accommodating intraocular lens

Hoz

Germann

Martinez-Enriquez

et al. 2019

Optica

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Presbyopia, the age-related loss of the crystalline lens's ability to dynamically focus, occurs primarily because of stiffening of lens material, making the ciliary muscle forces insufficient to reshape the lens. Despite its prevalence, there is no satisfactory solution to presbyopia. Here we present a novel accommodating intraocular lens (AIOL) able to reshape upon equatorial forces in compliance with the eye's accommodating mechanism. The concept and design parameters are demonstrated through finite element model simulations and measurements in a manufactured AIOL prototype, using custom quantitative 3D OCT (geometrical changes) and laser ray tracing (power changes), with forces radially applied using a custom eight-arm mechanical stretcher. There was an excellent agreement between simulations and measurements (1% for the focal length and 11.4% for geometrical parameters, on average) for radial load up to 0.6 N. The developed design is expected to achieve ∼2.5D of effective power change with a polymer material with 0.10-0.25 MPa Young's modulus and n 1.43 − 1.46.

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James Germann

Three-dimensional tracking of a single fluorescent nanoparticle using four-focus excitation in a confocal microscope

Multi-meridian corneal imaging of air-puff induced deformation for improved detection of biomechanical abnormalities

Quantization of collagen organization in the stroma with a new order coefficient

Corneal Collagen Ordering After In Vivo Rose Bengal and Riboflavin Cross-Linking

Design and ex situ performance of a shape-changing accommodating intraocular lens

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