| Nome |
# |
|
Diffuse optical characterization of collagen absorption from 500 to 1700 nm, file e0c31c0a-6b53-4599-e053-1705fe0aef77
|
526
|
|
A Compact Two-Wavelength Time-Domain NIRS System Based on SiPM and Pulsed Diode Lasers, file e0c31c0b-9a5d-4599-e053-1705fe0aef77
|
514
|
|
Memory effect in silicon time-gated single-photon avalanche diodes, file e0c31c08-ec1a-4599-e053-1705fe0aef77
|
487
|
|
Solid phantom recipe for diffuse optics in biophotonics applications: A step towards anatomically correct 3D tissue phantoms, file e0c31c0f-0027-4599-e053-1705fe0aef77
|
351
|
|
Time domain functional NIRS imaging for human brain mapping, file e0c31c09-4231-4599-e053-1705fe0aef77
|
344
|
|
Performance assessment of time-domain optical brain imagers, part 1: basic instrumental performance protocol, file e0c31c09-52e1-4599-e053-1705fe0aef77
|
324
|
|
Characterization of a time-resolved non-contact scanning diffuse optical imaging system exploiting fast-gated single-photon avalanche diode detection, file e0c31c0a-7579-4599-e053-1705fe0aef77
|
306
|
|
Time-resolved single-photon detection module based on silicon photomultiplier: A novel building block for time-correlated measurement systems, file e0c31c0a-77d4-4599-e053-1705fe0aef77
|
301
|
|
Criteria for the design of tissue-mimicking phantoms for the standardization of biophotonic instrumentation, file 2fa95dc4-2ca5-4335-8431-eae29dd18066
|
290
|
|
New frontiers in time-domain diffuse optics, a review, file e0c31c09-f35a-4599-e053-1705fe0aef77
|
290
|
|
Novel technologies for time-domain diffuse optics: Miniaturized wearable devices and bioresorbable optical fibers, file e0c31c0c-9adf-4599-e053-1705fe0aef77
|
260
|
|
Time-resolved diffused optical characterization of key tissue constituents of human bony prominence locations, file e0c31c09-5fae-4599-e053-1705fe0aef77
|
254
|
|
Solid switchable phantom for diffuse optical imaging, file e0c31c09-52eb-4599-e053-1705fe0aef77
|
250
|
|
Design and construction of a solid switchable phantom for diffuse optical imaging, file e0c31c09-52f1-4599-e053-1705fe0aef77
|
234
|
|
Toward noninvasive assessment of flap viability with time-resolved diffuse optical tomography: a preclinical test on rats, file e0c31c09-49ea-4599-e053-1705fe0aef77
|
231
|
|
In-vivo multilaboratory investigation of the optical properties of the human head, file e0c31c09-6065-4599-e053-1705fe0aef77
|
229
|
|
Mechanically switchable solid inhomogeneous phantom for performance tests in diffuse imaging and spectroscopy, file e0c31c09-4bcd-4599-e053-1705fe0aef77
|
225
|
|
Collagen content as a risk factor in breast cancer? A pilot clinical study, file e0c31c09-52ef-4599-e053-1705fe0aef77
|
222
|
|
Towards next generation time-domain diffuse optics devices, file e0c31c08-73a2-4599-e053-1705fe0aef77
|
221
|
|
Bimodal ultrasonic probe comprising an optical device for diagnosis, file e0c31c10-ffd7-4599-e053-1705fe0aef77
|
221
|
|
In vivo time domain broadband (600-1200 nm) diffuse optical characterization of human bone, file e0c31c0b-a713-4599-e053-1705fe0aef77
|
214
|
|
In vivo Study of the Layered Structure on the Abdomen by Broadband Time-Domain Diffuse Optical Spectroscopy, file e0c31c0b-e630-4599-e053-1705fe0aef77
|
206
|
|
Optical Quantification of Collagen and Breast Cancer: Lesion Classification and Risk Estimate, file e0c31c0c-25b4-4599-e053-1705fe0aef77
|
205
|
|
Optical study on the dependence of breast tissue composition and structure on subject anamnesis, file e0c31c09-4f3f-4599-e053-1705fe0aef77
|
200
|
|
Breast tissue composition and its dependence on demographic risk factors for breast cancer: Non-invasive assessment by Time Domain diffuse optical spectroscopy, file e0c31c08-c891-4599-e053-1705fe0aef77
|
194
|
|
Optical Characterization of Benign and Malignant Breast Lesions by Perturbative Model, file e0c31c09-9f00-4599-e053-1705fe0aef77
|
188
|
|
Bioresorbable fibers for time-domain diffuse optical measurements: a step toward next generation optical implantable devices, file e0c31c0f-228c-4599-e053-1705fe0aef77
|
188
|
|
Spectrally Resolved Single-Photon Timing of Silicon Photomultipliers for Time-Domain Diffuse Spectroscopy, file e0c31c08-e250-4599-e053-1705fe0aef77
|
186
|
|
Noninvasive optical estimation of CSF thickness for brain-atrophy monitoring, file e0c31c0c-471b-4599-e053-1705fe0aef77
|
180
|
|
Frequency Offset Raman Spectroscopy (FORS) for subsurface probing of highly scattering media, file e0c31c0c-58ee-4599-e053-1705fe0aef77
|
180
|
|
Light diffusion in quenched disorder: Role of step correlations, file e0c31c08-25a6-4599-e053-1705fe0aef77
|
177
|
|
Time domain diffuse optical spectroscopy: In vivo quantification of collagen in breast tissue, file e0c31c09-54f7-4599-e053-1705fe0aef77
|
175
|
|
Characterization of homogeneous tissue phantoms for performance tests in diffuse optics, file e0c31c0a-8ff2-4599-e053-1705fe0aef77
|
174
|
|
In vivo depth heterogeneity of the abdomen assessed by broadband time-domain diffuse optical spectroscopy, file e0c31c0c-a33b-4599-e053-1705fe0aef77
|
174
|
|
Fiber-based hybrid probe for non-invasive cerebral monitoring in neonatology, file e0c31c09-50e3-4599-e053-1705fe0aef77
|
171
|
|
Large area SiPM and high throughput timing electronics: toward new generation time-domain instruments, file e0c31c0e-7a93-4599-e053-1705fe0aef77
|
171
|
|
Large area silicon photomultipliers allow extreme depth penetration in time-domain diffuse optics, file e0c31c0a-7358-4599-e053-1705fe0aef77
|
170
|
|
Effects of time-gated detection in diffuse optical imaging at short source-detector separation, file e0c31c08-287a-4599-e053-1705fe0aef77
|
169
|
|
Optical discrimination between malignant and benign breast lesions, file e0c31c09-52ed-4599-e053-1705fe0aef77
|
169
|
|
Is collagen an independent risk factor for breast cancer?, file e0c31c0b-87c9-4599-e053-1705fe0aef77
|
167
|
|
Frequency offset Raman spectroscopy (FORS) for depth probing of diffusive media, file e0c31c0a-7039-4599-e053-1705fe0aef77
|
166
|
|
The LUCA project - Laser and ultrasound co-analyzer for thyroid nodules: Overview and current status, file e0c31c0e-ffab-4599-e053-1705fe0aef77
|
162
|
|
Wearable and wireless time-domain near-infrared spectroscopy system for brain and muscle hemodynamic monitoring, file e0c31c10-6c5c-4599-e053-1705fe0aef77
|
160
|
|
The SiPM revolution in time-domain diffuse optics, file e0c31c0f-c86c-4599-e053-1705fe0aef77
|
156
|
|
Optical identification of subjects at high risk for developing breast cancer, file e0c31c09-4eaa-4599-e053-1705fe0aef77
|
155
|
|
A Tool for quantitative and systematic simulation of diffuse optical tomography with a limited number of fixed sources and detectors, file e0c31c0e-7fae-4599-e053-1705fe0aef77
|
155
|
|
How should the new generation of detectors for diffuse optics be? A systematic simulation study, file e0c31c0e-7303-4599-e053-1705fe0aef77
|
154
|
|
A recipe for near infrared spectroscopy and diffuse correlation spectroscopy phantoms with tunable optical and dynamic properties, file e0c31c0f-0416-4599-e053-1705fe0aef77
|
154
|
|
Broadband time domain diffuse optical reflectance spectroscopy: a review of systems, methods, and applications, file e0c31c0e-d129-4599-e053-1705fe0aef77
|
152
|
|
Study of optimal measurement conditions for time-domain diffuse optics systems, file e0c31c0e-851f-4599-e053-1705fe0aef77
|
149
|
|
Performance assessment of time-domain optical brain imagers, part 2: nEUROPt protocol, file e0c31c08-4dd0-4599-e053-1705fe0aef77
|
147
|
|
Multiple-view diffuse optical tomography system based on time-domain compressive measurements, file e0c31c0b-7ab1-4599-e053-1705fe0aef77
|
147
|
|
In vivo, depth resolved measurement of blood flow with time domain diffuse correlation spectroscopy, file e0c31c0e-e2c3-4599-e053-1705fe0aef77
|
147
|
|
A wearable time domain near-infrared spectroscopy system, file e0c31c0e-f375-4599-e053-1705fe0aef77
|
147
|
|
Effects of temporal gating in time domain diffuse correlation spectroscopy for real systems, file e0c31c0e-f2fe-4599-e053-1705fe0aef77
|
143
|
|
Broadband (550-1350 nm) diffuse optical characterization of thyroid chromophores, file e0c31c0c-4446-4599-e053-1705fe0aef77
|
142
|
|
In vivo time domain speckle contrast optical spectroscopy, file e0c31c0f-2287-4599-e053-1705fe0aef77
|
142
|
|
Time-domain diffuse optical tomography using silicon photomultipliers: feasibility study, file e0c31c0a-038d-4599-e053-1705fe0aef77
|
137
|
|
Quantification in time-domain diffuse optical tomography using mellin-laplace transforms, file e0c31c09-f3a7-4599-e053-1705fe0aef77
|
131
|
|
BabyLux device: a diffuse optical system integrating diffuse correlation spectroscopy and time-resolved near-infrared spectroscopy for the neuromonitoring of the premature newborn brain, file e0c31c0e-e98d-4599-e053-1705fe0aef77
|
130
|
|
Fast silicon photomultiplier improves signal harvesting and reduces complexity in time-domain diffuse optics, file e0c31c08-ec1e-4599-e053-1705fe0aef77
|
129
|
|
Miniaturized pulsed laser source for time-domain diffuse optics routes to wearable devices, file e0c31c0b-68e5-4599-e053-1705fe0aef77
|
129
|
|
Depth sensitivity of frequency domain optical measurements in diffusive media, file e0c31c0c-7090-4599-e053-1705fe0aef77
|
129
|
|
Instrumental, optical and geometrical parameters affecting time-gated diffuse optical measurements: a systematic study, file e0c31c0e-8516-4599-e053-1705fe0aef77
|
129
|
|
Functional monitoring of lung tissue using a hybrid hyperspectral Time-Resolved GASMAS system: A systematic study on ex vivo sample, file e0c31c10-4b0d-4599-e053-1705fe0aef77
|
128
|
|
Phantoms for diffuse optical imaging based on totally absorbing objects, part 2: experimental implementation, file e0c31c08-344b-4599-e053-1705fe0aef77
|
126
|
|
Non-invasive optical estimate of tissue composition to differentiate malignant from benign breast lesions: A pilot study, file e0c31c0a-42f6-4599-e053-1705fe0aef77
|
124
|
|
Large-Area, Fast-Gated Digital SiPM with Integrated TDC for Portable and Wearable Time-Domain NIRS, file e0c31c10-4dbd-4599-e053-1705fe0aef77
|
123
|
|
Broadband extraction of tissue optical properties using a portable hybrid time-resolved continuous wave instrumentation: Characterization of ex vivo organs, file e0c31c10-4312-4599-e053-1705fe0aef77
|
121
|
|
In Vivo, non-invasive characterization of human bone by hybrid broadband (600-1200 nm) diffuse optical and correlation spectroscopies, file e0c31c0a-6fdd-4599-e053-1705fe0aef77
|
119
|
|
Estimate of tissue composition in malignant and benign breast lesions by time-domain optical mammography, file e0c31c09-4d0c-4599-e053-1705fe0aef77
|
117
|
|
Solid heterogeneous phantoms for multimodal ultrasound and diffuse optical imaging: an outcome of the SOLUS project for standardization, file e0c31c0e-f99d-4599-e053-1705fe0aef77
|
115
|
|
There's plenty of light at the bottom: Statistics of photon penetration depth in random media, file e0c31c09-e984-4599-e053-1705fe0aef77
|
112
|
|
Spatial resolution in depth for time-resolved diffuse optical tomography using short source-detector separations, file e0c31c08-23e5-4599-e053-1705fe0aef77
|
109
|
|
Time-domain functional diffuse optical tomography system based on fiber-free silicon photomultipliers, file e0c31c0b-8356-4599-e053-1705fe0aef77
|
107
|
|
Probe-hosted large area silicon photomultiplier and high-throughput timing electronics for enhanced performance time-domain functional near-infrared spectroscopy, file e0c31c10-5796-4599-e053-1705fe0aef77
|
107
|
|
A Versatile Setup for Time-Resolved Functional Near Infrared Spectroscopy Based on Fast-Gated Single-Photon Avalanche Diode and on Four-Wave Mixing Laser, file e0c31c0e-fe05-4599-e053-1705fe0aef77
|
105
|
|
Non-contact scanning time-domain functional optical imaging of the adult human brain, file e0c31c09-573e-4599-e053-1705fe0aef77
|
103
|
|
Determination of reference values for optical properties of liquid phantoms based on Intralipid and India ink, file e0c31c08-3201-4599-e053-1705fe0aef77
|
102
|
|
Broadband (600-1100 nm) diffuse optical characterization of thyroid tissue constituents and application to in vivo thyroid studies, file e0c31c0c-4162-4599-e053-1705fe0aef77
|
102
|
|
Strategic research agenda for biomedical imaging, file e0c31c0f-0033-4599-e053-1705fe0aef77
|
100
|
|
Time-Gated single-photon detection in time-domain diffuse optics: A review, file e0c31c0f-c79a-4599-e053-1705fe0aef77
|
100
|
|
Time-domain diffuse optics using bioresorbable fibers: A proof-of-principle study, file e0c31c0b-ece6-4599-e053-1705fe0aef77
|
99
|
|
Time-domain diffuse optics with 8.6 mm2 fast-gated SiPM for extreme light harvesting, file e0c31c11-9a4b-4599-e053-1705fe0aef77
|
98
|
|
Multi Simulation Platform for Time Domain Diffuse Optical Tomography: An Application to a Compact Hand-Held Reflectance Probe, file e0c31c0f-1ff3-4599-e053-1705fe0aef77
|
95
|
|
Effects of the instrument response function and the gate width in time-domain diffuse correlation spectroscopy: Model and validations, file e0c31c0f-2d9a-4599-e053-1705fe0aef77
|
94
|
|
Depth dependence of estimated optical properties of a scattering inclusion by time-resolved contrast functions, file e0c31c0c-31b1-4599-e053-1705fe0aef77
|
93
|
|
Probe-hosted silicon photomultipliers for time-domain functional near-infrared spectrscopy: phantom and in vivo tests, file e0c31c0a-9381-4599-e053-1705fe0aef77
|
91
|
|
A wearable time domain near infrared spectroscopy system, file e0c31c10-023c-4599-e053-1705fe0aef77
|
89
|
|
Broadband diffuse optical characterization of elastin for biomedical applications, file e0c31c0c-6b2c-4599-e053-1705fe0aef77
|
84
|
|
Towards next-generation time-domain diffuse optics for extreme depth penetration and sensitivity, file e0c31c08-7349-4599-e053-1705fe0aef77
|
75
|
|
Broadband (600-1350 nm) Time-Resolved Diffuse Optical Spectrometer for Clinical Use, file e0c31c09-f6a5-4599-e053-1705fe0aef77
|
68
|
|
Time-resolved laser spectroscopy for the in situ characterization of methacrylate monomer flow within spruce, file e0c31c0a-70c3-4599-e053-1705fe0aef77
|
68
|
|
Time domain diffuse Raman spectrometer based on a TCSPC camera for the depth analysis of diffusive media, file e0c31c0c-317f-4599-e053-1705fe0aef77
|
68
|
|
The LUCA device: laser and ultrasound co-analyzer for thyroid nodules, file e0c31c0e-d1dd-4599-e053-1705fe0aef77
|
68
|
|
Time-resolved diffuse optical tomography for non-invasive flap viability assessment: Pre-clinical tests on rats, file e0c31c09-4468-4599-e053-1705fe0aef77
|
65
|
|
Spectral approach to time domain diffuse optical tomography for breast cancer: validation on meat phantoms, file e0c31c0e-ba58-4599-e053-1705fe0aef77
|
65
|
|
Towards the use of bioresorbable fibers in time-domain diffuse optics, file e0c31c0e-c254-4599-e053-1705fe0aef77
|
64
|
|
Monitoring the motor cortex hemodynamic response function in freely moving walking subjects: A time-domain fNIRS pilot study, file e0c31c11-25c2-4599-e053-1705fe0aef77
|
63
|
|
Time resolved diffuse optical spectroscopy with geometrically accurate models for bulk parameter recovery, file e0c31c09-eb42-4599-e053-1705fe0aef77
|
62
|
| Totale |
16.659 |