Add to ORKGIn the field of biomedical optics, optical scattering has traditionally limited the range of imaging within tissue to a depth of one millimetre. A recently developed class of wavefront-shaping techniques now aims to overcome this limit and achieve diffraction-limited control of light beyond one centimetre. By manipulating the spatial profile of an optical field before it enters a scattering medium, it is possible to create a micrometre-scale focal spot deep within tissue. To successfully operate in vivo, these wavefront-shaping techniques typically require feedback from within the biological sample. This Review summarizes recently developed 'guidestar' mechanisms that provide feedback for intra-tissue focusing. Potential applications of gui...
Wave front shaping holds great potential for high-resolution imaging or light delivery either throug...
I will discuss our recent work on the use of digital optical phase conjugation and ultrasound taggin...
Phase distortions due to scattering in random media restrict optical focusing beyond one transport m...
In the field of biomedical optics, optical scattering has traditionally limited the range of imaging...
In the field of biomedical optics, optical scattering has traditionally limited the range of imaging...
Optical scattering has traditionally limited the ability to focus light inside scattering media such...
Noninvasive light focusing deep inside living biological tissue has long been a goal in biomedical o...
New developments in neuroscience are enabling us to understand the brain at unprecedented temporal a...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
Multiple light scattering has been regarded as a barrier in imaging through complex media such as bi...
A novel technique uses ultrasonic encoding and time reversal to break the diffusion limit and enabl...
A novel technique uses ultrasonic encoding and time reversal to break the diffusion limit and enabl...
I will discuss our recent work on the use of digital optical phase conjugation and ultrasound taggin...
Wave front shaping holds great potential for high-resolution imaging or light delivery either throug...
I will discuss our recent work on the use of digital optical phase conjugation and ultrasound taggin...
Phase distortions due to scattering in random media restrict optical focusing beyond one transport m...
In the field of biomedical optics, optical scattering has traditionally limited the range of imaging...
In the field of biomedical optics, optical scattering has traditionally limited the range of imaging...
Optical scattering has traditionally limited the ability to focus light inside scattering media such...
Noninvasive light focusing deep inside living biological tissue has long been a goal in biomedical o...
New developments in neuroscience are enabling us to understand the brain at unprecedented temporal a...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
The problem of optical scattering was long thought to fundamentally limit the depth at which light c...
Multiple light scattering has been regarded as a barrier in imaging through complex media such as bi...
A novel technique uses ultrasonic encoding and time reversal to break the diffusion limit and enabl...
A novel technique uses ultrasonic encoding and time reversal to break the diffusion limit and enabl...
I will discuss our recent work on the use of digital optical phase conjugation and ultrasound taggin...
Wave front shaping holds great potential for high-resolution imaging or light delivery either throug...
I will discuss our recent work on the use of digital optical phase conjugation and ultrasound taggin...
Phase distortions due to scattering in random media restrict optical focusing beyond one transport m...