Adaptive wavefront correction in two-photon microscopy using coherence-gated wavefront sensing

261

388

Neural activity in the brain is followed by localized changes in blood flow and volume. We address the relative change in volume for arteriole vs. venous blood within primary vibrissa cortex of awake, head-fixed mice. Two-photon laser-scanning microscopy was used to measure spontaneous and sensory evoked changes in flow and volume at the level of single vessels. We find that arterioles exhibit slow (<1 Hz) spontaneous increases in their diameter, as well as pronounced dilation in response to both punctate and prolonged stimulation of the contralateral vibrissae. In contrast, venules dilate only in response to prolonged stimulation. We conclude that stimulation that occurs on the time scale of natural stimuli leads to a net increase in the reservoir of arteriole blood. Thus, a "bagpipe" model that highlights arteriole dilation should augment the current "balloon" model of venous distension in the interpretation of fMRI images.ocalized changes in the flow and volume of oxygenated blood in the brain are commonly used as a correlate of heightened neural activity. For two important imaging modalities, blood oxygen level-dependent functional magnetic resonance imaging (BOLD fMRI) (1) and intrinsic optical signal imaging (IOS) (2), the signals are generated by a complex interplay of the rate of oxidative metabolism, the flux of blood in the underlying angioarchitecture, and changes in vascular volume (3). The locus for the increase in vascular volume that follows sensory stimulation (i.e., arterioles or venules) is an enduring controversy that bears directly on interpreting and quantifying fMRI signals (4-6). To resolve this question, we used in vivo two-photon laserscanning microscopy to image spontaneous and sensory evoked vascular dynamics in the vibrissa area of parietal cortex of awake, head-fixed mice. All data were collected through a reinforced thin-skull window (7) (Fig. 1A); this method obviates potential complications from inflammation or changes in cranial pressure that may occur with a craniotomy (8). ResultsImages of the pial surface and measurements of the diameter of the lumen of surface arterioles and venules were performed while the mouse sat passively (Fig. 1B). Dilations greater than 5% of the baseline diameter occurred with frequencies of 0.07 ± 0.05 Hz (mean ± SD, n = 118 arteries in six mice). The diameters of short segments of arterioles (red in Fig. 1B) exhibited relatively large spontaneous increases in the spectral range between 0.1 Hz and 1 Hz ( Fig. 1 C and D). The peak amplitude of these fluctuations was 23% ± 10% of the initial vessel diameter across all arterioles, with instances of a 50% increases in diameter. Further, these lowfrequency oscillations were strongly coherent and synchronous over a distance of several hundred micrometers across cortex (198 pairs of vessels, in six mice, that were separated by 20-315 μm; slope of coherence = 0.001 μm −1 [nonsignificant (NS)] and slope of phase shift = 0.0009 rad/μm

Section: Discussionmentioning

confidence: 99%

Fluctuating and sensory-induced vasodynamics in rodent cortex extend arteriole capacity

Drew

Shih

Kleinfeld

2011

261

388

“…Measuring and compensating for wavefront distortions lie within the realm of optical phase conjugation (OPC) (22) and adaptive optics (AO) (8,17,23,24). The challenging task is to combine effectively well-established wavefront compensation techniques with deep tissue microscopy.…”

mentioning

confidence: 99%

Superpenetration optical microscopy by iterative multiphoton adaptive compensation technique

Tang

Germain

Cui

2012

211

178

Biological tissues are rarely transparent, presenting major challenges for deep tissue optical microscopy. The achievable imaging depth is fundamentally limited by wavefront distortions caused by aberration and random scattering. Here, we report an iterative wavefront compensation technique that takes advantage of the nonlinearity of multiphoton signals to determine and compensate for these distortions and to focus light inside deep tissues. Different from conventional adaptive optics methods, this technique can rapidly measure highly complicated wavefront distortions encountered in deep tissue imaging and provide compensations for not only aberration but random scattering. The technique is tested with a variety of highly heterogeneous biological samples including mouse brain tissue, skull, and lymph nodes. We show that high quality three-dimensional imaging can be realized at depths beyond the reach of conventional multiphoton microscopy and adaptive optics methods, albeit over restricted distances for a given correction. Moreover, the required laser excitation power can be greatly reduced in deep tissues, deviating from the power requirement of ballistic light excitation and thus significantly reducing photo damage to the biological tissue.immunology | neuron imaging | nonlinear imaging | lymphocyte imaging | nonlinear iterative feedback

“…For one, it is not possible to place the wavefront sensor past the aberrating medium, which in this case would still be within the brain. Other approaches where the wavefront of the light reflected from the sample is directly measured are limited, because the strong scattering of light in brain tissue scrambles the information in the reflected wavefront (9,10).…”

mentioning

confidence: 99%

Characterization and adaptive optical correction of aberrations during in vivo imaging in the mouse cortex

Satō

Betzig

2011

183

158

The signal and resolution during in vivo imaging of the mouse brain is limited by sample-induced optical aberrations. We find that, although the optical aberrations can vary across the sample and increase in magnitude with depth, they remain stable for hours. As a result, two-photon adaptive optics can recover diffraction-limited performance to depths of 450 μm and improve imaging quality over fields of view of hundreds of microns. Adaptive optical correction yielded fivefold signal enhancement for small neuronal structures and a threefold increase in axial resolution. The corrections allowed us to detect smaller neuronal structures at greater contrast and also improve the signal-to-noise ratio during functional Ca 2 imaging in single neurons.T he ability to visualize biological systems in vivo has been a major attraction of optical microscopy, because studying biological systems as they evolve in their natural, physiological state provides relevant information that in vitro preparations often do not allow (1). However, for conventional optical microscopes to achieve their optimal, diffraction-limited resolution, the specimen needs to have identical optical properties to those of the immersion media for which the microscope objective is designed. For example, one of the most widely applied microscopy techniques for in vivo imaging, two-photon fluorescence microscopy, often uses water-dipping objectives. Because biological samples are comprised of structures (i.e., proteins, nuclear acids, and lipids) with refractive indices different from that of water, they induce optical aberrations to the incoming excitation wave and result in an enlarged focal spot within the sample and a concomitant deterioration of signal and resolution (2, 3). As a result, the resolution and contrast of optical microscopes is compromised in vivo, especially deep in tissue.Many questions related to how the brain processes information on both the neuronal circuit level and the cell biological level can be addressed by observing the morphology and activity of neurons inside a living and, preferably, awake and behaving mouse (1). In a typical experiment, an area of the skull is surgically removed and replaced with a cover glass to provide optical access to the underlying structure of interest (4). For imaging during behavior, the cover glass is often attached to an optically transparent plug embedded in the skull to improve mechanical stability and to prevent the skull from growing back and blocking the optical access (5, 6) (Fig. 1A). Before the excitation light of a two-photon microscope reaches the desired focal plane inside the brain, it has to traverse first the cranial window and then the brain tissue, both with optical properties different from water. Thus, they both impart optical aberrations on the excitation light, which leads to a distorted focus, even at the surface of the brain.These sample-induced aberrations can be corrected with adaptive optics (AO) to recover diffraction-limited resolution. In AO, a wavefront-shaping device m...