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Preictal and Ictal Neurovascular and Metabolic Coupling Surrounding a Seizure Focus

Mingrui Zhao, John Nguyen, Hongtao Ma, Nozomi Nishimura, Chris B. Schaffer, and Theodore H. Schwartz

The Journal of Neuroscience (2011)

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Epileptic events initiate a large focal increase in metabolism and cerebral blood flow (CBF) to the ictal focus. In contrast, decreases in CBF have been demonstrated surrounding the focus, the etiology of which is unknown (i.e., arising either from active shunting of blood or passive steal). The relationship between these events and neuronal activity and metabolism are also unknown. We investigated neuro- vascular and neurometabolic coupling in the ictal surround using optical imaging of light scattering and cerebral blood volume, auto- fluorescence flavoprotein imaging (AFI), direct measurements of the cortical metabolic rate of oxygen and two-photon imaging of blood vessel diameter in a rat model of ictal events elicited with focal injection of 4-aminopyridine. We discovered a novel phenomenon, in which ictal events are preceded by preictal vasoconstriction of blood vessels in the surround, occurring 1–5 s before seizure onset, which may serve to actively shunt oxygenated blood to the imminently hypermetabolic focus or may be due to small local decreases in metab- olism in the surround. Early ictal hypometabolism, transient decreases in cell swelling and cerebral blood volume in the surround are consistent with early ictal surround inhibition as a precipitating event in seizure onset as well as shaping the evolving propagating ictal wavefront, although the exact mechanism of these cerebrovascular and metabolic changes is currently unknown. AFI was extremely sensitive to the ictal onset zone and may be a useful mapping technique with clinical applications.

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Sub-surface, micrometer-scale incisions produced in rodent cortex using tightly-focused femtosecond laser pulses

John Nguyen, Jillian Ferdman, Mingrui Zhou, David Huland, Shatha Saqqa, Jan Ma, Nozomi Nishimura, Theodore H. Schwartz, and Chris B. Schaffer

Lasers in Surgery and Medicine (2011)

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Background and Objective: Techniques that allow tar- geted, micrometer-scale disruption in the depths of bio- logical tissue, without affecting overlying structures or causing significant collateral damage, could potentially lead to new surgical procedures. We describe an optical technique to make sub-surface incisions in in vivo rodent brain and characterize the relationship between the cut width and maximum depth of these optical transections as a function of laser energy. Materials and Methods: To produce cuts, high inten- sity, femtosecond laser pulses were tightly focused into and translated within the cortex, through a craniotomy, in anesthetized rodents. Imaging of stained brain slices was used to characterize cut width and maximum cutting depth. Results: Cut width decreased exponentially as a function of depth and increased as the cube root of laser energy, but showed about 50% variation at fixed depth and laser energy. For example, at a laser energy of 13 mJ, cut width decreased from 158 ` 43.1 mm (mean ` standard deviation) to 56 ` 33 mm over depths of approximately 200–800 mm, respectively. Maximal cut depth increased logarithmically with laser energy, with cut depths of up to 1 mm achieved with 13 mJ pulses. We further show- cased this technique by selectively cutting sub-surface cortical dendrites in a live, anesthetized transgenic mouse. Conclusions: Femtosecond laser pulses provide the nov- el capacity for precise, sub-surface, cellular-scale cuts for surgical applications in optically scattering tissues.

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Limitations of collateral flow after occlusion of a single cortical penetrating arteriole

Nozomi Nishimura*, Nathanael L Rosidi*, Costantino Iadecola and Chris B Schaffer

Journal of Cerebral Blood Flow & Metabolism (2010)

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Occlusions of penetrating arterioles, which plunge into cortex and feed capillary beds, cause severe decreases in blood flow and are potential causes of ischemic microlesions. However, surrounding arterioles and capillary beds remain flowing and might provide collateral flow around the occlusion. We used femtosecond laser ablation to trigger clotting in single penetrating arterioles in rat cortex and two-photon microscopy to measure changes in microvessel diameter and red blood cell speed after the clot. We found that after occlusion of a single penetrating arteriole, nearby penetrating and surface arterioles did not dilate, suggesting that alternate blood flow routes are not actively recruited. In contrast, capillaries showed two types of reactions. Capillaries directly downstream from the occluded arteriole dilated after the clot, but other capillaries in the same vicinity did not dilate. This heterogeneity in capillary response suggests that signals for vasodilation are vascular rather than parenchymal in origin. Although both neighboring arterioles and capillaries dilated in response to topically applied acetylcholine after the occlusion, the flow in the territory of the occluded arteriole did not improve. Collateral flow from neighboring penetrating arterioles is neither actively recruited nor effective in improving blood flow after the occlusion of a single penetrating arteriole.

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Two-photon microscopy-guided femtosecond-laser photoablation of avian cardiogenesis: noninvasive creation of localized heart defects

Huseyin C. Yalcin, Akshay Shekhar, Nozomi Nishimura, Ajinkya A. Rane, Chris B. Schaffer, and Jonathan T. Butcher

Am J Physiol Heart Circ Physiol (2010)

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Embryonic heart formation is driven by complex feedback between genetic and hemodynamic stimuli. Clinical congenital heart defects (CHD), however, often manifest as localized microtissue malformations with no underlying genetic mutation, suggesting that altered hemodynamics during embryonic development may play a role. An investigation of this relationship has been impaired by a lack of experimental tools that can create locally targeted cardiac perturbations. Here we have developed noninvasive optical techniques that can modulate avian cardiogenesis to dissect relationships between alterations in mechanical signaling and CHD. We used two-photon excited fluorescence microscopy to monitor cushion and ventricular dynamics and femtosecond pulsed laser photoablation to target micrometer-sized volumes inside the beating chick hearts. We selectively photoablated a small (100 m radius) region of the superior atrioventricular (AV) cushion in Hamburger- Hamilton 24 chick embryos. We quantified via ultrasound that the disruption causes AV regurgitation, which resulted in a venous pooling of blood and severe arterial constriction. At 48 h postablation, quantitative X-ray microcomputed tomography imaging demonstrated stunted ventricular growth and pronounced left atrial dilation. A histological analysis demonstrated that the laser ablation produced defects localized to the superior AV cushion: a small quasispherical region of cushion tissue was completely obliterated, and the area adjacent to the myocardial wall was less cellularized. Both cushions and myocardium were significantly smaller than sham-operated controls. Our results highlight that two-photon excited fluorescence coupled with femtosecond pulsed laser photoablation should be considered a powerful tool for studying hemodynamic signaling in cardiac morphogenesis through the creation of localized microscale defects that may mimic clinical CHD

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Deep tissue multiphoton microscopy using longer wavelength excitation

Demirhan Kobat, Michael E. Durst, Nozomi Nishimura, Angela W. Wong, Chris B. Schaffer, and Chris Xu

Optics Express (2009)

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We compare the maximal two-photon fluorescence microscopy (TPM) imaging depth achieved with 775-nm excitation to that achieved with 1280-nm excitation through in vivo and ex vivo TPM of fluorescently-labeled blood vessels in mouse brain. We achieved high contrast imaging of blood vessels at approximately twice the depth with 1280-nm excitation as with 775-nm excitation. An imaging depth of 1 mm can be achieved in in vivo imaging of adult mouse brains at 1280 nm with approximately 1-nJ pulse energy at the sample surface. Blood flow speed measurements at a depth of 900 µm are performed.

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Flexible microfluidic devices supported by biodegradable insertion scaffolds for convection-enhanced neural drug delivery

Conor P. Foley, Nozomi Nishimura, Keith B. Neeves, Chris B. Schaffer, and William L. Olbricht

Biomed Microdevices (2009)

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Convection enhanced delivery (CED) can improve the spatial distribution of drugs delivered directly to the brain. In CED, drugs are infused locally into tissue through a needle or catheter inserted into brain parenchyma. Transport of the infused material is dominated by convection, which enhances drug penetration into tissue compared with diffusion mediated delivery. We have fabricated and characterized an implantable microfluidic device for chronic convection enhanced delivery protocols. The device consists of a flexible parylene-C microfluidic channel that is supported during its insertion into tissue by a biodegradable poly(DL-lactide-co-glycolide) scaffold. The scaffold is designed to enable tissue penetration and then erode over time, leaving only the flexible channel implanted in the tissue. The device was able to reproducibly inject fluid into neural tissue in acute experiments with final infusate distributions that closely approximate delivery from an ideal point source. This system shows promise as a tool for chronic CED protocols.

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Light and Matter Interactions: Going with the Grain

Chris B. Schaffer

Nature Photonics (2008)

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Non-reciprocal optical phenomena — effects that depend on the direction of light propagation —are rare. Researchers have now observed non-reciprocal material modification when moving a beam of ultrashort light pulses through a lithium niobate crystal.

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Large two-photon absorptivity of hemoglobin in the infrared range of 780-880 nm

G. Omar Clay, Chris B. Schaffer, and David Kleinfeld

Journal of Chemical Physics (2007)

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Porphyrin molecules have a highly conjugated cyclic structure and are theorized to have unusually large two-photon absorptivities (σTPA), i.e., σTPA ~ 10^2 GM. The authors tested this claim. Ultrafast two-photon absorption (TPA) spectroscopy was performed on solutions of hemoglobin, which contains a naturally occurring metaloporphyrin. They used a pump-probe technique to directly detect the change in transmission induced by TPA over the wavelength range of λ0=780–880 nm. As controls, they measured the TPA of the dyes rhodamine 6G and B; their measurements both verify and extend previously reported values. In new results, hemoglobin was found to have a peak two-photon absorptivity of σTPA~150 GM at λ0=825 nm, near a resonance of the Soret band. This value supports theoretical expectations. They also found a significant difference in the TPA of carboxyhemoglobin versus oxyhemoglobin, e.g., σTPA=61 GM versus σTPA=18 GM, respectively, at λ0=850 nm, which shows that the ligand affects the electronic states involved in TPA.

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Penetrating arterioles are a bottleneck in the perfusion of neocortex

Nozomi Nishimura, Chris B. Schaffer, Beth Friedman, Patrick D. Lyden, and David Kleinfeld

Proceedings of the National Academy of Sciences (2007)

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Penetrating arterioles bridge the mesh of communicating arterioles on the surface of cortex with the subsurface microvascular bed that feeds the underlying neural tissue. We tested the conjecture that penetrating arterioles, which are positioned to regulate the delivery of blood, are loci of severe ischemia in the event of occlusion. Focal photothrombosis was used to occlude single penetrating arterioles in rat parietal cortex, and the resultant changes in flow of red blood cells were measured with two-photon laser-scanning microscopy in individual subsurface microvessels that surround the occlusion. We observed that the average flow of red blood cells nearly stalls adjacent to the occlusion and remains within 30% of its baseline value in vessels as far as 10 branch points downstream from the occlusion. Preservation of average flow emerges 350 µm away; this length scale is consistent with the spatial distribution of penetrating arterioles. We conclude that penetrating arterioles are a bottleneck in the supply of blood to neocortex, at least to superficial layers.

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Photonic band-gap fiber gas cell fabricated using femtosecond micromachining

Christopher J. Hensley , Daniel H. Broaddus, Chris B. Schaffer, and Alexander L. Gaeta

Optics Express (2007)

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Femtosecond laser drilling is used to produce a variable-pressure fiber gas cell. Tightly focused laser pulses are used to produce micrometer-diameter radial channels in a hollow-core photonic band-gap fiber (HC-PBGF), and through these microchannels the core of the fiber is filled with a gas. The fiber cell is formed by fusion splicing and sealing the ends of the HC-PBGF to standard step-index fiber. As a demonstration, acetylene is introduced into an evacuated fiber at multiple backing pressures and spectra are measured.

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