A Generalized Linear Models (GLM) was used to carry out the CFC analysis in Matlab. Because delta waves dominated the ECoG recorded, we modeled the higher-frequency amplitude envelope as a function of low-frequency phase using a spline basis. Besides the CFC analysis, we also characterized the distribution of the delta wave density in time domain. Four CFC, Theta, Alpha, Beta, and Gamma were at very small values after CSD, and after about 8 minutes, the CFC recovered to the pre-CSD level. CFC were seen to decrease before a CSD occurred at the higher-frequency bands and tended to decrease quickly. Whether the attenuated CFC by CSD has long-term consequences remains to be determined. Future studies will explore the impact of cortical CSD on CFC with deeper brain structures, including the thalamus and the caudate putamen.This is the first multimodal study of cerebral tissue metabolism and perfusion post-hypoxic-ischaemic (HI) brain injury using broadband near-infrared spectroscopy (bNIRS), diffuse correlation spectroscopy (DCS), positron emission tomography (PET) and magnetic resonance spectroscopy (MRS). In seven piglet preclinical models of neonatal HI, we measured cerebral tissue saturation (StO2), cerebral blood flow (CBF), cerebral oxygen metabolism (CMRO2), changes in the mitochondrial oxidation state of cytochrome c oxidase (oxCCO), cerebral glucose metabolism (CMRglc) and tissue biochemistry (Lac+Thr/tNAA). At baseline, the parameters measured in the piglets that experience HI (not controls) were 64 ± 6% StO2, 35 ± 11 ml/100 g/min CBF and 2.0 ± 0.4 μmol/100 g/min CMRO2. After HI, the parameters measured were 68 ± 6% StO2, 35 ± 6 ml/100 g/min CBF, 1.3 ± 0.1 μmol/100 g/min CMRO2, 0.4 ± 0.2 Lac+Thr/tNAA and 9.5 ± 2.0 CMRglc. This study demonstrates the capacity of a multimodal set-up to interrogate the pathophysiology of HIE using a combination of optical methods, MRS, and PET.The blood-brain barrier (BBB) poses a significant challenge for drug delivery to the brain. The limitations of our knowledge about the nature of BBB explain the slow progress in the therapy of brain diseases and absence of methods for drug delivery to the brain in clinical practice. Here, we show that the BBB opens for high-molecular-weight compounds after exposure to loud sound (100 dB 370 Hz) in rats. The role of stress induced by loud sound and the systemic and molecular mechanisms behind it are discussed in the framework of the BBB. This opens an informative platform for novel fundamental knowledge about the nature of BBB and for the development of a noninvasive brain drug delivery technology.Oxygen supply to tissues can be seriously impacted during wound healing. In particular, edema can increase the distance between capillaries, thus decreasing oxygen supply to cells. Thus, the detection of edema, preferably at the preclinical stage, is of great importance. However, there is no reference standard for a cross-sectional, objective measurement of edema. Multispectral imaging can be such adjuvant technology to elucidate the impact of edema on oxygen transport to tissues. The purpose of the current study is to assess the feasibility of multispectral imaging for visualization of water content in surface tissues. The skin (hand and forearm) of healthy volunteers was imaged using the Multi-Spectral Imaging Device (MSID). MSID is a multispectral imaging system for visualization of tissue chromophores in surface tissues. It uses a 12-bit scientific-grade NIR-enhanced monochrome camera and ten wavelength light source (600-1000 nm range) to visualize the distribution of oxy- and deoxyhemoglobins, methemoglobin, water, and melanin. The imaging distance is 30 cm and the field of view 7×7 cm. Water content was extracted using various subsets of two and three wavelengths. To mimic the use of a consumer-grade camera, four least significant bits for each pixel value of a 12-bit image were discarded during preprocessing. https://www.selleckchem.com/products/vav1-degrader-3.html Eight-bit results were compared with 12-bit results. Rough numerical calculations and initial experiments show feasibility of water content imaging in the skin using 970 nm band illumination and 12- and 8-bit cameras. Rough numerical calculations and initial experiments show feasibility of water content imaging in the skin using 970 nm band illumination and 12- and 8-bit cameras.In radiotherapy, hypoxia is a known negative factor, occurring especially in solid malignant tumours. Nitroimidazole-based positron emission tomography (PET) tracers, due to their selective binding to hypoxic cells, could be used as surrogates to image and quantify the underlying oxygen distributions in tissues. The spatial resolution of a clinical PET image, however, is much larger than the cellular spatial scale where hypoxia occurs. A question therefore arises regarding the possibility of quantifying different hypoxia levels based on PET images, and the aim of the present study is the prescription of corresponding therapeutic doses and its exploration.A tumour oxygenation model was created consisting of two concentric spheres with different oxygen partial pressure (pO2) distributions. In order to mimic a PET image of the simulated tumour, given the relation between uptake and pO2, fundamental effects that limit spatial resolution in a PET imaging system were considered the uptake distribution was processed with a Gaussian 3D filter, and a re-binning to reach a typical PET image voxel size was performed. Prescription doses to overcome tumour hypoxia and predicted tumour control probability (TCP) were calculated based on the processed images for several fractionation schemes. Knowing the underlying oxygenation at microscopic scale, the actual TCP expected after the delivery of the calculated prescription doses was evaluated. Results are presented for three different dose painting strategies by numbers, by contours and by using a voxel grouping-based approach.The differences between predicted TCP and evaluated TCP indicate that careful consideration must be taken on the dose prescription strategy and the selection of the number of fractions, depending on the severity of hypoxia.