Changing stroke rehab and research worldwide now.Time is Brain! trillions and trillions of neurons that DIE each day because there are NO effective hyperacute therapies besides tPA(only 12% effective). I have 523 posts on hyperacute therapy, enough for researchers to spend decades proving them out. These are my personal ideas and blog on stroke rehabilitation and stroke research. Do not attempt any of these without checking with your medical provider. Unless you join me in agitating, when you need these therapies they won't be there.

What this blog is for:

My blog is not to help survivors recover, it is to have the 10 million yearly stroke survivors light fires underneath their doctors, stroke hospitals and stroke researchers to get stroke solved. 100% recovery. The stroke medical world is completely failing at that goal, they don't even have it as a goal. Shortly after getting out of the hospital and getting NO information on the process or protocols of stroke rehabilitation and recovery I started searching on the internet and found that no other survivor received useful information. This is an attempt to cover all stroke rehabilitation information that should be readily available to survivors so they can talk with informed knowledge to their medical staff. It lays out what needs to be done to get stroke survivors closer to 100% recovery. It's quite disgusting that this information is not available from every stroke association and doctors group.

Tuesday, August 1, 2023

Hypercapnia increases brain viscoelasticity

 A cerebral blood flow increase of  36 ± 15% sounds like it could be very important immediately post stroke! It's been almost 4 years, has ANYTHING AT ALL been done in the stroke world on this? Or do we have fucking failures of stroke associations  doing nothing once again?

No clue, so ask your doctor what this means.

Viscoelasticity is defined as the time-dependent response of a material subjected to a constant load or deformation (Cohen, Foster, & Mow, 1998). From: Human Orthopaedic Biomechanics, 2022.

 

Hypercapnia increases brain viscoelasticity

2019 Dec; 39(12): 2445–2455.
Published online 2018 Sep 5. doi: 10.1177/0271678X18799241
PMCID: PMC6893988
PMID: 30182788


Stefan Hetzer,1,2 Florian Dittmann,3 Karl Bormann,1,2 Sebastian Hirsch,1,2 Axel Lipp,4 Danny JJ Wang,5 Jürgen Braun,6 and Ingolf Sack3
Author information Article notes Copyright and License information Disclaimer

Abstract

Brain function, the brain’s metabolic activity, cerebral blood flow (CBF), and intracranial pressure are intimately linked within the tightly autoregulated regime of intracranial physiology in which the role of tissue viscoelasticity remains elusive. We applied multifrequency magnetic resonance elastography (MRE) paired with CBF measurements in 14 healthy subjects exposed to 5-min carbon dioxide-enriched breathing air to induce cerebral vasodilatation by hypercapnia. Stiffness and viscosity as quantified by the magnitude and phase angle of the complex shear modulus, |G*| and ϕ, as well as CBF of the whole brain and 25 gray matter sub-regions were analyzed prior to, during, and after hypercapnia. In all subjects, whole-brain stiffness and viscosity increased due to hypercapnia by 3.3 ± 1.9% and 2.0 ± 1.1% which was accompanied by a CBF increase of 36 ± 15%. Post-hypercapnia, |G*| and ϕ reduced to normal values while CBF decreased by 13 ± 15% below baseline. Hypercapnia-induced viscosity changes correlated with CBF changes, whereas stiffness changes did not. The MRE-measured viscosity changes correlated with blood viscosity changes predicted by the Fåhræus–Lindqvist model and microvessel diameter changes from the literature. Our results suggest that brain viscoelastic properties are influenced by microvessel blood flow and blood viscosity: vasodilatation and increased blood viscosity due to hypercapnia result in an increase in MRE values related to viscosity.

Results

Figure 3 shows group-averaged perfusion and stiffness maps of one representative image slice for the three phases of the hypercapnia challenge. Figure 4 shows the group-averaged values of whole-brain perfusion, stiffness, and viscosity next to the average values of BP and HR. All of them follow a similar pattern: (i) highly significant increase from normocapnia to hypercapnia: Δ|G*| = +3.3 ± 1.9% (p = 1.1 × 10−5), Δϕ = +2.0 ± 1.1% (p = 1.8 × 10−6), ΔCBF = + 36 ± 15% (p = 1.7 × 10−7), ΔBP = +3.4 ± 3.0% (p = 4.3 × 10−3), ΔHR = +5.1 ± 6.0% (p = 5.2 × 10−3); (ii) decrease after hypercapnia with significant differences for stiffness, viscosity, and perfusion only: Δ|G*| = −2.4 ± 1.9% (p = 3.9 × 10−4), ΔBP = −0.8 ± 3.7% (p = 4.5 × 10−1), Δϕ = −2.0 ± 0.7% (p = 1.2 × 10−6), ΔHR = −2.3 ± 6.4% (p = 9.6 × 10−2), and ΔCBF = −36 ± 11% (p = 1.6 × 10−7). For an overview of all group-averaged whole-brain MRE and CBF values, see Table 1.

An external file that holds a picture, illustration, etc. Object name is 10.1177_0271678X18799241-fig3.jpg

Group-averaged perfusion, stiffness, and viscosity maps of one exemplary slice in Montreal Neurological Institute space for the three phases of the hypercapnia challenge. See Figure 2(b) for the corresponding map of analyzed AAL atlas regions in the same slice. Note the pronounced CBF offset in the auditory cortex activated by the scanner noise (Heschl’s gyrus—ROI #23, white arrow). CBF: cerebral blood flow.

An external file that holds a picture, illustration, etc. Object name is 10.1177_0271678X18799241-fig4.jpg

Highly significant increase in all parameters between normocapnia and hypercapnia (red). Decrease in all measured parameters after hypercapnia (blue) with significant differences for whole-brain perfusion, stiffness, and viscosity only (*p < 0.05; **p < 0.01; ***p < 0.001). Note the significant CBF drop under baseline (dashed line) after hypercapnia. For detailed values, see Table 1. CBF: cerebral blood flow.

 

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