Matchmaking away from Bloodstream Heat, Viscosity, and you will Tension
The fresh new blood sugar levels focus dimensions have been made that have a keen Accutrend GC glucometer (Boehringer Mannheim, Mannheim, Germany). No less than five measurements of blood glucose and you will simultaneous size of bloodstream and you will plasma viscosity were made for everyone of 31 times at the 0, 29, 60, and you will 120 min within 22°C, after consumption regarding 75 grams regarding sugar.
Analytical Assessment
Consequence of the original category were analyzed mathematically with the Student t make sure Spearman correlation test. The relationship between blood sugar attention and you may viscosity try examined statistically utilising the Beginner local hookups Pittsburgh t attempt, data regarding variance, and you may regression investigation.
Results
When the blood temperature decreased from 36.5° to 22°C, the mean blood free flow time increased from to sec (%). According to Poiseuille’s equation, the blood flow rate decreases %, and for the compensation of this ischemic state, a % BP increase or 5.9% vasodilation is needed. If viscosity (? in the denominator of the equation) changes from 100 to (%), the flow rate Q would decrease = %. If viscosity increases %, the pressure (F1 ? F2) value (multiplier in the equation) must be increased with the same percentage to keep the equation constant. When the viscosity increases %, to keep the flow rate constant, the radius of vessel (initial) a 4 , must increase %. The calculation of this increased radius (last) is a 4 final = 1.2613 ? a 4 initial. From this calculation, ?final = = 1.0597 and so, 5.97% vasodilation can be estimated.
If the temperatures increased regarding thirty-six.5° so you can 39.5°C, this new blood 100 % free flow go out diminished of to sec (%). Inside state, brand new flow rates increased %; predicated on Poiseuille’s equation, an excellent % reduced amount of BP or 2.71% vasoconstriction try needed seriously to hold the hemodynamic harmony constant.
The correlation between temperature and blood viscosity is r = ?0.84, P < .001 when all the differences at the three temperatures are evaluated together (Fig. 1). When all of the blood free flow time data for the three temperatures were evaluated together according to age, there was a negative correlation (r = ?0.1381 and P < .05); when the data were evaluated according to sex, it was found that the mean blood free flow time in women was % less than that in men (r = 0.3408, P < .001).
Effect of temperature on blood viscosity. When blood temperature decreases from 36.5° to 22°C, blood viscosity increases %. If temperature increases from 36.5° to 39.5°C, blood viscosity decreases %. To make a more accurate presentation in the graphic representation and statistics, instead of the “relative viscosity” value, blood free flow time in seconds (s) was used as data. When all of the differences at three temperatures are evaluated together, a negative correlation is seen between blood temperature and viscosity (r = ?0.84, P < .001).
When the temperature decreased from 36.5° to 22°C, plasma free flow time rose from 4.81 to 5.71 sec (%); with a temperature increase from 36.5° to 39.5°C, it decreased from 4.78 to 4.57 sec (4.99%). A negative correlation was seen (r = ?0.9342, P < .001) when the plasma flow times at the three temperatures were evaluated together. With a temperature decrease from 36.5° to 22°C, erythrocyte free flow time increased from to sec (%). When the temperature increased from 36.5° to 39.5°C, erythrocyte free flow time decreased from to sec (9.92%). There was a negative correlation between temperature and erythrocyte free flow time (r = ?0.62, P < .001). All of the blood, plasma viscosity, and erythrocyte deformability differences due to temperature were statistically significant (P < .001).
