A man of height 1.8 m is in a standing position . What is the difference in the blood pressure between th e blood in his feet and the topmost level of his head, if the density or blood is `1.06kg//m^3`
[Assume that the blood vessels in a human body act as extremely thin pipes and g =`10//s^2`]

Calculate the hydrostatic difference in blood pressure between the brain and the foot in a person of height 1.50 m. The density of blood is 1.06 xx 10^(3) kg//m^(3) .

What is the minimum pressure required to force the blood from the heart to the top of the head (vertical distance 0.5m ) ? [density of blood is 1040 kg m^(-3). Fraction is to be neglected and g=9.8ms^(-2) ]

What is the minimum pressure required to force the blood from the heart to the top of the head (vertical distance 0.5m ) ? [density of blood is 1040 kg m^(-3). Fraction is to be neglected and g=9.8ms^(-2) ]

The average human heart forces four litre of blood per minute through arteries a pressure of 125 mm. If the density of blood is 1.03xx10^(3)kg//m^(3) then the power of heart is :

The average human heart forces four litre of blood per minute through arteries a pressure of 125 mm. If the density of blood is 1.03xx10^(3)kg//m^(3) then the power of heart is :

The human heart forces 4000cm^(3) of blood per minute through the arteries under pressure of 130mm . The density of blood is 1.03g//c c . What is the horse power of the heart ?

Blood pressure in Argentinosaurus. (a) If this long-necked, gigantic sauropod had a head height of 18 m and a heart height of 8.0 m, what (hydrostatic) gauge pressure in its blood was required at the heart such that the blood pressure at the brain was 80 torr (just enough to perfuse the brain with blood)? Assume the blood had a density of 1.06 xx 10 kg//m^(3) . (b) What was the blood pressure (in torr or mm Hg) at the feet?

The speed at which a person runs is directly proportional to the bloodpressure in his body. If the speed of a person is 2 m/sec his blood pressure would be 120 units. Find the blood pressure in unis of a person running at 8.5 m/sec.

A 70 kg man standing on ice throws a 3 kg body horizontally at 8m//s. The friction coefficient between the ice and his feet is 0.02. The distance, the man slip is

A 70 kg man standing on ice throws a 3 kg body horizontally at 8m//s. The friction coefficient between the ice and his feet is 0.02. The distance, the man slip is