Blood type, vessel thickness, and temperature

Blood viscosity, vessel length, and radius

Blood pressure, vessel diameter, and flow rate

Heart rate, blood volume, and vessel elasticity

It halves the resistance

It doubles the resistance

It quadruples the resistance

It has no effect on resistance

Because length changes decrease resistance

Because radius is raised to the fourth power in the equation

Because length is not a factor in the resistance equation

Because radius changes are easier to achieve

By multiplying the resistances of each vessel

By adding the resistances of each vessel

By subtracting the smallest resistance from the largest

By averaging the resistances of each vessel

The total resistance remains the same

The total resistance decreases

The total resistance becomes zero

The total resistance increases significantly

It has no effect on resistance

It doubles the resistance

It increases the resistance by 16 times

It decreases the resistance by half

By taking the reciprocal of the sum of reciprocals of each resistance

By subtracting the smallest resistance from the largest

By multiplying the resistances of each vessel

By adding the resistances of each vessel

It is unaffected by changes in individual resistances

It is equal to the sum of all resistances

It is always less than any individual resistance

It is always greater than any individual resistance

21

2.1

15

30

Because the resistances are averaged

Because the resistances are added

Because the resistances are divided

Because the resistances are multiplied