Activity 7.5.3.
A dose of morphine is absorbed from the bloodstream of a patient at a rate proportional to the amount in the bloodstream.
(a)
Write a differential equation for \(M(t)\text{,}\) the amount of morphine in the patient’s bloodstream, using \(k\) as the constant proportionality.
(b)
Assuming that the initial dose of morphine is \(M_0\text{,}\) solve the initial value problem to find \(M(t)\text{.}\) Use the fact that the half-life for the absorption of morphine is two hours to find the constant \(k\text{.}\)
(c)
Suppose that a patient is given morphine intravenously at the rate of 3 milligrams per hour. Write a differential equation that combines the intravenous administration of morphine with the body’s natural absorption.
(d)
Find any equilibrium solutions and determine their stability.
(e)
Assuming that there is initially no morphine in the patient’s bloodstream, solve the initial value problem to determine \(M(t)\text{.}\) What happens to \(M(t)\) after a very long time?
(f)
To what rate should a doctor reduce the intravenous rate so that there is eventually 7 milligrams of morphine in the patient’s bloodstream?
