Stenotic lesion characterization

The invention claimed is: 1. A method comprising: inserting an intravascular measurement device into a body of a patient; controlling the intravascular measurement device to acquire a first measurement signal, the first measurement signal being indicative of a physical dimension of a blood vessel having a stenotic lesion during a first blood flow rate, the first measurement signal comprising a first distal measurement signal indicative of the physical dimension of the blood vessel at a location distal to the stenotic lesion and a first proximal measurement signal indicative of the physical dimension of the blood vessel at a location proximal to the stenotic lesion, the location proximal to the stenotic lesion not surpassing any portion of the stenotic lesion; controlling the intravascular measurement device to acquire a second measurement signal, the second measurement signal being indicative of the physical dimension of the blood vessel having the stenotic lesion during a second blood flow that is greater than the first blood flow rate, the second measurement signal comprising a second distal measurement signal indicative of the physical dimension of the blood vessel at the location distal to the stenotic lesion and a second proximal measurement signal indicative of the physical dimension of the blood vessel at the location proximal to the stenotic lesion; and determining, with a processor, a value representative of a change in the physical dimension of the blood vessel between the first blood flow rate and the second blood flow rate based on the first measurement signal and the second measurement signal, wherein determining the value representative of the change in the physical dimension of the blood vessel between the first and second blood flow rates comprises (i) generating a distal dilation value by determining a difference between the physical dimension of the blood vessel at the location distal to the stenotic lesion during the second blood flow rate and the physical dimension of the blood vessel at the location distal to the stenotic lesion during the first blood flow rate, (ii) generating a proximal dilation value by determining a difference between the physical dimension of the blood vessel at the location proximal to the stenotic lesion during the second blood flow rate and the physical dimension of the blood vessel at the location proximal to the stenotic lesion during the first blood flow rate, and (iii) comparing the distal dilation value to the proximal dilation value to determine the value representative of the change in physical dimension of the blood vessel between the first and second blood flow rates. 2. The method of claim 1 , wherein the first blood flow rate is a blood flow rate during a first part of a patient cardiac cycle, the second blood flow rate is a blood flow rate during a second part of the patient cardiac cycle that is different than the first part of the patient cardiac cycle, the second part of the patient cardiac cycle being a part in which vascular resistance is minimized during the patient cardiac cycle. 3. The method of claim 1 , wherein the intravascular measurement device is an intravascular ultrasonic measurement device; the first blood flow rate is a non-hyperemic blood flow rate; and the second blood flow rate is a hyperemic blood flow rate caused by a pharmacologic vasodilator drug. 4. The method of claim 1 , wherein the first blood flow rate is a non-hyperemic blood flow rate and the second blood flow rate is a hyperemic blood flow rate caused by a pharmacologic vasodilator drug. 5. The method of claim 1 , wherein the intravascular measurement device is an intravascular optical measurement device. 6. The method of claim 1 , wherein the intravascular measurement device is an intravascular ultrasonic measurement device. 7. The method of claim 1 , further comprising determining, with the processor, whether the lesion is an ischemia-inducing lesion based on the comparison between the distal dilation value and the proximal dilation value. 8. The method of claim 7 , wherein the physical dimension of the blood vessel is at least one of a cross-sectional area of the blood vessel or a diameter of the blood vessel. 9. The method of claim 8 , wherein, based on the comparison between the distal dilation value and the proximal dilation value, the lesion is determined to be an ischemia-inducing lesion when the distal dilation value is different than the proximal dilation value. 10. The method of claim 9 , wherein the lesion is determined to be an ischemia-inducing lesion when the distal dilation value is smaller than the proximal dilation value. 11. The method of claim 1 , wherein the blood vessel is a coronary artery. 12. The method of claim 1 , wherein comparing the distal dilation value to the proximal dilation value to determine the value representative of the change in physical dimension of the blood vessel between the first and second blood flow rates comprises determining a ratio of the distal dilation value to the proximal dilation value. 13. The method of claim 1 , wherein comparing the distal dilation value to the proximal dilation value to determine the value representative of the change in physical dimension of the blood vessel between the first and second blood flow rates comprises determining a difference between the distal dilation value and proximal dilation value. 14. A system comprising: an intravascular measurement device configured to acquire first and second measurement signals; a catheter configured to deliver the intravascular measurement device to a desired location in a body of a patient; and a processor that is configured to: receive the first measurement signal from the intravascular measurement device, the first measurement signal being indicative of a physical dimension of a blood vessel having a stenotic lesion during a first blood flow rate, the first measurement signal comprising a first distal measurement signal indicative of the physical dimension of the blood vessel at a location distal to the stenotic lesion and a first proximal measurement signal indicative of the physical dimension of the blood vessel at a location proximal to the stenotic lesion, the location proximal to the stenotic lesion not surpassing any portion of the stenotic lesion; receive the second measurement signal from the intravascular measurement device, the second measurement signal being indicative of the physical dimension of the blood vessel having the stenotic lesion during a second blood flow rate that is greater than the first blood flow rate, the second measurement signal comprising a second distal measurement signal indicative of the physical dimension of the blood vessel at the location distal to the stenotic lesion and a second proximal measurement signal indicative of the physical dimension of the blood vessel at the location proximal to the stenotic lesion; and determine a value representative of a change in the physical dimension of the blood vessel between the first blood flow rate and the second blood flow rate based on the first measurement signal and the second measurement signal by (i) generating a distal dilation value by determining a difference between the physical dimension of the blood vessel at the location distal to the stenotic lesion during the second blood flow rate and the physical dimension of the blood vessel at the location distal to the stenotic lesion during the first blood flow rate, (ii) generating a proximal dilation value by determining a difference between the physical dimension of the blood vessel at the location proximal to the stenotic lesion during the second