Quantitative blood flow measurements in the small animal cardiopulmonary system using digital subtraction angiography

Autor: Ming De Lin, Claude A. Piantadosi, Yi Qi, Craig T. Marshall, Samuel M. Johnston, G. Allan Johnson, Cristian T. Badea
Rok vydání: 2009
Předmět:
Zdroj: Medical Physics. 36:5347-5358
ISSN: 0094-2405
Popis: Purpose: The use of preclinical rodent models of disease continues to grow because these models help elucidate pathogenic mechanisms and provide robust test beds for drug development. Among the major anatomic and physiologic indicators of disease progression and genetic or drug modification of responses are measurements of blood vessel caliber and flow. Moreover, cardiopulmonary blood flow is a critical indicator of gas exchange. Current methods of measuring cardiopulmonary blood flow suffer from some or all of the following limitations—they produce relative values, are limited to global measurements, do not provide vasculature visualization, are not able to measure acute changes, are invasive, or require euthanasia. Methods: In this study, high-spatial and high-temporal resolution x-ray digital subtraction angiography(DSA) was used to obtain vasculature visualization, quantitative blood flow in absolute metrics (ml/min instead of arbitrary units or velocity), and relative blood volume dynamics fromdiscrete regions of interest on a pixel-by-pixel basis ( 100 × 100 μ m 2 ) . Results: A series of calibrations linked the DSA flow measurements to standard physiological measurement using thermodilution and Fick’s method for cardiac output (CO), which in eight anesthetized Fischer-344 rats was found to be 37.0 ± 5.1 ml / min . Phantom experiments were conducted to calibrate the radiographic density to vessel thickness, allowing a link of DSAcardiac output measurements to cardiopulmonary blood flow measurements in discrete regions of interest. The scaling factor linking relative DSAcardiac output measurements to the Fick’s absolute measurements was found to be 18.90 × CO DSA = CO Fick . Conclusions: This calibrated DSA approach allows repeated simultaneous visualization of vasculature and measurement of blood flow dynamics on a regional level in the living rat.
Databáze: OpenAIRE