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Department of Mechanical Engineering and Center for Biomedical Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139
The method of
surfactant instillation into the lungs for treatment of neonatal
respiratory distress syndrome is an important attribute of delivery,
and it may determine the overall efficacy of treatment. Previous
studies primarily focused on the rate at which the bolus is instilled.
These findings show that rapid injections lead to a more homogenous
distribution, whereas slow infusions drain into the dependent lung with
respect to gravity, resulting in a heterogeneous deposition. These
results suggest that it is beneficial to form a meniscus, from which a
more homogenous dispersal can proceed. The objective of the present
study was to develop a functional criterion for meniscus formation
during bolus injection. An in vitro experiment was used to examine the
clinical setting of surfactant instillation. The physical variables
examined were the bolus viscosity (µ) and density (
), gravity
(g), injection rate (Q), orientation of the
trachea with respect to gravity (
), tracheal size
(D), surface tension (
), and
catheter size (d). All quantities
were varied, except gravity and catheter size. Experimental results
show that a meniscus will form when
NSt > 0.004Re2/3, where
NSt is Stokes
number and Re is Reynolds number,
NSt = µQ/D4gsin,
a ratio of viscous effects to gravitational effects, and Re = QD/d2µ,
a ratio of inertial effects to viscous effects. Rapid injections, high
viscosity, and small inclination with respect to gravity promote
meniscus formation. These results can be used to refine the guidelines
for administration of surfactant replacement therapy.
acute respiratory distress syndrome; respiratory distress syndrome; surfactant bolus; surfactant replacement therapy
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