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Literature DB >> 18396469

Gas and aerosol mixing in the acinus.

Akira Tsuda¹, Frank S Henry, James P Butler.

Abstract

This review is concerned with mixing and transport in the human pulmonary acinus. We first examine the current understanding of the anatomy of the acinus and introduce elements of fluid mechanics used to characterize the transport of momentum, gas and aerosol particles. We then review gas transport in more detail and highlight some areas of current research. Next we turn our attention to aerosol transport and in particular to mixing within the alveoli. We examine the factors influencing the level of mixing, review the concept of chaotic convective mixing, and make some brief comments on how mixing affects particle deposition. We end with a few comments on some issues unique to the neonatal and developing lung.

Entities: Species

Mesh：

Substances：
Aerosols
Gases

Year: 2008 PMID： 18396469 PMCID： PMC3386788 DOI： 10.1016/j.resp.2008.02.010

Source DB: PubMed Journal: Respir Physiol Neurobiol ISSN： 1569-9048 Impact factor: 1.931

55 in total

Gas and aerosol mixing in the acinus.

1. Two new pulmonary functional indexes suggested by a simple mathematical model.

2. Smaller is better--but not too small: a physical scale for the design of the mammalian pulmonary acinus.

3. The Green's function for the convection-diffusion equation in an analytic lung model.

4. Macroscopic isotropy of lung expansion.

5. A model study of gas diffusion in alveolar sacs.

6. Breathing of half-micron aerosols. II. Interpretation of experimental results.

7. Structure of the human respiratory acinus.

8. Penetration of inhaled He and SF6 into alveolar space at low tidal volumes.

9. Human pulmonary imaging and spectroscopy with hyperpolarized 129Xe at 0.2T.

10. Alveolar development in the human fetus and infant.

1. Geometric hysteresis of alveolated ductal architecture.

2. Aerosol bolus dispersion in acinar airways--influence of gravity and airway asymmetry.

Review 3. Particle transport and deposition: basic physics of particle kinetics.

4. Biomimetics of the pulmonary environment in vitro: A microfluidics perspective.

5. Aerosol deposition characteristics in distal acinar airways under cyclic breathing conditions.

6. Why chaotic mixing of particles is inevitable in the deep lung.

7. Steady streaming: A key mixing mechanism in low-Reynolds-number acinar flows.

8. Aerosol delivery into small anatomical airway model through spontaneous engineered breathing.

9. A Microfluidic Model of Biomimetically Breathing Pulmonary Acinar Airways.

10. Radial transport along the human acinar tree.