Display options
Cite
Wheatley MA, Schrope B, Shen P. Contrast agents for diagnostic ultrasound: development and evaluation of polymer-coated microbubbles. Biomaterials. 1990;11(9):713-7doi: 10.1016/0142-9612(90)90033-m.
Wheatley, M. A., Schrope, B., & Shen, P. (1990). Contrast agents for diagnostic ultrasound: development and evaluation of polymer-coated microbubbles. Biomaterials, 11(9), 713-7. https://doi.org/10.1016/0142-9612(90)90033-m
Wheatley, M A, et al. "Contrast agents for diagnostic ultrasound: development and evaluation of polymer-coated microbubbles." Biomaterials vol. 11,9 (1990): 713-7. doi: https://doi.org/10.1016/0142-9612(90)90033-m
Wheatley MA, Schrope B, Shen P. Contrast agents for diagnostic ultrasound: development and evaluation of polymer-coated microbubbles. Biomaterials. 1990 Nov;11(9):713-7. doi: 10.1016/0142-9612(90)90033-m. PMID: 2090309.
Copy Download .nbib Format: NLM
Share it on
Full text links
Elsevier Science

Biomaterials. 1990 Nov;11(9):713-7. doi: 10.1016/0142-9612(90)90033-m.

Contrast agents for diagnostic ultrasound: development and evaluation of polymer-coated microbubbles.

Biomaterials

M A Wheatley, B Schrope, P Shen

Affiliations

  1. Department of Chemical Engineering, Drexel University, Philadelphia, PA 19104.

PMID: 2090309 DOI: 10.1016/0142-9612(90)90033-m

Abstract

Although the concept of an ultrasound contrast agent dates from Gramiak's work in 1968 in which indocyanine green was injected into the ascending aorta and heart, no universally accepted contrast agent for ultrasound now exists. This is primarily due to problems with stability, size and/or toxicity of the agents which have been investigated. Development of an effective ultrasound contrast agent would be highly significant for the health care industry, since it would greatly expand the scope of ultrasound (a noninvasive and safe procedure) as a diagnostic technique. While encapsulated gas bubbles offer particular advantages in stability over hand-agitated systems, they frequently present problems with size. Capsules larger than 10 microns in diameter become entrapped in the capillary bed of the lung. This paper describes the use of ionotropic gelation of the naturally occurring polysaccharide, alginate, for microencapsulation of air. Two procedures have been investigated. A novel jet head has been developed which allows co-extrusion of a solution of sodium alginate and air to produce nascent microencapsulated air bubbles which fall into a hardening solution of calcium ions. A second method employs ultrasound to introduce cavitation-induced bubbles into the alginate before capsule formation by spraying. Power spectra of these preparations demonstrate echogenicity (that is strong scatter of the incident ultrasound wave back to the emitting transducer, which also acts as a receiver), with resonant peaks that are a function of capsule size and wall characteristics.

Cited by

Substances

MeSH terms

Publication Types

LinkOut - more resources