Thromb Haemost 1977; 38(03): 0640-0651
DOI: 10.1055/s-0038-1651879
Original Article
Schattauer GmbH

Platelet Aggregation Induced in Vitro by Therapeutic Ultrasound

B. V Chater
*   Haematology Section, Central Toxicology Laboratory, ICI Limited, Alderley Park, Nr Macclesfield, Cheshire and
,
A. R Williams
**   The Department of Medical Biophysics, University of Manchester Medical School, Stopford Building, Oxford Road, Manchester, England
› Author Affiliations
Further Information

Publication History

Received 19 April 1977

Accepted 16 June 1977

Publication Date:
04 July 2018 (online)

Summary

Platelets were found to aggregate spontaneously when exposed to ultrasound generated by a commercial therapeutic device. At a given frequency, aggregation was found to be a dose-related phenomenon, increasing intensities of ultrasound inducing more extensive and more rapid aggregation. At any single intensity, the extent aggregation was increased as the frequency of the applied ultrasound was decreased (from 3.0 to 0.75 MHz).

Ultrasound-induced platelet aggregation was found to be related to overall platelet sensitivity to adenosine diphosphate. More sensitive platelets were found to aggregate spontaneously at lower intensities of sound, and also the maximum extent of aggregation was found to be greater. Examination of ultrasound-induced platelet aggregates by electron microscopy demonstrated that the platelets had undergone the release reaction.

The observation that haemoglobin was released from erythrocytes in whole blood irradiated under identical physical conditions suggests that the platelets are being distrupted by ultrasonic cavitation (violent gas/bubble oscillation).

It is postulated that overall platelet aggregation is the result of two distinct effects. Firstly, the direct action of ultrasonic cavitation disrupts a small proportion of the platelet population, resulting in the liberation of active substances. These substances produce aggregation, both directly and indirectly by inducing the physiological release reaction in adjacent undamaged platelets.

 
  • References

  • 1 Born G. V. R. 1962; Quantative investigations into the aggregation of blood platelets. Journal of Physiology 162: 67.
  • 2 Chater B. V. 1976; The role of membrane bound complement in the aggregation of mammalian platelets by collagen. British Journal of Haematology 32: 511.
  • 3 Crosby W. H, Furth E. W. 1956; A modification of the benzidine method for the measurement of haemoglobin in plasma and urine. Blood 11: 380.
  • 4 Didisheim P, Kazmier E. J, Fuster V. 1974; Platelet inhibition in the management of thrombosis. Thrombosis et Diathesis Haemorrhagica Suppl. 32: 21.
  • 5 Glover C. J, Mcintire L. V, Natelson E. A, Brown III C. H. 1974 Effect of shear stress on clot formation. Paper presented at the American Institute of Chemical Engineering. Meeting Pittsburg, Penn.. 2–5 June.
  • 6 Hill C. R. 1968; The possibility of hazard in medical and industrial applications of ultrasound. British Journal of Radiology 41: 561.
  • 7 Honour A. J, Mitchell J. R. A. 1964; Platelet clumping in injured vessels. British Journal of Experimental Pathology 45: 75.
  • 8 Hung T. C, Hochmuth R. M, Joist J. H. 1976; Shear-induced aggregation and lysis of platelets. Transactions of the American Society of Artificial Internal Organs 22: 110.
  • 9 Jørgensen L, Rowsell H. G, Hovig T, Glynn M. F, Mustard J. F. 1967; Adenosine diphosphate induced platelet aggregation and myocardial infarction in swine. Laboratory Investigations 17: 616.
  • 10 Kobayashi L, Mashimo N, Herther K. K, Didisheim P. 1974; Mechanism of collagen induced thrombocytopenia and haemoglobinaemia in rats. Thrombosis et Diathesis Haemorrhagica Suppl. 60: 407.
  • 11 Mustard J. F, Packham M. A. 1970; Factors influencing platelet function: adhesion, release, and aggregation. Pharmacological reviews 22: 97.
  • 12 Mustard J. F, Packham M. A. 1974. Role of platelets and thrombosis in atherosclerosis. In: The Platelet. (Eds.) Brinkhouse K. M, Shermer R. W, Mostofi F. K. The Williams and Wilkins Company; Baltimore: 215.
  • 13 O’Brien J. R. 1962; Platelet aggregation II some results from a new method of study. Journal of Clinical Pathology 15: 446.
  • 14 O’Brien J. R. 1966; Changes in platelet membranes possibly associated with platelet stickiness. Nature (London) 212: 1057.
  • 15 Packam M. A, Ardle N. G, Mustard J. F. 1969; The effect of adenine compounds in platelet aggregation. American Journal of Physiology 217: 1009.
  • 16 Paterson J. C. 1969. The pathology of venous thrombosis. In: Thrombosis. (Eds.) Sherry S, Brinkhouse K. M, Genton E, Stengle J. M. National Academy of Sciences; Washington DC, USA: 321.
  • 17 Sanderson J. H, Delamore E. W. 1973; Changes in platelet thrombotic tendency during oral contraception. The Journal of Obstetrics and Gynaecology of the British Commonwealth 80: 639.
  • 18 Sanderson J. H, Taylor D. S, Delamore E. W. 1973; Changes in platelet thrombotic tendency during parturition. The Journal of Obstetrics and Gynaecology of the British Commonwealth 80: 633.
  • 19 Sevitt S. 1973. Pathology and pathogenesis of deep vein thrombosis. In: Recent Advances in Thrombosis, Vol. 1. (ed.) Poller L. Churchill and Livingstone; Edinburgh — London: 17.
  • 20 Wells P. N. T. 1969. In: The Physical Principles of Ultrasonic Diagnosis. published by Academic Press; London and New York.:
  • 21 Williams A. R. 1974; Release of serotonin from human platelets by acoustic microstreaming. Journal of the Acoustic Society of America 56: 1640.
  • 22 Williams A. R, O’Brien Jr. W. D, Coller B. S. 1976; Exposure to ultrasound decreases the recalcification time of platelet rich plasma. Ultrasound in Medicine and Biology 2: 113.
  • 23 Williams A. R. 1977 Iravascular mural thrombi produced by acoustic microstreaming. Ultrasound in Medicine and Biology. in press.
  • 24 Yamazaki H, Takahashi R, Tadahiro S. 1975; Hyperaggregability of platelets in thromboembolitic disorders. Thrombosis et Diathesis Haemorrhagica 34: 94.