Bio-effects and safety of low-intensity, low-frequency ultrasonic exposure

Low-frequency (LF) ultrasound (20–100kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic tr...

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Bibliographic Details
Published inProgress in biophysics and molecular biology Vol. 108; no. 3; pp. 119 - 138
Main Authors Ahmadi, Farzaneh, McLoughlin, Ian V., Chauhan, Sunita, ter-Haar, Gail
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.04.2012
Subjects
Animals
Bio-effects
Biological effects
blood
Dentistry
Drugs
Environmental Exposure - adverse effects
Environmental Exposure - standards
eyes
Hazard
Humans
industrial applications
Kidney
Low-frequency ultrasound
mathematical models
Mechanical index
Mechanical Phenomena
Molecular biology
renal calculi
risk reduction
Safety
safety standards
Simulation
Sonophoresis
Surgery
surveys
Temperature
Thermal index
Ultrasonic Therapy - adverse effects
Ultrasonic Therapy - methods
Ultrasonic Therapy - standards
Ultrasonics
Ultrasonics - methods
Sonophoresis
Bio-effects
Mechanical index
Thermal index
Hazard
Low-frequency ultrasound
Online AccessGet full text
ISSN0079-6107
1873-1732
1873-1732
DOI10.1016/j.pbiomolbio.2012.01.004

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Abstract Low-frequency (LF) ultrasound (20–100kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500kHz.
AbstractList Low-frequency (LF) ultrasound (20-100 kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500 kHz.Low-frequency (LF) ultrasound (20-100 kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500 kHz.
Low-frequency (LF) ultrasound (20–100kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500kHz.
Low-frequency (LF) ultrasound (20-100 kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500 kHz.
Low-frequency (LF) ultrasound (20–100kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound mainly occupy this frequency range. This range is also used for various therapeutic medical applications including sonophoresis (ultrasonic transdermal drug delivery), dentistry, eye surgery, body contouring, the breaking of kidney stones and eliminating blood clots. While emerging LF applications such as ultrasonic drug delivery continue to be developed and undergo translation for human use, significant gaps exist in the coverage of safety standards for this frequency range. Accordingly, the need to understand the biological effects of LF ultrasound is becoming more important. This paper presents a broad overview of bio-effects and safety of LF ultrasound as an aid to minimize and control the risk of these effects. Its particular focus is at low intensities where bio-effects are initially observed. To generate a clear perspective of hazards in LF exposure, the mechanisms of bio-effects and the main differences in action at low and high frequencies are investigated and a survey of harmful effects of LF ultrasound at low intensities is presented. Mechanical and thermal indices are widely used in high frequency diagnostic applications as a means of indicating safety of ultrasonic exposure. The direct application of these indices at low frequencies needs careful investigation. In this work, using numerical simulations based on the mathematical and physical rationale behind the indices at high frequencies, it is observed that while thermal index (TI) can be used directly in the LF range, mechanical index (MI) seems to become less reliable at lower frequencies. Accordingly, an improved formulation for the MI is proposed for frequencies below 500kHz.
Author Chauhan, Sunita
McLoughlin, Ian V.
Ahmadi, Farzaneh
ter-Haar, Gail
Author_xml – sequence: 1
  givenname: Farzaneh
  surname: Ahmadi
  fullname: Ahmadi, Farzaneh
  organization: School of Computer Engineering, Nanyang Technological University, N4-02b-52, Nanyang Avenue, Singapore 639798, Singapore
– sequence: 2
  givenname: Ian V.
  surname: McLoughlin
  fullname: McLoughlin, Ian V.
  email: mcloughlin@ntu.edu.sg
  organization: School of Computer Engineering, Nanyang Technological University, N4-02b-52, Nanyang Avenue, Singapore 639798, Singapore
– sequence: 3
  givenname: Sunita
  surname: Chauhan
  fullname: Chauhan, Sunita
  organization: School of Mechanical & Aerospace Engineering, Nanyang Technological University, N3-02b-41, Nanyang Avenue, Singapore
– sequence: 4
  givenname: Gail
  surname: ter-Haar
  fullname: ter-Haar, Gail
  organization: Joint Physics Department, Royal Marsden Hospital: Institute of Cancer Research, Sutton, Surrey SM2 5PT, UK
BackLink https://www.ncbi.nlm.nih.gov/pubmed/22402278$$D View this record in MEDLINE/PubMed
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Issue 3
Keywords Sonophoresis
Bio-effects
Mechanical index
Thermal index
Hazard
Low-frequency ultrasound
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Snippet Low-frequency (LF) ultrasound (20–100kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound...
Low-frequency (LF) ultrasound (20-100 kHz) has a diverse set of industrial and medical applications. In fact, high power industrial applications of ultrasound...
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SubjectTerms Animals
Bio-effects
Biological effects
blood
Dentistry
Drugs
Environmental Exposure - adverse effects
Environmental Exposure - standards
eyes
Hazard
Humans
industrial applications
Kidney
Low-frequency ultrasound
mathematical models
Mechanical index
Mechanical Phenomena
Molecular biology
renal calculi
risk reduction
Safety
safety standards
Simulation
Sonophoresis
Surgery
surveys
Temperature
Thermal index
Ultrasonic Therapy - adverse effects
Ultrasonic Therapy - methods
Ultrasonic Therapy - standards
Ultrasonics
Ultrasonics - methods
Title Bio-effects and safety of low-intensity, low-frequency ultrasonic exposure
URI https://dx.doi.org/10.1016/j.pbiomolbio.2012.01.004
https://www.ncbi.nlm.nih.gov/pubmed/22402278
https://www.proquest.com/docview/1113245988
https://www.proquest.com/docview/1733555225
https://www.proquest.com/docview/992832909
Volume 108
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