Report on Laser Safety: Risks, Hazards, and Control Measures Analysis
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This report delves into the critical aspects of laser safety, addressing the risks, hazards, and control measures necessary for safe operation in various settings, including healthcare. It begins with an introduction to laser technology, highlighting its widespread use and the potential for harm if not handled correctly. The report then discusses risk management, emphasizing the importance of understanding international standards, practice guidelines, and regulations, such as those from IEC and ANSI. It covers the identification of risks and hazards, including properties of laser light, wavelength characteristics, and application techniques. Control measures, including procedural, engineering, and administrative controls, are examined. The role and responsibilities of the Laser Safety Officer (LSO) are detailed, along with procedural control measures such as controlled access and the management of ocular and electrical hazards. The report also emphasizes the importance of audits, education, training, and documentation in maintaining a robust laser safety program. Overall, the report aims to provide general information and practical guidance to promote high standards of safety for personnel involved in the maintenance and operation of laser devices, with a particular focus on the healthcare environment.
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Running head: LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Laser Safety: Risks, Hazards and Control Measures
Name of the Student:
Name of the University:
Author note:
Table of Contents
Laser Safety: Risks, Hazards and Control Measures
Name of the Student:
Name of the University:
Author note:
Table of Contents
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1LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Introduction....................................................................................................................2
Discussion......................................................................................................................2
Risk management.......................................................................................................2
1. Knowledge about the standards, practice guidelines and regulations....................2
2. Identification of the Risks and Hazards.................................................................4
3. Implementation of the control measures and establishing control measures.........4
The Laser Safety Officer........................................................................................6
Procedural Control Measures.................................................................................7
Controlled Access..................................................................................................7
Ocular Hazards.......................................................................................................7
Electrical Hazards..................................................................................................8
4. Audit for Safety Program Monitoring....................................................................8
Education and Training..........................................................................................8
Documentation.......................................................................................................9
Conclusion......................................................................................................................9
References:...................................................................................................................10
Introduction....................................................................................................................2
Discussion......................................................................................................................2
Risk management.......................................................................................................2
1. Knowledge about the standards, practice guidelines and regulations....................2
2. Identification of the Risks and Hazards.................................................................4
3. Implementation of the control measures and establishing control measures.........4
The Laser Safety Officer........................................................................................6
Procedural Control Measures.................................................................................7
Controlled Access..................................................................................................7
Ocular Hazards.......................................................................................................7
Electrical Hazards..................................................................................................8
4. Audit for Safety Program Monitoring....................................................................8
Education and Training..........................................................................................8
Documentation.......................................................................................................9
Conclusion......................................................................................................................9
References:...................................................................................................................10
2LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Introduction
Laser technology is now not only limited to the hospital operating rooms, it in fact has
also become available in the clinics, private enterprises and the office practices. The burden
of the management of safety has shifted to the individual users from that of the hospital
staffs, often without the advantage of proper resources. The reason behind such a change is
that laser emits coherent and intense electromagnetic radiation which has the potential to
cause irreversible damage to both the skin and eye. Laser safety is something that is
everyone’s concern. Lasers have the capability of delivering a large package of energy and
that too in a very focused and controlled manner; in fact most of the laser applications take
the advantage of it (Debord et al. 2014). However, it is also to be noted that if those
properties are not controlled in an effective way, they could present severe hazards to the
workers working with them and also to the adjacent activities and materials. Like, for
example, the risk of burns, eye damage and the risks of material surfaces to get damaged.
This paper will present a brief jest of risks, hazards and control measures associated with the
laser safety. The main purpose of this report is to provide general information and some
practical guidance on the working conditions in an aim to lead to high standards of the safety
for all the personnel that are involved in the maintenance and operation of laser devices.
Discussion
Risk management
1. Knowledge about the standards, practice guidelines and regulations
The international standards regarding the laser safety are all available through the IEC
(International Electrotechnical Commission), documents 60825, 60825- Part 8 and 60601
(Smalley 2013). All these standards are worldwide benchmarks for the laser safety and
consist of the informative and normative guidance for the professional clinicians, laser use
Introduction
Laser technology is now not only limited to the hospital operating rooms, it in fact has
also become available in the clinics, private enterprises and the office practices. The burden
of the management of safety has shifted to the individual users from that of the hospital
staffs, often without the advantage of proper resources. The reason behind such a change is
that laser emits coherent and intense electromagnetic radiation which has the potential to
cause irreversible damage to both the skin and eye. Laser safety is something that is
everyone’s concern. Lasers have the capability of delivering a large package of energy and
that too in a very focused and controlled manner; in fact most of the laser applications take
the advantage of it (Debord et al. 2014). However, it is also to be noted that if those
properties are not controlled in an effective way, they could present severe hazards to the
workers working with them and also to the adjacent activities and materials. Like, for
example, the risk of burns, eye damage and the risks of material surfaces to get damaged.
This paper will present a brief jest of risks, hazards and control measures associated with the
laser safety. The main purpose of this report is to provide general information and some
practical guidance on the working conditions in an aim to lead to high standards of the safety
for all the personnel that are involved in the maintenance and operation of laser devices.
Discussion
Risk management
1. Knowledge about the standards, practice guidelines and regulations
The international standards regarding the laser safety are all available through the IEC
(International Electrotechnical Commission), documents 60825, 60825- Part 8 and 60601
(Smalley 2013). All these standards are worldwide benchmarks for the laser safety and
consist of the informative and normative guidance for the professional clinicians, laser use
3LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
facility administrator, and manufacturers of the laser use facilities. In some of the countries
such as in Australia and Canada, these standards are coordinated with the national standards
and are also made mandatory as the starting point for all the professional recommended
practices and the additional regulations. The standards are though non-regulatory but they
serve as the consensus documents for the best practise. In Australia, the 4173 (guide to safe
use of lasers in the health care) and AS/NZ 2211 (Laser safety) has become the standards for
the laser safety in all the healthcare centres (Kaushal, Jain and Kar 2017). They have taken on
the affect of the regulation through its world wide acceptance. These standards have been
incorporated into the state regulations like the ones adopted in Western Australia and
Tasmania under the Radiation Safety Act of 1999 (Olsen et al. 2015). Also, in the United
States, there are number of states that have regulations needing registration of the laser
systems, and proof of the administrative controls as it is defined in the ANSI Z136.3
(American National Standard). These ANSI standards are the base for the laser safety
requirements as it is determined by the OSHA (Occupational Safety and Health
Administration), the governmental branch of ‘Department of Labour’. They carry the power
to issue the legal and citations action for the non-compliance.
Similarly, in Europe the guidelines listed in the document of IEC-60825 offers non-
regulatory guidelines for the control and identification of the major hazards that are in
relation with the medical lasers (Smalley 2013). Also, the document of 60825- part 8 too
contains much more informative sections with the expanded illustrative processes that are
focused on the laser users and is indeed a very helpful for the safety management and policy
development (Oswal, Moseley and Smalley 2014).
The laser users must possess working knowledge about all the technical materials
which included the nominal ovular hazard area, the limits of exposure, classifications etc. The
clinicians can make use of the services of the medical physicist, a LPA (Laser Protection
facility administrator, and manufacturers of the laser use facilities. In some of the countries
such as in Australia and Canada, these standards are coordinated with the national standards
and are also made mandatory as the starting point for all the professional recommended
practices and the additional regulations. The standards are though non-regulatory but they
serve as the consensus documents for the best practise. In Australia, the 4173 (guide to safe
use of lasers in the health care) and AS/NZ 2211 (Laser safety) has become the standards for
the laser safety in all the healthcare centres (Kaushal, Jain and Kar 2017). They have taken on
the affect of the regulation through its world wide acceptance. These standards have been
incorporated into the state regulations like the ones adopted in Western Australia and
Tasmania under the Radiation Safety Act of 1999 (Olsen et al. 2015). Also, in the United
States, there are number of states that have regulations needing registration of the laser
systems, and proof of the administrative controls as it is defined in the ANSI Z136.3
(American National Standard). These ANSI standards are the base for the laser safety
requirements as it is determined by the OSHA (Occupational Safety and Health
Administration), the governmental branch of ‘Department of Labour’. They carry the power
to issue the legal and citations action for the non-compliance.
Similarly, in Europe the guidelines listed in the document of IEC-60825 offers non-
regulatory guidelines for the control and identification of the major hazards that are in
relation with the medical lasers (Smalley 2013). Also, the document of 60825- part 8 too
contains much more informative sections with the expanded illustrative processes that are
focused on the laser users and is indeed a very helpful for the safety management and policy
development (Oswal, Moseley and Smalley 2014).
The laser users must possess working knowledge about all the technical materials
which included the nominal ovular hazard area, the limits of exposure, classifications etc. The
clinicians can make use of the services of the medical physicist, a LPA (Laser Protection
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4LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Advisor), a LSO (Laser Safety Officer) or any company that is specialised in the laser safety
in order to assess technical issues such as accident investigation.
2. Identification of the Risks and Hazards
To assess the potential risks and hazards of the exposure to the hazardous levels
of laser emission, it is very important for both the operator and the user to have
thorough knowledge and understanding of the laser science. The laser science
includes:
Properties of the laser light
The absorbing chromosomes of every wavelength
Characteristics of the wave length
Dosimeter (power density, energy density, pulse parameters, power etc)
Delivery systems, spot size and instrumentation
Application techniques (medical and surgical)
When all of the above mentioned attributes are nicely understood, clinician
could then anticipate the potential risks and hazards and (Parandoush and Hossain
2014). Once the potential hazards are recognised, the risk can be assessed.
3. Implementation of the control measures and establishing control measures
Control measures are referred to the actions that are taken by the healthcare personnel
in order to prevent the exposure or injury to the identified hazards (Hoyos and Zimolong
2014). Once the risks based on the hazards is identified as well as the potential of the
exposure to those risks are been assessed, the users could then able to develop control
Advisor), a LSO (Laser Safety Officer) or any company that is specialised in the laser safety
in order to assess technical issues such as accident investigation.
2. Identification of the Risks and Hazards
To assess the potential risks and hazards of the exposure to the hazardous levels
of laser emission, it is very important for both the operator and the user to have
thorough knowledge and understanding of the laser science. The laser science
includes:
Properties of the laser light
The absorbing chromosomes of every wavelength
Characteristics of the wave length
Dosimeter (power density, energy density, pulse parameters, power etc)
Delivery systems, spot size and instrumentation
Application techniques (medical and surgical)
When all of the above mentioned attributes are nicely understood, clinician
could then anticipate the potential risks and hazards and (Parandoush and Hossain
2014). Once the potential hazards are recognised, the risk can be assessed.
3. Implementation of the control measures and establishing control measures
Control measures are referred to the actions that are taken by the healthcare personnel
in order to prevent the exposure or injury to the identified hazards (Hoyos and Zimolong
2014). Once the risks based on the hazards is identified as well as the potential of the
exposure to those risks are been assessed, the users could then able to develop control
5LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
measures as well as implement them. These measures generally translate into the procedures
and policies which have clear statement of the scopes and rationale.
Each of the policies must be updated annually, when the new accessories, clinical
applications or systems are introduced. It must also consider whenever a new standard or
regulation is been published. The main responsibility of the LSO is to enforce the compliance
along with all the control measures.
Basically, there are three types of control measures- procedural controls, engineering
controls and administrative controls-
Procedural controls- It refers to the procedures and policies in the healthcare facilities
(Nolan 2014). These are mainly the operational activities that are specific to the
practice and equipment and they include the flammability hazard prevention, ocular
protection, control of the electrical hazards, controlled access, control of the beam
emissions, control of the system of delivery and the management of the plume.
Engineering controls- These are the inbuilt safety features that are provided by the
manufacturers who are in compliance with the FDA and IEC standards (McHugh et al
2013). They include guarded footswitch, visible and audible emission, and housing
interlocks, stand by controls, beam attenuators and emergency off control.
Administrative controls- These are the infrastructure of the laser safety program. It is
to be noted that they must be in the place right before laser could be used and they
include the LSC, LSO, training and education of all the personnel, development of the
documentation tools, technical management plan and development of the formal audit
(Smalley 2018). There are often reviewed by the OSHA, TJC or the state health
departments.
measures as well as implement them. These measures generally translate into the procedures
and policies which have clear statement of the scopes and rationale.
Each of the policies must be updated annually, when the new accessories, clinical
applications or systems are introduced. It must also consider whenever a new standard or
regulation is been published. The main responsibility of the LSO is to enforce the compliance
along with all the control measures.
Basically, there are three types of control measures- procedural controls, engineering
controls and administrative controls-
Procedural controls- It refers to the procedures and policies in the healthcare facilities
(Nolan 2014). These are mainly the operational activities that are specific to the
practice and equipment and they include the flammability hazard prevention, ocular
protection, control of the electrical hazards, controlled access, control of the beam
emissions, control of the system of delivery and the management of the plume.
Engineering controls- These are the inbuilt safety features that are provided by the
manufacturers who are in compliance with the FDA and IEC standards (McHugh et al
2013). They include guarded footswitch, visible and audible emission, and housing
interlocks, stand by controls, beam attenuators and emergency off control.
Administrative controls- These are the infrastructure of the laser safety program. It is
to be noted that they must be in the place right before laser could be used and they
include the LSC, LSO, training and education of all the personnel, development of the
documentation tools, technical management plan and development of the formal audit
(Smalley 2018). There are often reviewed by the OSHA, TJC or the state health
departments.
6LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
A well written safety plan must be kept in a book mentioned at the laser use site. It must
be noted that the book should contain all the policies and procedures along with the safety set
up checklists, credentials roster, audit reports etc. It is also to be ensured that each and
everyone should become familiar with this book.
The Laser Safety Officer
The Laser Safety Officer or LSO is the person who has the responsibility for managing
the risk and he has the power to ensure compliance with every applicable rules and standards
(Marendaz, Suard and Meyer 2013). Hence, a LSO must to be competent enough to assess all
the systems as well as to validate the skills and knowledge of the personnel who are engaged
in laser practise. It is to be noted that a LSO could be an infection control officer or an
occupational health and safety officer or any safety consultant. He just has to be properly
qualified in this field. However, the duties the LSO varies based on the scope and size of
laser facility but the standards require LSOs to be responsible for the following:
Evaluation of the hazard
Advising the facility administration
Approving the labels and the signange
Investigating the incidents and accidents
Authorization of the service providers and the laser technicians
Maintaining and approving the protective equipments
Implement proper control measures
Ensuring that audits are conducted on a regular basis as well as are documented and
followed up
Ensuring that every staff is well trained and educated on the safety measures (Sliney
and Mellerio 2013)
A well written safety plan must be kept in a book mentioned at the laser use site. It must
be noted that the book should contain all the policies and procedures along with the safety set
up checklists, credentials roster, audit reports etc. It is also to be ensured that each and
everyone should become familiar with this book.
The Laser Safety Officer
The Laser Safety Officer or LSO is the person who has the responsibility for managing
the risk and he has the power to ensure compliance with every applicable rules and standards
(Marendaz, Suard and Meyer 2013). Hence, a LSO must to be competent enough to assess all
the systems as well as to validate the skills and knowledge of the personnel who are engaged
in laser practise. It is to be noted that a LSO could be an infection control officer or an
occupational health and safety officer or any safety consultant. He just has to be properly
qualified in this field. However, the duties the LSO varies based on the scope and size of
laser facility but the standards require LSOs to be responsible for the following:
Evaluation of the hazard
Advising the facility administration
Approving the labels and the signange
Investigating the incidents and accidents
Authorization of the service providers and the laser technicians
Maintaining and approving the protective equipments
Implement proper control measures
Ensuring that audits are conducted on a regular basis as well as are documented and
followed up
Ensuring that every staff is well trained and educated on the safety measures (Sliney
and Mellerio 2013)
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7LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Procedural Control Measures
The controlling hazards in the room of laser treatment generally depends on the
controlled access to the equipments and room, monitoring the testing operations of the laser
as well as its system of delivery and appropriate use of the personal protective devices.
Controlled Access
The controlled access is built on the determination or identification of the NOHA
(Nominal Ocular Hazard Area) or the NHZ (Nominal Hazard Zone) (Stewart et al. 2013). It
is the area in which the exposure level to the laser radiation could exceed MPE (Maximum
Permissible Exposure). However, it is to note that both NHZ and NOHA refer to the
mathematical calculation.
Ocular Hazards
The levels of the Ocular injury are firm about the interaction with the tissues and the
absorption of the chromosomes which are there in the structure that are bare.
The long wavelengths are absorbed by the water in the tissues and therefore, they
could be absorbed at the tear layer that covers the cornea of the eye (Sacca, Roszkowska and
Izzotti 2013). When water is vaporised away, beam interacts with the cornea’s tissues in
Procedural Control Measures
The controlling hazards in the room of laser treatment generally depends on the
controlled access to the equipments and room, monitoring the testing operations of the laser
as well as its system of delivery and appropriate use of the personal protective devices.
Controlled Access
The controlled access is built on the determination or identification of the NOHA
(Nominal Ocular Hazard Area) or the NHZ (Nominal Hazard Zone) (Stewart et al. 2013). It
is the area in which the exposure level to the laser radiation could exceed MPE (Maximum
Permissible Exposure). However, it is to note that both NHZ and NOHA refer to the
mathematical calculation.
Ocular Hazards
The levels of the Ocular injury are firm about the interaction with the tissues and the
absorption of the chromosomes which are there in the structure that are bare.
The long wavelengths are absorbed by the water in the tissues and therefore, they
could be absorbed at the tear layer that covers the cornea of the eye (Sacca, Roszkowska and
Izzotti 2013). When water is vaporised away, beam interacts with the cornea’s tissues in
8LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
order to cause burns. Though it is temporary but still, it can be very painful and can led to
temporarily disabling. The mid ranged infrared could partially absorb and still they can
partially transmit via water and it also has the potential to cause injury to the lens and cornea,
though not to retina (Mallet and Rochette 2013). Furthermore, the short wave lengths
penetrate through the water and they can transmit all the structures that are anterior of the
eye, thereafter absorbing the haemoglobin present in the retina and causing a permanent
damage to the vision of the eye (Taylor et al. 2015).
Protective eyewear that are specially designed for the management of the wavelength
and the classification of laser that are in use must always be worn along with other safety
controls which might be in the place in order to make sure that the person would not be
exposed to the laser energy that are in surplus of the MPE (Roberts, Kruse and Stoll 2013).
Hence, everyone who works in the laser treatment room must wear proper protective eyewear
all the times when a laser is in use. The exception to this is only when any physician is
working on a filtered microscope.
order to cause burns. Though it is temporary but still, it can be very painful and can led to
temporarily disabling. The mid ranged infrared could partially absorb and still they can
partially transmit via water and it also has the potential to cause injury to the lens and cornea,
though not to retina (Mallet and Rochette 2013). Furthermore, the short wave lengths
penetrate through the water and they can transmit all the structures that are anterior of the
eye, thereafter absorbing the haemoglobin present in the retina and causing a permanent
damage to the vision of the eye (Taylor et al. 2015).
Protective eyewear that are specially designed for the management of the wavelength
and the classification of laser that are in use must always be worn along with other safety
controls which might be in the place in order to make sure that the person would not be
exposed to the laser energy that are in surplus of the MPE (Roberts, Kruse and Stoll 2013).
Hence, everyone who works in the laser treatment room must wear proper protective eyewear
all the times when a laser is in use. The exception to this is only when any physician is
working on a filtered microscope.
9LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
Electrical Hazards
Lasers are the electrical devices and therefore they should be handled with same
caution and safety measures as any other electrical device but there are some individual users
who completely overlook this matter. It should always be remembered that every electrical
safety measures and procedures must be followed as well as a safety plan that is well
responsive to the fire must be in the right place and they must include in the staff education
programs.
The laser operator must examine the unit during the set up and the testing in order to
ensure that all the electrical cords, chargers, connections and plugs are intact and are also in a
safe working condition.
4. Audit for Safety Program Monitoring
Education and Training
Proper education and training equip clinicians with a foundation of information and
knowledge is required to establish an environment that is laser safe. It is the responsibility of
an individual practitioner or facility to establish criteria that is acceptable and at the same
time, is credentialing. Along with this, some courses that offers written tests and validates
certain knowledge level must be validated with the own equipments of the users in a proper
Electrical Hazards
Lasers are the electrical devices and therefore they should be handled with same
caution and safety measures as any other electrical device but there are some individual users
who completely overlook this matter. It should always be remembered that every electrical
safety measures and procedures must be followed as well as a safety plan that is well
responsive to the fire must be in the right place and they must include in the staff education
programs.
The laser operator must examine the unit during the set up and the testing in order to
ensure that all the electrical cords, chargers, connections and plugs are intact and are also in a
safe working condition.
4. Audit for Safety Program Monitoring
Education and Training
Proper education and training equip clinicians with a foundation of information and
knowledge is required to establish an environment that is laser safe. It is the responsibility of
an individual practitioner or facility to establish criteria that is acceptable and at the same
time, is credentialing. Along with this, some courses that offers written tests and validates
certain knowledge level must be validated with the own equipments of the users in a proper
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10LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
manner in their clinical workplace. It is to be ensured that the education that is to be provided
to the users must be an on-going process in order to stay in track with the technology through
conferences, networking, professional organisations and journals.
Documentation
Of all the safety procedures and measures, the most important is the documentation
and it should become one of the priorities. Audit reports, logos, policies, operative records,
maintenance records and repair everything contribute to the claims that clinician has enforced
laser safety practice (Smallwood 2013). In absence of accurate documentation, there is no
sustainable support or factual objective for that claim. Incomplete and inaccurate
documentation is an area that falls under the liability for most laser clinicians all round the
world. Much more attention is being placed on the compliance with the known standards of
safety, and compliance with and knowledge of, standards is an indispensable. Hence,
documentation is very important to include in formal audit process along with an emphasis on
identifying the areas that are not being completed accurately with the mentioning of the
recommendations for the remedies as well.
Conclusion
To sum up it can be said that lasers are potent to produce powerful beam of light that
can harm the eye permanently and generate any other associated hazards. The lens of the
human eye concentrates on the light energy through focusing the light on small part of the
retina and the result could be microscopic burn that can cause permanent or temporary blind
spot on the eye. Hence, it is very important to take proper safety measures in order to avoid
such conditions.. The safety precautions must include every control measures and knowledge
about the safe laboratory design along with personal protection equipments.
manner in their clinical workplace. It is to be ensured that the education that is to be provided
to the users must be an on-going process in order to stay in track with the technology through
conferences, networking, professional organisations and journals.
Documentation
Of all the safety procedures and measures, the most important is the documentation
and it should become one of the priorities. Audit reports, logos, policies, operative records,
maintenance records and repair everything contribute to the claims that clinician has enforced
laser safety practice (Smallwood 2013). In absence of accurate documentation, there is no
sustainable support or factual objective for that claim. Incomplete and inaccurate
documentation is an area that falls under the liability for most laser clinicians all round the
world. Much more attention is being placed on the compliance with the known standards of
safety, and compliance with and knowledge of, standards is an indispensable. Hence,
documentation is very important to include in formal audit process along with an emphasis on
identifying the areas that are not being completed accurately with the mentioning of the
recommendations for the remedies as well.
Conclusion
To sum up it can be said that lasers are potent to produce powerful beam of light that
can harm the eye permanently and generate any other associated hazards. The lens of the
human eye concentrates on the light energy through focusing the light on small part of the
retina and the result could be microscopic burn that can cause permanent or temporary blind
spot on the eye. Hence, it is very important to take proper safety measures in order to avoid
such conditions.. The safety precautions must include every control measures and knowledge
about the safe laboratory design along with personal protection equipments.
11LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
References:
Debord, B., Alharbi, M., Vincetti, L., Husakou, A., Fourcade-Dutin, C., Hoenninger, C.,
Mottay, E., Gérôme, F. and Benabid, F., 2014. Multi-meter fiber-delivery and pulse self-
compression of milli-Joule femtosecond laser and fiber-aided laser-micromachining. Optics
express, 22(9), pp.10735-10746.
Hoyos, C.G. and Zimolong, B.M., 2014. Occupational safety and accident prevention:
behavioral strategies and methods(Vol. 11). Elsevier.
Kaushal, H., Jain, V.K. and Kar, S., 2017. Overview of Wireless Optical Communication
Systems. In Free Space Optical Communication (pp. 1-39). Springer, New Delhi.
Mallet, J.D. and Rochette, P.J., 2013. Wavelength-dependent ultraviolet induction of
cyclobutane pyrimidine dimers in the human cornea. Photochemical & Photobiological
Sciences, 12(8), pp.1310-1318.
Marendaz, J.L., Suard, J.C. and Meyer, T., 2013. A systematic tool for Assessment and
Classification of Hazards in Laboratories (ACHiL). Safety science, 53, pp.168-176.
McHugh, M., McCaffery, F., MacMahon, S.T. and Finnegan, A., 2013. Improving safety in
medical devices from concept to retirement. In Handbook of Medical and Healthcare
Technologies (pp. 453-480). Springer, New York, NY.
Nolan, D.P., 2014. Handbook of fire and explosion protection engineering principles: for oil,
gas, chemical and related facilities. William Andrew.
Olsen, C.M., Wilson, L.F., Green, A.C., Bain, C.J., Fritschi, L., Neale, R.E. and Whiteman,
D.C., 2015. Cancers in Australia attributable to exposure to solar ultraviolet radiation and
prevented by regular sunscreen use. Australian and New Zealand journal of public
health, 39(5), pp.471-476.
References:
Debord, B., Alharbi, M., Vincetti, L., Husakou, A., Fourcade-Dutin, C., Hoenninger, C.,
Mottay, E., Gérôme, F. and Benabid, F., 2014. Multi-meter fiber-delivery and pulse self-
compression of milli-Joule femtosecond laser and fiber-aided laser-micromachining. Optics
express, 22(9), pp.10735-10746.
Hoyos, C.G. and Zimolong, B.M., 2014. Occupational safety and accident prevention:
behavioral strategies and methods(Vol. 11). Elsevier.
Kaushal, H., Jain, V.K. and Kar, S., 2017. Overview of Wireless Optical Communication
Systems. In Free Space Optical Communication (pp. 1-39). Springer, New Delhi.
Mallet, J.D. and Rochette, P.J., 2013. Wavelength-dependent ultraviolet induction of
cyclobutane pyrimidine dimers in the human cornea. Photochemical & Photobiological
Sciences, 12(8), pp.1310-1318.
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Sayre, J., Hubschman, J.P., Deng, S. and Brown, E.R., 2015. THz and mm-wave sensing of
Oswal, V., Moseley, H. and Smalley, P., 2014. Risk management in laser technology:
Primum non nocere–First do no harm. Principles and Practice of Lasers in
Otorhinolaryngology and Head and Neck Surgery, p.29.
Parandoush, P. and Hossain, A., 2014. A review of modeling and simulation of laser beam
machining. International journal of machine tools and manufacture, 85, pp.135-145.
Roberts, D.B., Kruse, R.J. and Stoll, S.F., 2013. The effectiveness of therapeutic class IV (10
W) laser treatment for epicondylitis. Lasers in surgery and medicine, 45(5), pp.311-317.
Sacca, S.C., Roszkowska, A.M. and Izzotti, A., 2013. Environmental light and endogenous
antioxidants as the main determinants of non-cancer ocular diseases. Mutation
Research/Reviews in Mutation Research, 752(2), pp.153-171.
Sliney, D.H. and Mellerio, J., 2013. Safety with lasers and other optical sources: a
comprehensive handbook. Springer Science & Business Media.
Smalley, P.J., 2013. Laser safety: regulations, standards, and guidelines for practice.
In Lasers for Medical Applications (pp. 725-759).
Smalley, P.J., 2018. Keys to Building a Safe and Effective Healthcare Laser Program. LASER
THERAPY, 27(1), pp.11-20.
Smallwood, R.F., 2013. Managing electronic records: Methods, best practices, and
technologies (Vol. 592). John Wiley & Sons.
Stewart, N., Lim, A.C., Lowe, P.M. and Goodman, G., 2013. Lasers and laser‐like devices:
Part one. Australasian Journal of Dermatology, 54(3), pp.173-183.
Taylor, Z.D., Garritano, J., Sung, S., Bajwa, N., Bennett, D.B., Nowroozi, B., Tewari, P.,
Sayre, J., Hubschman, J.P., Deng, S. and Brown, E.R., 2015. THz and mm-wave sensing of
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13LASER SAFETY: RISKS, HAZARDS AND CONTROL MEASURES
corneal tissue water content: Electromagnetic modeling and analysis. IEEE transactions on
terahertz science and technology, 5(2), pp.170-183.
corneal tissue water content: Electromagnetic modeling and analysis. IEEE transactions on
terahertz science and technology, 5(2), pp.170-183.
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