Chapter 24 Dental Unit Waterlines Copyright 2003, Elsevier Science (USA). All rights reserved. No part of this product may be reproduced or transmitted.

Chapter 24Dental Unit Waterlines

Chapter 24Dental Unit Waterlines

Copyright 2003, Elsevier Science (USA).

All rights reserved. No part of this product may be reproduced or transmitted in any form or by any means, electronic or mechanical, including input into or storage in any information system, without permission in writing from the publisher.

PowerPoint® presentation slides may be displayed and may be reproduced in print form for instructional purposes only, provided a proper copyright notice appears on the last page of each print-out.

Produced in the United States of America

ISBN 0-7216-9770-4

Copyright 2003, Elsevier Science (USA). All rights reserved.

Introduction Introduction Outbreaks of waterborne disease have

occurred in a broad range of facilities. Although there is no evidence of a widespread public health problem, published reports have associated illness with exposure to water from dental units. The fact that there are bacteria capable of causing disease in humans found in dental unit waterlines is reason for concern.

Outbreaks of waterborne disease have occurred in a broad range of facilities. Although there is no evidence of a widespread public health problem, published reports have associated illness with exposure to water from dental units. The fact that there are bacteria capable of causing disease in humans found in dental unit waterlines is reason for concern.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Introduction cont’dIntroduction cont’d In community water, the number of waterborne

bacteria is kept below 500 colony-forming units (CFU) per milliliter.

The water from air-water syringes and dental handpieces frequently has bacteria levels that are hundreds or thousands of times greater than is permissible in drinking water.

The types of bacteria that are found in dental unit water are frequently the same types as those found in community water, but the levels of bacteria found in the dental units are almost always higher.

In community water, the number of waterborne bacteria is kept below 500 colony-forming units (CFU) per milliliter.

The water from air-water syringes and dental handpieces frequently has bacteria levels that are hundreds or thousands of times greater than is permissible in drinking water.

The types of bacteria that are found in dental unit water are frequently the same types as those found in community water, but the levels of bacteria found in the dental units are almost always higher.

Copyright 2003, Elsevier Science (USA). All rights reserved.

BackgroundBackground Dental health care workers are exposed to Legionella

bacteria at a much higher rate than the general public.

Dental personnel are exposed to contaminated dental unit waterlines by inhaling the aerosol generated by the handpiece and the air-water syringe.

There is at least one suspected fatality of a dentist from legionellosis.

Case reports have been published of immunocompromised patients who developed postoperative infections caused by contaminated dental water.

Dental health care workers are exposed to Legionella bacteria at a much higher rate than the general public.

Dental personnel are exposed to contaminated dental unit waterlines by inhaling the aerosol generated by the handpiece and the air-water syringe.

There is at least one suspected fatality of a dentist from legionellosis.

Case reports have been published of immunocompromised patients who developed postoperative infections caused by contaminated dental water.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Microorganisms in WaterlinesMicroorganisms in Waterlines The primary source of microorganisms in dental

waterlines is the public water supply. It is possible that saliva may be retracted back into

the waterlines during treatment. This process is also called “suck back.”

Antiretraction valves on dental units and thorough flushing of the dental lines between patients minimize the chance of this occurring.

Entering public water source has a colony forming units (CFU) count of less than 500; once that water enters the dental waterlines and colonizes within the biofilm, the CFU count skyrockets.

The primary source of microorganisms in dental waterlines is the public water supply.

It is possible that saliva may be retracted back into the waterlines during treatment. This process is also called “suck back.”

Antiretraction valves on dental units and thorough flushing of the dental lines between patients minimize the chance of this occurring.

Entering public water source has a colony forming units (CFU) count of less than 500; once that water enters the dental waterlines and colonizes within the biofilm, the CFU count skyrockets.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Communities of BacteriaCommunities of Bacteria There are two “communities” of bacteria in

dental unit waterlines:

• One bacterial community exists in the water itself and is referred to as planktonic (free floating).

• The other exists in the biofilm attached to the walls of the waterlines.

There are two “communities” of bacteria in dental unit waterlines:

• One bacterial community exists in the water itself and is referred to as planktonic (free floating).

• The other exists in the biofilm attached to the walls of the waterlines.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig 24-1 Close up of dental tube opening.Fig 24-1 Close up of dental tube opening.

Fig. 24-1Fig. 24-1

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig. 24-2 A cross-section of a dental unit waterline illustrating the formation of biofilm on the inside wall of a dental tube.Fig. 24-2 A cross-section of a dental unit waterline illustrating the formation of biofilm on the inside wall of a dental tube.

Fig. 24-2Fig. 24-2

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig 24-4 Maze of dental unit lines. Fig 24-4 Maze of dental unit lines.

Fig. 24-4Fig. 24-4

Copyright 2003, Elsevier Science (USA). All rights reserved.

BiofilmBiofilm Biofilm exists in all places where moisture

and a suitable solid surface exist. Biofilm consists of bacterial cells and other

microbes that adhere to surfaces and form a protective slime layer.

Biofilm can contain many types of bacteria, as well as fungi, algae, and protozoa.

Viruses, such as the human immunodeficiency virus (HIV), cannot multiply in the dental unit waterline.

Biofilm exists in all places where moisture and a suitable solid surface exist.

Biofilm consists of bacterial cells and other microbes that adhere to surfaces and form a protective slime layer.

Biofilm can contain many types of bacteria, as well as fungi, algae, and protozoa.

Viruses, such as the human immunodeficiency virus (HIV), cannot multiply in the dental unit waterline.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig. 24-3 Magnification of biofilm formation on the walls of the tube. Fig. 24-3 Magnification of biofilm formation on the walls of the tube.

Fig. 24-3Fig. 24-3

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig. 24-5 Bacteria in biofilm dropping into waterlines. Fig. 24-5 Bacteria in biofilm dropping into waterlines.

Fig. 24-5Fig. 24-5

Copyright 2003, Elsevier Science (USA). All rights reserved.

Methods to Reduce ContaminationMethods to Reduce Contamination

It is not yet possible to totally eliminate biofilm, but it can be minimized by:

• Self-contained water reservoirs

• Chemical treatment regimens

• Microfiltration

• Daily draining and drying of lines

It is not yet possible to totally eliminate biofilm, but it can be minimized by:

• Self-contained water reservoirs

• Chemical treatment regimens

• Microfiltration

• Daily draining and drying of lines

Copyright 2003, Elsevier Science (USA). All rights reserved.

Self-Contained Water Reservoirs Self-Contained Water Reservoirs These systems supply air pressure to the water

bottle (reservoir). The air pressure in the bottle forces the water from

the bottle up into the dental unit water lines (DUWL) and out to the handpiece and air-water syringe.

Self-contained water systems have two advantages:

• The dental personnel can select the quality of water to be used, such as distilled, tap, or sterile.

• Maintenance of the water system (between the reservoir bottle and the handpieces and syringes) is under the control of the dentist and staff.

These systems supply air pressure to the water bottle (reservoir).

The air pressure in the bottle forces the water from the bottle up into the dental unit water lines (DUWL) and out to the handpiece and air-water syringe.

Self-contained water systems have two advantages:

• The dental personnel can select the quality of water to be used, such as distilled, tap, or sterile.

• Maintenance of the water system (between the reservoir bottle and the handpieces and syringes) is under the control of the dentist and staff.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig 24-6 Self-contained dental water unit. Fig 24-6 Self-contained dental water unit.

Fig. 24-6Fig. 24-6

Copyright 2003, Elsevier Science (USA). All rights reserved.

Microfiltration CartridgeMicrofiltration Cartridge A disposable inline microfiltration cartridge

also can dramatically reduce the bacterial contamination in the dental unit water.

This device must be inserted as close to the handpiece or air-water syringe as possible.

It should be replaced at least daily on each line. The use of filtration cartridges combined with water reservoirs can ensure improved water quality.

A disposable inline microfiltration cartridge also can dramatically reduce the bacterial contamination in the dental unit water.

This device must be inserted as close to the handpiece or air-water syringe as possible.

It should be replaced at least daily on each line. The use of filtration cartridges combined with water reservoirs can ensure improved water quality.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Fig. 24-8 Disposable microfiltration filter in place near the handpiece at the end of the waterline.Fig. 24-8 Disposable microfiltration filter in place near the handpiece at the end of the waterline.

Fig. 24-8Fig. 24-8

Copyright 2003, Elsevier Science (USA). All rights reserved.

Chemical AgentsChemical Agents Chemicals can be used to help control biofilm in

two ways:

• Periodic or “shock” treatment with biocidal levels (levels that will kill microorganisms) of chemicals.

• Continuous application of chemicals to the system (at the level to kill the microorganisms but not harm humans).

Always check with the manufacturer of the dental equipment to determine which chemical product and maintenance protocol they recommend.

Chemicals can be used to help control biofilm in two ways:

• Periodic or “shock” treatment with biocidal levels (levels that will kill microorganisms) of chemicals.

• Continuous application of chemicals to the system (at the level to kill the microorganisms but not harm humans).

Always check with the manufacturer of the dental equipment to determine which chemical product and maintenance protocol they recommend.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Water for Surgical ProceduresWater for Surgical Procedures Dental unit water should not be used as an

irrigant for surgery involving the exposure of bone.

Only use sterile water from special sterile water delivery systems or hand irrigation using sterile water in a sterile disposable syringe.

Dental unit water should not be used as an irrigant for surgery involving the exposure of bone.

Only use sterile water from special sterile water delivery systems or hand irrigation using sterile water in a sterile disposable syringe.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Flushing WaterlinesFlushing Waterlines All dental waterlines and handpieces should be

flushed in the mornings and between patients. Although this will not remove biofilms from the

lines, it may temporarily reduce the microbial count in the water.

It will help clean the handpiece waterlines of materials that may have entered from the patient’s mouth.

Flushing also brings a fresh supply of chlorinated water from the main waterlines into the dental unit.

All dental waterlines and handpieces should be flushed in the mornings and between patients.

Although this will not remove biofilms from the lines, it may temporarily reduce the microbial count in the water.

It will help clean the handpiece waterlines of materials that may have entered from the patient’s mouth.

Flushing also brings a fresh supply of chlorinated water from the main waterlines into the dental unit.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Minimize AerosolMinimize Aerosol Always use the high-volume evacuator when

using the high-speed handpiece, ultrasonic scaler, and air-water syringe.

The high-volume evacuation may also reduce exposure of the patient to these waterborne microorganisms.

Always use the high-volume evacuator when using the high-speed handpiece, ultrasonic scaler, and air-water syringe.

The high-volume evacuation may also reduce exposure of the patient to these waterborne microorganisms.

Copyright 2003, Elsevier Science (USA). All rights reserved.

Use Protective BarriersUse Protective Barriers

The dental dam greatly reduces direct contact.

The dam also greatly reduces the aerosolizing and spattering of the patient’s oral microorganisms onto the dental team.

Protective barriers, including masks, eyewear, and face shields, also serve as barriers for the dental team.

The dental dam greatly reduces direct contact.

The dam also greatly reduces the aerosolizing and spattering of the patient’s oral microorganisms onto the dental team.

Protective barriers, including masks, eyewear, and face shields, also serve as barriers for the dental team.