1. DH102: Clinic II Ultrasonic Scaling
Lisa Mayo, RDH, BSDH
Concorde Career College

2. Reference
Nield: CH 25&26
Wilkins CH39: Nonsurgical Periodontal Instrumentation
You will need to read both Nield chapters, test questions will come from power point as well as the reading!

4. Topics for today History of Power instruments Mode of action
Mechanism of action
Limitations
Contraindications
Occupational risks
Types
Controls
Calculus removal
Clinical steps

5. Powered Instruments
Rapidly vibrating tip to dislodge calculus from the tooth surface, disrupt plaque and biofilm and flush out bacteria
Technology been around since 1950s
Started as sonic scalers
Now have ultrasonic and piezo technology
Parts
Handpiece that attaches to dental unit
Interchangeable tips
Power supply

6. Handpiece and Tip

7. Interchangeable Tip

8. Tip In action

9. Objective #1 History of power instruments

10. Objective #2 Mode of action

11. 2. Mode of action
Mechanical vibration
Power-driven scaling devices convert electrical energy (ultrasonic) or air pressure (sonic) into high-frequency sound waves
Sound waves produce rapid vibrations in the specially designed scaling tips
Calculus is incrementally shattered from the tooth surface when the vibrations are applied to the deposit

12. Water Irrigation/Lavage
2. Mode of action
Water Irrigation/Lavage
Water is required to dissipate the heat produced at the vibrating tip
Occurs when the water meets the vibrating tip
Minute bubbles are created that collapse and release energy
Little influence on hard deposit removal
Capable of destroying surface bacteria
Remove endotoxins from the root surface
Better vision in bleeding sulcus

13. Acoustic Microstreaming of the Water
2. Mode of action
Water Irrigation:
Acoustic Microstreaming of the Water
Swirling effect produced within the confined space of a periodontal pocket by the continuous stream of fluid flowing over the vibrating tip
May play a role in the disruption of sub-g plaque biofilms assoc w/ perio disease
Limited to an area immediately surrounding the instrument tip
In order to most effectively remove plaque biofilm – tip must touch every part of the root surface

14. Water Irrigation: Cavitation of the Water
2. Mode of action
Water Irrigation: Cavitation of the Water
Formation of tiny bubbles in water stream
Energy release that occurs when tiny bubbles in the fluid spray collapse
When bubbles collapse, they produce shock waves that alter or destroy bacteria by tearing the bacterial cell walls

15. Pocket penetration of tip & water

16. Review
The water spray in ultrasonic and sonic scaling devices penetrates to the base of the pocket to provide a continuous flushing of debris, bacteria, and endotoxin. Oscillation of the ultrasonic tip causes hydrodynamic waves to surround the tip; this acoustic turbulence is believed to have a disruptive effect on surface bacteria. A) The first statement is true and the second statement is true B) The first statement is false and the second statement is false C) The first statement is true and the second statement is false D) The first statement is false and the second statement is true

17. Answer
A) The first statement is true and the second statement is true is the correct answer. In ultrasonic scalers, water spray acts as a lavage to flush debris from the base of the pocket; tip oscillation causes acoustic turbulence resulting in disruption of bacteria.

18. Objective #3 Mechanism of Action

19. How effectively instrument runs determined by:
3. Mechanism of action
How effectively instrument runs determined by:
Tips vibration frequency
Stroke length
Stroke motion
Surface of the instrument tip in contact
with the tooth .

20. 3. Mechanism of action Frequency
Measure of how many times the electronically powered instrument tip vibrates per second
Can be compared to windshield wipers on a car
Low Frequency: wiper setting on low, go back and forth few times in a min = tip vibrates fewer times per sec
High Frequency: wipers back and forth multiple times per min = tip vibrates more times per sec

21. 3.Mechanism of action amplitude
Amplitude or stroke measures how far the instrument tip moves back and forth during one stroke cycle
Ultrasonic devises have a power knob that is used to change the length of the stroke (strength)
Higher amplitude delivers a longer, more powerful stroke
Lower amplitude delivers short, less powerful stroke

22. Frequency/Amplitude http://www.youtube.com/watch?v=iNcKT4uJZBY
Frequency: 0-1min
Amplitude: 2-3min

23. 3. Mechanism of action Cleaning efficiency
Combo of frequency and amplitude
Frequency = determines # vibrations
Amplitude = determines length of each stroke
Rule of thumb = use lowest setting (frequency) to achieve goal
For a Dentsply cavitron – will live in BLUE setting
Gray setting a power BOOST setting and should ONLY be used for gross/heavy calculus
If vibrates too fast = will skim over calculus on roots without removing

24. 3. Mechanism of action Strength of power instruments
Effective calculus removal and plaque biofilm
Effective at deplaquing
Disrupt or remove sub-g plaque biofilm from root surfaces and pocket space
Pocket penetration
Can penetrate deeper than many instruments
Access to Furcations
Class II & III better access with slim line tips
Irrigation (Lavage)
Wash toxic products & free-floating bacteria from pocket
Improve vision
Shorter instrumentation time than hand instruments (shorter, not better!)

25. Objective #4 Limitations of power instruments

26. 4. Limitations of power instruments
Clinician skill level
Skill level more important than power vs hand
Very technique sensitive like hand instruments
Have to have complete understanding of root anatomy
Reduced tactile sensitivity
Occupational risks
Infection control: some components CANNOT be sterilized
Aerosol production: high levels
Muscoskeletal & Auditory Damage

27. Objective #5 contraindications

29. Objective #6 Occupational risks

30. 6. Occupational risks contaminated aerosols
Dental aerosols airborne particles that are compromised of debris, microorganisms, blood which are smaller than 50μm
Aerosols stay airborne and float on office air currents moving some distance from the point of origin
Very small particles can remain suspended at the end of the procedure for many hours
Can inhale through nose and intubate in respiratory tree
The mouth contains large numbers of
Stretococci
Staphylococci
Gram (-) bacteria
Viruses

31. 6. Occupational risks contaminated aerosols
Power ultrasonic instrum. are the greatest produces of small-particle aerosol contamination in dentistry!!!
Can suspend blood particles!!
Preventive measures
Barrier protection
High volume suction: can reduce up to 90-98% aerosols
Saliva ejector does not substitute as HVE
Isolite: can be difficult to use, patients not always like
Pre-procedural rinse: CHX or Listerine for 1min

32. isolite

33. 6. Occupational risks musculoskeletal damage
Nerve damage from dental instruments that cause vibration
Blunt the sense of touch
Muscle weakness
Reduction strength and tactile sensitivity due to vibration

34. 6. Occupational risks Hearing loss
Research ongoing!
Tinnitus: early stage of hearing loss
Hearing protection devises has been an emerging science
Custom earplugs like musicians use
Can still hear patient but drowns out high-pitch frequencies

35. Objective #7 Types of power instruments

36. 7. Types of power instruments

37. 7. Types of power instruments
Sonic
Low frequency
3,000-8,000 cycles per sec (Hz)
Driven by compressed air from dental unit
No heat is generated so little water used as a lavage
Not good use for heavy deposits

38. 7. Types of power instruments
Ultrasonic: 18,000-50,000 cycles per sec
Piezoelectric
Use electric energy to activate crystals within the handpiece to vibrate the tip
Magnetostrictive
Transfer electrical energy to metal stacks made of nickel-iron alloy or to a ferrous rod

39. 7. Types of power instruments

40. 7. Types of power instruments sonic
Handpiece that attached to dental unit high-speed handpiece and interchangeable tips

41. 7. Types of power instruments Sonic Scaling Devices
Tip activation
Tip motion: Driven by compressed air from the dental unit rather than electrical energy. Moves in an elliptical pattern. All surfaces of the tip are active.
Amplitude. Less powerful than ultrasonic scalers
Frequency. Producing vibrations at the tip; range between 2,500 and 7,000 cps. Because of fewer vibrations produced, calculus removal is more difficult.
Water source. Water is required to cool the friction between the instrument tip and the tooth surface. Heat is not generated by the scaling tip.

42. 7. Types of power instruments Ultrasonic piezo
Portable electronic generator
Handpiece
Instrument tips

43. 7. Types of power instruments Piezoelectric Ultrasonic Scalers
Composition
Ceramic rod in handpiece
Activation
Dimensional changes in quartz or metal
alloy crystal transducers housed in handpiece
Tip motion
Moves in a linear pattern, forward and backward
Only the lateral surfaces of the tip are active
Handpiece position will adjust at each line angle to maintain adaptation of the lateral surface of the tip to the tooth

44. 7. Types of power instruments Piezoelectric Ultrasonic Scalers
Technique
Placement and movement of the tip is specific
Position the lateral surface of the tip in contact with the tooth
Use only the terminal 2-4 mm of the tip’s lateral surface
Keep terminal lateral surface adapted at all times around curvatures and line angles using wrist pivot
Tip shape
Cross section of tip varies from trapezoidal with angular edges to round or bladed
Frequency
Varies according to manufacturer
# of times per second a tip moves back and forth during one cycle
Ranges from 25,000 to 50,000 cps

45. 7. Types of power instruments Magnetostrictive Ultrasonic
Portable unit
Electronic generator
Handpiece
Interchangeable tips/inserts
Available in 25-kHz or 30-kHz

46. 7. Types of power instruments 25K: inserts longer and thicker

47. 7. Types of power instruments Magnetostrictive Inserts
Metal Stack: converts electrical power into mechanical O-Ring: seal that keeps water flowing through the insert rather than flowing out of the handpiece Handle grip: portion of the insert grasped by the clinician during instrumentation Water outlet: provides water to the instrument Working-End: used for calculus removal
You will need to be able to list all 5 parts of insert for Quiz!

49. 7. Types of power instruments Tips
Variety of designs and functions
Different tips from different manufacturers not always interchangeable
2 Basic Types
Standard-Diameter
Larger in size
Shorter shank lengths
Similar to sickle scalers or universal Columbia 13/14
Slim-Diameter
40% smaller diameter
Longer, more complex shanks
Similar to area-specific curets

50. 7. Types of power instruments Standard Diameter

51. 7. Types of power instruments Slim Diameter

52. 7. Types of power instruments Tip wear & replacement
Rule of thumb = 1mm of wear results in 25% loss of efficiency
2mm wear = 50% loss of efficiency
Inspect for signs of wear frequently
Prevent from bending or will not work correctly
Bag correctly: always place insert “BUTT-FIRST” into a bag
Tips fragile, esp slim and ultra-slim designs
Can easy bend/break
If insert into unit while tip still hot – will bend as well

53. 7. Types of power instruments Tip Selection
Select based on size, shape, diameter, length, curvature – just like hand instruments
Calculus size and location

54. 7. Types of power instruments Tip selection & sequence of use
Standard Diameter Tips
Supra deposits
Mod to heavy sub-g
Extrinsic stain
Medium power
Straight Slim Diameter Tips
Lt to mod deposits anterior teeth and post deposits sub-g
Deep pockets
Root scaling
Low to medium power
Curved Slim Diameter Tips
Lt to mod calculus deposits on post roots
Deeper pockets
Low power

55. 7. Types of power instruments Curved insert

56. 7. Types of power instruments Standard tip

57. 7. Types of power instruments tips

58. 7. Types of power instruments tips

59. 7. Types of power instruments Tips
Set of Slim-Diameter Tips
Straight
Rt-Curved
Lf-Curved
Straight: similar to perio probe
Curved: similar to Naber’s probe

61. Objective #8 controls

62. 8. Controls Controls to adjust water and power
Some allow to control frequency: Manually Tunes Ultrasonic

63. 8. Controls Power Determine length of stroke
Distance instrument travels back and forth in one cycle
Higher = longer, more forceful stroke
More uncomfortable for patient
More likely to damage tooth surface
Lower = shorter, less powerful stroke
Recommended
SLOWER IS BETTER!!!
Most slim and ultra slim CANNOT be used on higher power settings = risk of breakage

64. 8. Controls Tips that can be used on high power settings

65. 8. Controls Frequency Automatic: We have in clinic
2 control knobs: power and water
Clinician can adjust length stroke and water flow
LOW to MED for patient comfort
Water dissipates heat by vibrating tip
Auto = allows the tip to vibrate at a frequency that produces the most effective calculus removal for the selected power setting

66. 8. controls Frequency Manual 3 knows: power, water, tuning
Clinician adjusts length of stroke (strength), tip frequency of vibration (#) and water flow
Can set vibration frequency of the tips at a level above or below the resonant frequency
Disadv: incorrectly tuned = ineffective calculus removal
OLD SCHOOL!

67. 8. Controls frequency, amplitude & water flow
Cools by fluid to prevent overheating of vibrating tip
Water is the coolant
Continuous flow
Disperses in a fine spray at or near the tip
Clinicians can adjust the volume of water supplied to tip
Lower rates of water flow increase heating changes = warmer water at the tip
Too little = heat damage to pulp
More water flow recommended for calculus removal and less water slow for deplaquing

68. 8. Controls Water flow
A: fine mist
B: slow drip

69. 8. Controls frequency, amplitude & water flow
One of most common mistakes by beginning clinicians = using too little water
If handpiece warms up in your hand = water too low
Tip have external or internal flow

70. 8. Controls Internal water flow (Our clinic uses)

71. 8. controls External water flow

72. 8. Controls frequency, amplitude & water flow
Fluid Reservoirs
Some have
Distilled water, sterile saline, stannous fluoride, antimicrobials (CHX)
Not been shown to enhance pocket depth resolve than regular instrumentation
Pathogenic biofilms are highly resistant to antimicrobial agents and systemic antibiotics
Only way to disrupt biofilm = mechanical removal

73. 8. Controls Energy dispersion by working-end
Vibrations from ea surface of working end
Have to adapt correct tip surface to control energy dispersion and patient sensitivity
Dependent on 3 factors (next slides)
Energy output
Pattern of Tip Movement
Adaptation of Powered Tips

74. 8. Controls 1.) Energy output
Face, back, lateral surfaces and point produce different amts of energy
Point of Tip
Produced greatest amt of energy vibrations
NEVER adapt directly on a tooth surface due to potential discomfort for the patient and damage of root surface
Face of Tip (concave surface)
2nd greatest amt of energy vibrations
NOT adapted – would be difficult to do

75. 8. Controls 1.) Energy output
Back of Tip (convex surface)
Produces less energy than the face or the point
3rd greatest amt
Lateral surfaces of tip
Least amt
To be used against tooth surface

76. 8. Controls 1.) Energy output

77. 8. Controls 1.) Energy output

78. 8. Controls 2.) Pattern of tip movement
Tip motion varies from lateral motion to an elliptical motion
Motion is really more dependent on power setting and shape of instrument tip
Elliptical motions appears to be better at efficient calculus removal

79. 8. controls 3.) Adaptation of powered tips
Follow manufacturer directions for instrument tip-to-tooth surface adaptation
The point of tip and face of the tip should never be directly adapted to a tooth surface
Backs of most ultrasonic and sonic instrument tips can be adapted to the tooth surface, following the recommendations of the tip manufacturer

80. 8. controls 3.) Adaptation of powered tipstips
Angle of adaptation: an angle of between 0-15 degrees is recommended for direct adaptation to tooth surfaces
Lateral surfaces of the working end is recommended with sonic, piezoelectric, magnetostrictive ultrasonic
Piezo: tip does not do as much vibration as magnetostrictive, it’s the lateral surfaces that are more effective

81. 8. controls 3.) Adaptation of powered tips
Active tip area: portion of the instruments that is capable of doing work
Power to remove calculus is concentrated in the last 2-4mm of the length of a tip
Test Alert!

82. 8. controls 3.) Adaptation of powered tips & implants
Tip HAS to be made of a material that is softer than titanium because titanium is a soft metal that can easily be damaged by metal instruments
If scratch titanium implant = increase potential for biofilm adhesion by creating a roughened surface
Power tip with nonmetal plastic or carbon tips are appropriate
Some studies show they are more effective than hand-activated plastic instruments

83. 8. controls 3.) Adaptation of powered tips
Adaptation of tip surfaces to the tooth surface
Point and face of a power tip
Back and Lateral surface of a power tip
Orientation of the powered tip to the tooth surface
Transverse tip orientation (Curet Position)
Vertical tip orientation (Probe Position)

84. 8. controls 3.) Adaptation of powered tips
Adaptation of tip surfaces to the tooth surface
Point and face of a power tip
NEVER be directly adapted to a tooth surface
Great caution must be taken with the point of power tip = highest motion and vibration, surface area small = concentrated energy

85. 8. controls 3.) Adaptation of powered tips
Adaptation of tip surfaces to the tooth surface
Back and Lateral surface of a power tip
Magnetostrictive =BACK SURFACE most effective in breaking calculus deposits and LATERAL SURFACES most effective in breaking tenacious calculus deposits
Both can be used for calculus removal=sonic, piezo, magnetostrictive
Last 2-4mm of back and lateral surface=active portion–must be in contact w/tooth at all times and be adapted so that the point is not directed toward the root or against the soft tissue

86. 8. controls 3.) Adaptation of powered tips
Orientation of the powered tip to the tooth surface
Transverse tip orientation (Curet Position)
Length of the tip is positioned with the back or lateral surface in a transverse orientation or at a right angle to the long axis of the tooth
Tip is placed in a similar fashion to a universal curet
Zero degree angulation maintained between back or lateral surface of the tip to tooth
Can be used when removing calculus above or slightly below gingival margin

87. 8. controls 3.) Adaptation of powered tips
Orientation of the powered tip to the tooth surface
Vertical tip orientation (Probe Position)
Length of tip is positioned w/ back or lateral surface in a manner similar to probing
Back or lateral surface of tip at zero degree angulation to root surface
Used for calculus removal and deplaquing shallow to deep pockets

88. 8. controls 3.) Adaptation of powered tips
For a transverse orientation, the power tip is positioned in a similar manner to a curet with the length of the back surface, or lateral surface, at a right angle to the long axis of the tooth

89. 8. controls 3.) Adaptation of powered tips
For a vertical orientation, the powered tip is positioned so the length of the back surface, or lateral surface, is positioned in a manner similar to that of a periodontal probe

90. 8. controls 3.) Adaptation of powered tips
Incorrect adaptation: the point of a power instrument tip should NOT be adapted against a tooth surface. Using a power tip in the manner can gouge cementum and dentin!!

91. 8. controls 3.) Adaptation of powered tips
Correct Adaptation of Lateral Surface in a Transverse Orientation

92. 8. controls 3.) Adaptation of powered tips
Correct adaptation of a lateral surface in a vertical orientation

93. 8. controls 3.) Adaptation of powered tips
Correct adaptation of the back surface in a vertical tip orientation. Use the convex side Will prevent injury to the root surface with the tip

94. 8. controls 3.) Adaptation of powered tips
Tip-to-tooth angulation should be as close to 0°as possible and should never exceed 15°
Root surface will be gouged

95. Objective #9 Calculus removal with power instruments

96. 9. Calculus removal with power tips
Calculus removal technique with Curet
Gracey positioned apical to or below the calculus deposit then vertical stroke coronally or up and away from the tissue
Calculus removal with power tip
Work top of the deposit downward
Start at CEJ and work downward
No need to position the tip beneath the deposit
Great advantage when working in very deep pockets

97. 9. Calculus removal with power tips
Different techniques w/ power instrument tip and a hand-activated instrument
A= power
B=scaler

98. 9. Strokes for calculus removal
Tips break up heavy deposits by putting little microfractures in the deposit
Power tip needs to be moved over the surface of a deposit some time in order to allow the microfractures to develop
Slower, repetitive controlled strokes are more effective in removing large tenacious calculus deposits
Keep tip moving at all times for patient comfort
Oblique, overlapping, vertical most effective
Light pressure
Avoid Horizontal = tendency to burnish calculus into tooth and create a smooth veneer than remove it completely. Why we always follow up cavitron w/hand instruments

99. 9. Strokes for calculus removal

100. 9. Strokes for plaque biofilm removal
2-4mm of tip actively remove biofilm
Gentle, light sweeping strokes in the pocket over the root surface
Short, overlapping strokes will cover every mm of the root
Vertical, oblique or horizontal direction ok
Move tip at all times for patient comfort
Can be a little faster than hand instruments
Must hand instrument after to smooth back the surface ultrasonic roughs up
LOW power setting to avoid removing cementum

101. 9. Sweeping Motion

102. 9. Calculus removal

103. Curved tips Lateral surface adapted to facial

104. Curved tips Lateral surface adapted to facial

105. Curved tips lateral surface adapted to proximal

106. Straight Tips back surface, vertical

107. Straight Tips lateral surface, vertical

108. Straight Tips back surface, vertical

109. Straight Tips back surface, transverse

110. 9. Removing tenacious calculus
Common mistake with beginners is that the power tips will snap the calculus off with one quick swipe
Power tips are not magic wands!!
Take many overlapping strokes just like hand instruments

111. 9. Removing tenacious calculus
Select proper tip for your task: standard, slim, curved, etc..
Use a tip that can withstand medium pressure
Low power may not remove heavy tenacious deposits
Select appropriate water level: water should create a halo effects or light mist with no excessive dripping
Maintain proper control and adaptation
Keep 2-4mm of tip in contact with tooth

112. 9. Removing tenacious calculus
Attack deposit from all directions w/ different strokes
Use correct surface of the powered tip: magnetostrictive vs piezo
Change to a different tip
Begin with a periodontal file first then switch to power
Increase the power if all the above have been utilized first, last resort and make sure select a tip that can withstand higher powers!!

113. 9. Calculus removal Furcation access
Slim tips can be more effective than hand instruments many times in treating Class II and III furcations
Standard gracey’s too wide to enter the furcation areas of over 50% of all maxillary and mand molars
Avg facial furcation entrance of maxillary and mand first molars is from 0.63 – 1.04mm in width
Width of standard Gracey curets ranges from 0.76 – 1mm
Diameter of a modified slim-diameter instrument tip is 0.55mm or less

114. 9. Calculus removal Furcation access

115. 9. Calculus removal Furcation access

116. Objective #10 Clinical steps

118. 10. Clinical steps Fundamentals
Position
Clinician same as for hand instruments
Neutral seated
Patient supine
Patient head to one side so water does not choke them
Grasp
Modified pen grasp of handpiece
Light and relaxed grasp – if have increased lateral pressure, tip will not work as effectively

119. 10. Clinical steps Fundamentals
Finger Rests
Intraoral or advanced finger rest is CRITICAL!!
Lateral Pressure
Light
Moderate or firm – decrease effectiveness of tip or can even stop vibration of the tip
With proper technique, patients will not feel the tip
Motion Activation
Digital activation is recommended because the tip removes the calculus and not the clinician

120. 10. Clinical steps
Just like hand scaling, use explorer to feel for residual calculus deposit
If have an endoscope – helpful for detecting residual calculus

121. 10. Clinical steps Preparation
Dental hygiene care plan
Review medical hx for contraindications
Assess calculus deposits and location
Infection control measures
Personal protective equipment: PPE’s
Face shield to protect from aerosols
Surgical cap to prevent contamination of hair
Change mask every 20min or if it gets moist from aerosols
Flush water lines just like A/W syringe
2min at beginning of day
20-30 sec in between patients

122. 10. Clinical steps Preparation
Plug in power cord to wall
Connect water hose
Fill handpiece with water
Then insert the tip twisting gently until it
snaps into place
Select correct power setting
Select correct water setting
Pre-procedural rinse: Listerine or CHX for 2min

123. 10. Clinical steps Preparation
Point-of-Use Filter
Some ultrasonic devises have preinstalled
Reduced # microorganisms in the water flowing over instrument tip

124. 10. Clinical steps Water containment techniques
Fluid control in anterior sections
Lower and upper lips can be cupped to contain the water spray
Allows the lip to act as a barrier to deflect the water back into the mouth and a “cup” to collect the water

125. 10. Clinical steps Water containment techniques
Fluid control in posterior sections
Hold cheek between thumb and index finger and pull out and up, or down, to form a cup
Creates a “cheek cup” to catch water spray

126. 10. Clinical steps Handpiece cord management
Decrease fatigue of hands
Several techniques to reduce pull of cord

127. 10. Clinical steps Handpiece cord management

128. 10. Clinical steps Handpiece cord management

129. 10. Clinical steps Smoothing amalgam overhangs
Overhang removal is a recontouring procedure used to correct defective margins of restorations to provide a smooth surface that will deter bacterial accumulation
Overhangs act as a biofilm trap
Power tips can be used to remove such as Burnett or Dentsply blue insert

131. 10. Clinical steps Smoothing amalgam overhangs
Both inserts are designed to withstand higher power settings and more lateral pressure than a conventional slim-line
Uses: heavy deposits, overhangs, removing ortho cement