A dental drill or dental handpiece is a hand-held, mechanical instrument used to perform a variety of common dental procedures, including removing decay, polishing fillings, performing cosmetic dentistry, and altering prostheses. The handpiece itself consists of internal mechanical components which initiate a rotational force and provide power to the cutting instrument, usually a dental burr. The type of apparatus used clinically will vary depending on the required function dictated by the dental procedure. It is common for a light source and cooling water-spray system to also be incorporated into certain handpieces; this improves visibility, accuracy and overall success of the procedure. The burrs are usually made of tungsten carbide or diamond.

A high-speed dental handpiece.
Head of the dental drill

High-speed handpiece edit

High-speed handpieces may cut at speeds of up to 180,000 rpm. Depending on their mechanisms, they are classified as air turbine or speed-increasing. However, in a clinical context, air turbine handpieces are commonly referred to as "high-speeds." Handpieces have a chuck or collet, for holding a cutter, called a burr or bur.

Mechanisms edit

Power edit

 
Air turbine used in a dental handpiece
 
Correlation between rotational speed and torque
 
Correlation between rotational speed and turbine output power

The turbine is powered by compressed air between 35 and 61 pounds per square inch (~2,4 to 4,2 bar),[1][2] which passes up the centre of the instrument and rotates a Pelton wheel in the head of the handpiece. The centre of the windmill (chuck) is surrounded by bearing housing, which holds a friction-grip burr firmly & centrally within the instrument. Inside the bearing housing are small, lubricated ball-bearings (stainless steel or ceramic) which allow the shank of the burr to rotate smoothly along a central axis with minimal friction. The complete rotor is fixed with O-Rings in the head of the high speed. The O-Rings allow the system to become perfect centric during the idle speed but allow a small movement of the rotor within the head.

Failure of the burr to run centrally causes a number of clinical defects:

  • The burr will judder; this will cause excessive, damaging vibrations leading to cracking and crazing in the material being cut. It is also an unpleasant experience for the patient.
  • Eccentric cutting - this will result in irregular removal of the surface, meaning more tissue than necessary is removed.
  • Decreased control - due to irregular cutting, it is more difficult for the dentist to control movements

Cooling edit

High-speed friction generates tremendous heat within the burr. High-speed handpieces must consequently have an excellent water-cooling system. The standard is 50 ml/min of cooling water provided through 3 to 5 spray hole jets.

Illumination edit

Many modern handpieces now have a light in close proximity to the burr. The light is directed at the cutting surface as to assist with intra-operative vision.

Older handpieces utilized a system of halogen lamps and fiber-optic rods, but this method has several drawbacks: halogen bulbs decay over time and are costly to repair, and fiber-optic rods fracture readily if dropped and disintegrate through repeated autoclaving cycles.

LED technologies are now used in many sophisticated handpieces. LEDs have a longer operating life, produce more powerful light, and produce less heat.

Speed-increasing handpiece edit

Electric motors cannot turn as fast as air turbines. To power a high-speed handpiece, gears are needed to increase the speed of an electric motor, often by a ratio of 1:5.[3] For this reason, electric handpieces are also called speed-increasing handpieces, working at cutting speeds over 180,000 rpm.[4]

  • Speed-increasing handpiece is driven by electrical motor, also known as micromotor.
  • The power to the handpiece is provided by the micromotor.
  • Within the handpiece is internal gearings which allow the friction grip burr to rotate at a constant speed independent of torque.
  • Therefore, the power is provided by micromotor and internal gearings.

Torque edit

  • Torque is the ability of burr to continually rotate with the same speed and cut even when pressure is applied
  • As the speed of a handpiece increases its torque subsequently decreases (slow-speed handpieces have high torque, whereas high-speed handpieces, like the air turbine system, have a low torque)
  • The free running speed of 1:5 speed-increasing handpiece is the same as its cutting speed, thus 40,000 motor speed x5= 200,000 rpm burr speed.
  • Electrical motor maintains the 200,000 rpm speed and provides consistent power so torque will be maintained, depending on the electronic control parameters.

Comparison of high speed and speed increasing handpieces edit

High speed Speed increasing
Type of burr used Friction grip Friction grip
Power source Compressed air Electric Micromotor
Torque Variable Constant
Motion of burr Rotation & Pecking Rotation only
Balance Usually neutral Motor end heavy

Slow speed handpiece edit

Slow speed handpieces work at a much slower rate that high speed and speed-increasing handpieces, and are usually driven by rotary vane motors, instead of air turbines. They work at a speed between 600 and 25,000 rpm. The internal gearings are very similar to that of a speed-increasing handpiece. The main difference between the two is that slow speed has internal gearing and they can use both a latch grip burr and a friction grip burr.

Indications for use edit

Generally used for operative procedures such as the removal of dental caries or for polishing enamel or restorative materials. Straight slow speed handpiece is generally indicated for the extra oral adjustment and polishing of acrylic and metals.

Speed decreasing handpiece edit

Designed to work at slower speeds.

Indications for use edit

The main indications for use include endodontic canal preparation, implant placement and prophylaxis.

Endodontic canal preparation edit

Endodontic canals are prepared using a slow rotating file. It is imperative that torque is controlled in order to prevent endodontic file separation during use.

  • Implant placement - In order to prevent heat damage to bone during implant placement speed decreasing handpiece is used.
  • Prophylaxis - Prophylaxis with the use of speed decreasing handpiece ensures that less heat is produced and thus less risk of pulpal damage by heat transmission.

Dental burr edit

 
A collection of various burrs used in dentistry.
 
Dental rotary instruments - boreri

A dental burr or bur is a type of cutter used in a handpiece. The burrs are usually made of tungsten carbide or diamond. The three parts of a burr are the head, the neck, and the shank.[5]

The heads of some burrs (such as tungsten carbide burrs) contain the blades which remove material. These blades may be positioned at different angles in order to change the property of the burr. More obtuse angles will produce a negative rake angle, which increases the strength and longevity of the burr. More acute angles will produce a positive rake angle, which has a sharper blade, but which dulls more quickly. The heads of other commonly used burrs are covered in a fine grit which has a similar cutting function to blades (e.g. high speed diamond burrs). Diamond burrs seem to give better control and tactile feedback then carbide burrs, due to the fact that the diamonds are always in contact with the milled tooth in comparison to the single blades of the carbide burrs.[6]

There are various shapes of burrs that include round, inverted cone, straight fissure, tapered fissure, and pear-shaped burrs. Additional cuts across the blades of burrs were added to increase cutting efficiency, but their benefit has been minimized with the advent of high-speed handpieces.[5] These extra cuts are called crosscuts.

Due to the wide array of different burrs, numbering systems to categorise burrs are used and include a US numbering system and a numbering system used by the International Organization for Standardization (ISO).

Dental burrs typically have shank diameters of either 1.6 mm (1/16 inches) or 2.35 mm (3/32 inches).[7]

Maintenance edit

The instrument needs to be disinfected or sterilized after every usage to prevent infection during succeeding incisions. Due to the mechanical structure of the device, this must not be done with alcoholic disinfectant, as that would destroy the lubricants. Instead it has to be done in an autoclave after removing the drill, washing the instrument with water and lubricating it.[8][9] The United States Food and Drug Administration classes burrs as "single-use devices",[10] although they can be sterilised with proper procedures.

History edit

 
Foot-powered dental drill

The Indus Valley civilization has yielded evidence of dentistry being practiced as far back as 7000 BC.[11] This earliest form of dentistry involved curing tooth-related disorders with bow drills operated, perhaps, by skilled bead craftsmen.[12] The reconstruction of this ancient form of dentistry showed that the methods used were reliable and effective.[13] Cavities of 3.5 mm depth with concentric grooves indicate use of a drill tool. The age of the teeth has been estimated at 9,000 years. In later times, mechanical hand drills were used. Like most hand drills, they were quite slow, with speeds of up to 15 rpm. In 1864, British dentist George Fellows Harrington invented a clockwork dental drill named Erado.[14] The device was much faster than earlier drills, but also very noisy. In 1868, American dentist George F. Green came up with a pneumatic dental drill powered by pedal-operated bellows. James B. Morrison devised a pedal-powered burr drill in 1871.

 
Chayes M33 with Buffalo drive belt.

The first electric dental drill was patented in 1875 by Green, a development that revolutionized dentistry. By 1914, electric dental drills could reach speeds of up to 3,000 rpm. A second wave of rapid development occurred in the 1950s and 60s, including the development of the air turbine drill.

Contra-angle edit

The modern incarnation of the dental drill is the air turbine (or air rotor) contra-angle handpiece, where the shaft of the rotary instrument is at an angle allowing it to reach less accessible areas of the mouth for dental work. The contra-angle was invented by John Patrick Walsh (later knighted) and members of the staff of the Dominion Physical Laboratory (DPL) Wellington, New Zealand. The first official application for a provisional patent for the handpiece was filed in October 1949.[15] This handpiece was driven by compressed air. The patent was granted in November to John Patrick Walsh, who conceived the idea of the contra-angle air-turbine handpiece after he had used a small commercial-type air grinder as a straight handpiece. Dr. John Borden developed it in America and it was first commercially manufactured and distributed by the DENTSPLY Company as the Borden Airotor in 1957. Borden Airotors soon were also manufactured by different other companies like KaVo Dental, which built their first one in 1959.[16]

Current iterations can operate at up to 800,000 rpm, however, most common is a 400,000 rpm "high speed" handpiece for precision work complemented with a "low speed" handpiece operating at a speed that is dictated by a micromotor which creates the momentum (max up to 40,000 rpm) for applications requiring higher torque than a high-speed handpiece can deliver.[17]

Alternatives edit

Starting in the 1990s, a number of alternatives to conventional rotary dental drills have been developed. These include dental laser systems,[18] air abrasion devices (devices that combine small abrasive particles with pressurized air, essentially miniature sand blasters),[19][20] and dental treatments with ozone or silver diamine fluoride (SDF).[21][22]

References edit

  1. ^ "Instruction for Use MASTERtorque M9000L". kavo.com. 2 March 2017.
  2. ^ "Highspeed Handpiece Design". American Dental Accessories. May 25, 2010. Retrieved October 16, 2018.
  3. ^ Gregori M. Kurtzman (February 2007). "Electric Handpieces: An Overview of Current Technology". Inside Dentistry. 3 (2). AEGIS Communications. Retrieved October 15, 2018.
  4. ^ Bonsor, Pearson (2013). A clinical guide to applied dental materials. Churchill Livingstone Elsevier. p. 329.
  5. ^ a b Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001. Pages 139 - 143. ISBN 0-86715-382-2.
  6. ^ Stevens, Lorin; Malcolm, Scott; George, Scott; Palmer, Timothy; Martinez, Alejandro; Moeller, Aaron; Hein, Cameron; Christensen, Gordon (2014). "Comparison of Carbide and Diamond Burs for Class-II Preparations" – via ResearchGate.
  7. ^ "Guide to the Different Types of Dental Burs". Dentared Odontology Services. Retrieved May 7, 2020.
  8. ^ "Maintenance Instruction for Dental Drills (Italian)"
  9. ^ "Hygiene Instructions for Dentists (German)"
  10. ^ Mary Govoni (October 15, 2014). "Reusing disposable items: saving money or risking cross-contamination?". www.dentaleconomics.com. Retrieved 2017-03-02.
  11. ^ Coppa, A. et al. 2006. Early Neolithic tradition of dentistry. Nature. Volume 440. 6 April 2006. doi:10.1038/440755a
  12. ^ "Stone age man used dentist drill". BBC News. 6 April 2006.
  13. ^ NBC News (2008). Dig uncovers ancient roots of dentistry.
  14. ^ "BDA Museum: Collections: Dental equipment: Clockwork drill and dental engine". British Dental Association. 7 June 2013. Retrieved 9 September 2015.
  15. ^ NZ patent 104611, F.R. Callaghan, "Pneumatic Dental Drilling Apparatus", published 12-23-1952 
  16. ^ History of Dental Turbines Archived 2015-04-28 at archive.today
  17. ^ Handpiece, Use, Care and Maintenance", Franzel, Mattana. University Detroit Mercy School of Dentistry literature 2007
  18. ^ Johannes, Laura (2013-04-29). "To Cut Tooth Decay: A Laser vs. a Drill". Wall Street Journal. ISSN 0099-9660. Retrieved 2016-09-20.
  19. ^ Huang, CT; Kim, J; Arce, C; Lawson, NC (2019). "Intraoral Air Abrasion: A Review of Devices, Materials, Evidence, and Clinical Applications in Restorative Dentistry". Compendium of Continuing Education in Dentistry. 40 (8): 508–514. ISSN 1548-8578. PMID 31478697.
  20. ^ Mandinic, Zoran; Vulicevic, Zoran; Beloica, Milos; Radovic, Ivana; Mandic, Jelena; Carevic, Momir; Tekic, Jasmina (2014). "The application of air abrasion in dentistry" (PDF). Srpski Arhiv Za Celokupno Lekarstvo. 142 (1–2). National Library of Serbia: 99–105. doi:10.2298/sarh1402099m. ISSN 0370-8179. PMID 24684041.
  21. ^ Tiwari, Sansriti; Avinash, Alok; Katiyar, Shashank; Aarthi Iyer, A.; Jain, Suyog (2017). "Dental applications of ozone therapy: A review of literature". The Saudi Journal for Dental Research. 8 (1–2). Elsevier BV: 105–111. doi:10.1016/j.sjdr.2016.06.005. ISSN 2352-0035. S2CID 77862294.
  22. ^ Rosenblatt, A.; Stamford, T.C.M.; Niederman, R. (2009). "Silver Diamine Fluoride: A Caries "Silver-Fluoride Bullet"". Journal of Dental Research. 88 (2). SAGE Publications: 116–125. doi:10.1177/0022034508329406. ISSN 0022-0345. PMID 19278981. S2CID 30730306.