Laser in stomatology

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The use of laser in dentistry[edit | edit source]

Different types of laser are used in dentistry and their use is also different. They main ones are:

  1. diode laser
  2. erbium laser

Diode laser[edit | edit source]

- is used in :

A type of laser that is absorbed in tissues with a high content of blood pigment - hemoglobin. It is therefore used to treat soft tissues such as gums, mucous membranes or skin. However, it cannot remove tooth decay, but it helps us to find out where and at what stage the decay is located. It works at a wavelength of approximately 655 nm and reaches up to 2 mm below the enamel, through which it penetrates with the help of a sensor that captures the reflected light beam and, based on the principle of laser fluorescence, we obtain information about the state of the dental tissue. Today, these lasers are commonly used in the world even in the form of a pen (Diode laser Diagnodent Pen ©), but in our normal practice (in the Czech Republic) they are still a novelty.

Erbium laser[edit | edit source]

- is used in :

  • preparation of dental caries (especially classes I. and V.),
  • sterilization of the dental canal during endodontics,
  • tartar removal,
  • inflammation therapy.

Unlike the diode laser, it is best absorbed in water-containing tissues, such as teeth and bones. The wavelength of the beam is 2940 nm. Since this wavelength borders the spectrum of visible light, the dental laser is equipped with a targeting beam source (semiconductor) whose wavelength is 670 nm. The energy emitted by this laser increases the temperature in the tissue by several 100 °C and the affected tissue is actually vaporized. This laser is used for non-contact removal of tooth decay or calculus. It can also be used to sterilize the dental canal or its use is used for inflammation of the dental pulp.


When removing tartar, the laser tip first searches for the tartar and the device evaluates its size. Accordingly, it will accurately calculate the dose to remove it. The size of the dose and the presence of tartar is shown on the display of the measuring device. The device sends laser beams only to places where tartar is present, simplifying and speeding up subsequent regeneration.

Benefits[edit | edit source]

  • the possibility of early detection of changes in the dental substance – the so-called enamel demineralization, which is the 1st stage of tooth decay,
  • faster healing of wounds thanks to the sterilization properties of the laser,
  • a smaller amount of anesthesia is often required,
  • during laser preparation, the dentinal tubules remain open, so it is not necessary to etch the surface before filling with composite material,
  • we do not find a Smear layer at the bottom of the prepared cavity,
  • noiselessness during preparation,
  • cavity decontamination.

Disadvantages[edit | edit source]

  • high purchase price of the device,
  • devices weight,
  • the need for intensive cooling during treatment (there is a risk of thermal damage to tissues (e.g. damage to the dental pulp during laser preparation of dental caries)).

Links[edit | edit source]

References[edit | edit source]

  • MAZÁNEK, Jiří. Zubní lékařství : Propedeutika. 1. edition. Grada Publishing, 2014. 576 + 28 pp. ISBN 978-80-247-3534-4.


Source[edit | edit source]

  • BROUKAL, . Strategie léčby / ošetření kazu [přednáška k předmětu Kariologie, obor Zubní lékařství, 1. LF UK]. VFN. 20. 5. 2014. 

External links[edit | edit source]