Dental pulpal testing is a clinical and diagnostic aid used in dentistry to help establish the health of the dental pulp within the pulp chamber and root canals of a tooth. Such investigations are important in aiding dentists in devising a treatment plan for the tooth being tested.

There are two major types of dental pulp tests. Vitality testing assesses the blood supply to the tooth, whilst sensitivity testing tests the sensory supply.

Clinical application

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Dental pulp tests are valuable techniques used to establish the pulpal health status of a tooth in dentistry. The diagnostic information obtained from pulpal testing is then used alongside a patient's history, clinical and radiographic findings to determine a diagnosis and prognosis of the tooth.

Pulp tests are useful for the following procedures in dentistry:

  • diagnosis of endodontic pathology,
  • localisation of tooth pain,
  • differentiating between odontogenic and non-odontogenic pain,
  • assessing pulpal status following dental trauma,
  • establishment of pulpal health prior to prosthodontic treatment.

Pulpal tests may be conducted via stimulation of the sensory fibres within the pulp (sensitivity testing) or by assessing pulpal blood flow (vitality testing). All available techniques are reported to have limitations in terms of accuracy and reproducibility [1] and therefore require careful interpretation in clinical practice.

Sensitivity testing

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Sensitivity tests assess the sensory response of a tooth to an external stimulus, results which may be extrapolated to indirectly determine pulpal health status. Sensory stimuli, such as heat, cold or an electrical current, are applied to the tooth in question in order to stimulate the nocireceptors within the pulp. The type of sensory fibres activated and therefore the response felt by the patient depends on the stimulus used. Sensibility testing is based on Brännström's hydrodynamic theory, which postulates that the activation of nocireceptors is caused by fluid movement within the dentinal tubules in response to thermal, electrical, mechanical or osmotic stimuli.[2]

Responses to sensitivity testing

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There are three primary outcomes of a pulp sensitivity test:

  • A normal response — healthy pulps respond to sensitivity testing by eliciting a short, sharp pain which subsides when the stimulus is removed, indicating that the nerve fibres are present and responsive.
  • A heightened or prolonged response — an exaggerated or lingering response to sensitivity testing indicates some degree of pulpal inflammation. If the pain is pronounced yet subsides once the stimulus has been removed, a diagnosis of reversible pulpitis may be probable. However, a lingering pain which continues despite the removal of the stimulus is indicative of irreversible pulpitis.
  • No response — lack of response to sensitivity testing suggests that the nerve supply to the tooth has been diminished, as in the case of pulpal necrosis or in previously root treated canals.

Types of sensitivity tests

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Thermal tests

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Thermal testing, which involves the application of either hot or cold stimuli to the tooth, is the most common form of sensibility test.

A number of products are available for cold testing, each with varying melting points. Although household ice (0 °C [32 °F]) is cheap and easy to obtain, it is not as accurate as colder products.[3] Dry ice (−78 °C [−108 °F]) can be used, however there have been concerns regarding the damaging effects of using something so cold in the oral cavity[4] despite evidence to suggest that dry ice has no negative impact on mucosal[5] or tooth structure.[6][7] Refrigerant sprays, such as ethyl chloride (−12.3 °C [9.9 °F]), 1,1,1,2-tetrafluoroethane (−26.5 °C [−15.7 °F]) or a propane/butane/isobutane gas mixture are further commonly used cold tests. Cold testing is thought to stimulate Type Aδ fibres in the pulpal tissue, which elicit a short, sharp pain.

Heat tests include using heated instruments, such as a ball-ended probe or gutta-percha, a rubber commonly used in root canal procedures. Such tests are less commonly used as they are thought to be less accurate than cold tests, and may be more likely to cause damage to the teeth and surrounding mucosa.[4]

Electric pulp testing

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An electrical current can be applied to the tooth in order to generate an action potential in the Type Aδ fibres within pulp, eliciting a neurological response. Such tests are conducted by applying a conducting medium (e.g. toothpaste) on a dried tooth and placing the probe tip of an electric pulp tester on the surface of the tooth closest to the pulp horn(s). The patient is then directed to hold the end of the conducting probe to complete the circuit and asked to let go of the probe when a ‘tingling’ sensation [8] is felt.

The use of electric pulp testing has been questioned in patients with traditional cardiac pacemakers despite no evidence of interferences in humans, particularly with more modern devices.[4] Care must be taken if using an electric pulp test on a tooth adjacent to metallic restorations, as these can create electrical conduction and yield false negative results.

Anaesthesia testing

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When pulp testing results are inconclusive and that patients cannot localise or specify the pain or symptoms, an anaesthetic would be helpful and be used. The most posterior tooth in the area where the pain resonates undergoes anaesthesia by either infiltration or intraligamentary injection until pain diminishes. If the pain is still present, the procedure is repeated on the mesial teeth, one by one until the pain diminishes and is gone. If one can still not determine the source of the pain, the procedure will be repeated on the opposite arch. In the case that the pain cannot be localised to either the maxillary or mandibular arch, an inferior alveolar nerve block would be used. If the pain stops, such would imply that it involves teeth of the mandibular arch.[9]

Test cavity

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The test cavity technique is only used as a last resort when results produced by all other methods above are inconclusive. High-speed burs are used without anaesthetic, drilling through enamel, or restorations to dentine. Throughout the drilling process, the patient is asked whether a painful sensation is felt, which would indicate pulpal vitality. In the event of a vital pulp, a painful response is provoked when dentin is contacted by the bur and the procedure will be stopped. A restoration would be then placed. Contrarily, when compared with vital pulp, pulp with partial necrosis will not be stimulated as extensively. In the case of partial necrosis, access to and into dentine would be needed, with the dentist progressively invading and drilling deeper into dentine, checking the sensory response—which is usually without sensory response because of the partial necrosis. Due to the invasiveness and possible anxiety that it may generate in patients, the test cavity technique is generally avoided. Also, there is little literature supporting its effectiveness, and it has been relatively anecdotal within clinical practice.[9]

Limitations of sensitivity testing

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All tests have some limitations and test results should be interpreted by an experienced dentist under the bidirectional consideration of both clinical symptoms and radiography. Sensitivity tests only indicate the presence or absence of the nerve supply to an individual tooth. Even though a prolonged response to aforementioned tests indicate pulpal inflammation, the degree of inflammation or innervation cannot be inferred from these tests.

False positive or false negative results are possible when performing a sensitivity testing. A false positive response occurs when a patient is respondent to sensitivity testing despite a lack of sensory tissue in the tooth that is being tested. Such responses may occur due to innervation of adjacent teeth due to inadequate isolation of the tooth being tested, or in anxious patients who perceive pain despite no sensory stimulus, or in multi-rooted teeth which still have residual pulpal tissue residing in canals.[10][11] False negative results occurs when innervated teeth do not respond to sensibility testing. Such can occur in individuals who have recently traumatised teeth, teeth with incomplete root development, teeth with heavy restorations or teeth that have significantly reduced pulp size due to production of tertiary or sclerotic dentine.[12]

Pulpal sensitivity testing may be regarded as inferior to vitality testing as they do not definitively prove that the tooth has a blood supply and is vital. Nonetheless, electric pulp testing and cold testing tests have been found to be accurate and reliable in the case of assessing pulpal health, especially when tests are used in combination.[13][14] In addition, cold testing is also more accurate than electric pulp in the case of running tests upon immature or traumatised teeth.[15]

Despite the insights gained from sensitivity testing, a research study found that the density of nerve fibers and blood vessels in the pulp tissue, and the degree of oxygen saturation, may play a crucial role in interpreting the results. The presence of a higher density of nerve fibers may contribute to a lower threshold for electrical stimulation, suggesting the involvement of neural factors in pulp sensibility. Moreover, the positive correlation between blood vessel density and oxygen saturation, as well as the negative correlation between nerve fiber density and electrical voltage perception, provide valuable insights into the complex nature of dental pulp. Therefore, in addition to the standard sensitivity testing, more objective and accurate methods such as pulse oximetry might be necessary for a comprehensive understanding of pulp vitality. However, the findings of this study should be generalized with caution due to its small sample size and focus on healthy teeth extracted for orthodontic reasons.[16]

Vitality testing

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Vitality tests assess the vascular supply of a tooth. Vascular supply is generally accepted as the earliest indicator of pulpal health.[17][18] However, vitality tests have limitations and require strict adherence to correct application techniques.[14] The diagnostic methods to assess the vascular response of the pulp include:

Laser Doppler flowmetry

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Laser Doppler flowmetry is able to assess blood flow within the dental pulp directly. A laser beam directed onto the tooth follows the path of dentinal tubules to the pulp.[19] The viability of the vascular supply of the pulp is determined by the output signal generated by the backscattered reflected light from circulating blood cells.[20] The reflected light is Doppler-shifted and has a different frequency to those reflected by the surrounding tissues which are static. An arbitrary unit of measurement, ‘perfusion unit’ (PU), is used to measure the concentration and velocity (flux) of blood cells.[19][21] The output of laser Doppler flowmetry may be influenced by the blood flow in surrounding tissues, and therefore the test tooth must be adequately isolated to avoid inaccuracies.[22]

Pulse oximetry

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Pulse oximetry utilises the difference in red and infrared light absorption by oxygenated and deoxygenated red blood cells within blood circulation to determine the oxygen saturation level (SaO2).[23][24] Pulse oximetry, as well as laser Doppler flowmetry vitality tests may not truly reflect the real state of health of the dental pulp. This mainly happens in clinical scenarios when the dental pulp is diseased, yet a viable blood supply is maintained.[14] In a study from Slovenia, correlations were found between clinical tests and histological analysis of dental pulp in 26 healthy permanent premolars extracted for orthodontic reasons. It was found that a higher density of blood vessels in the pulp tissue corresponded to increased oxygen saturation levels measured through pulse oximetry, lending support to the validity of pulse oximetry as a reliable method for assessing pulp vitality. Furthermore, teeth with closed apices had a higher density of nerve fibers in the upper part of the dental pulp compared to teeth with open apices. This further indicated individual variations in sensitivity, with teeth showing a higher density of nerve fibers having a lower threshold for electrical stimulation.[25]

Dual wavelength spectrophotometry

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The use of dual wavelength light establishes the contents within the pulp chamber.[26]

References

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  1. ^ Chen, Eugene (September 2009). "Dental Pulp Testing; A Review". International Journal of Dentistry. 2009 (Article ID 365785): 365785. doi:10.1155/2009/365785. PMC 2837315. PMID 20339575.
  2. ^ Brännström, Martin (January 1986). "The hydrodynamic theory of dentinal pain: Sensation in preparations, caries, and the dentinal crack syndrome". Journal of Endodontics. 12 (10): 453–457. doi:10.1016/S0099-2399(86)80198-4. PMID 3465849.
  3. ^ Fuss, Zvi; Trowbridge, Henry; Bender, I.B.; Rickoff, Bruce; Sorin, Solomon (January 1986). "Assessment of reliability of electrical and thermal pulp testing agents". Journal of Endodontics. 12 (7): 301–305. doi:10.1016/S0099-2399(86)80112-1. PMID 3461119.
  4. ^ a b c Chen, Eugene; Abbott, Paul V. (2009). "Dental Pulp Testing: A Review". International Journal of Dentistry. 2009: 365785. doi:10.1155/2009/365785. PMC 2837315. PMID 20339575.
  5. ^ Ehrmann, EH (August 1977). "Pulp testers and pulp testing with particular reference to the use of dry ice". Australian Dental Journal. 22 (4): 272–9. doi:10.1111/j.1834-7819.1977.tb04511.x. PMID 277144.
  6. ^ Rickoff, Bruce; Trowbridge, H.; Baker, John; Fuss, Z.; Bender, I.B. (January 1988). "Effects of thermal vitality tests on human dental pulp". Journal of Endodontics. 14 (10): 482–485. doi:10.1016/S0099-2399(88)80104-3. PMID 3255773.
  7. ^ Augsburger, Robert A.; Peters, Donald D. (March 1981). "In vitro effects of ice, skin refrigerant, and CO2 snow on intrapulpal temperature". Journal of Endodontics. 7 (3): 110–116. doi:10.1016/S0099-2399(81)80124-0. PMID 6938630.
  8. ^ Kleier, D.J.; Sexton, J.R.; Averbach, R.E. (December 1982). "Electronic and Clinical Comparison of Pulp Testers". Journal of Dental Research. 61 (12): 1413–1415. doi:10.1177/00220345820610120701. PMID 6960045. S2CID 42448558.
  9. ^ a b Mythri, H; Arun, A; Chachapan, Dale (2015). "Pulp vitality tests - an overview on comparison of sensitivity and vitality". Indian Journal of Oral Sciences. 6 (2): 41. doi:10.4103/0976-6944.162622 (inactive 1 November 2024). ISSN 0976-6944.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  10. ^ Peters, Donald D.; Baumgartner, J. Craig; Lorton, Lewis (October 1994). "Adult pulpal diagnosis. I. Evaluation of the positive and negative responses to cold and electrical pulp tests". Journal of Endodontics. 20 (10): 506–511. doi:10.1016/S0099-2399(06)80048-8. PMID 7714424.
  11. ^ Gopikrishna, Velayutham; Pradeep, Gali; Venkateshbabu, Nagendrababu (January 2009). "Assessment of pulp vitality: a review". International Journal of Paediatric Dentistry. 19 (1): 3–15. doi:10.1111/j.1365-263X.2008.00955.x. PMID 19120505.
  12. ^ Jafarzadeh, H.; Abbott, P. V. (2010-07-01). "Review of pulp sensibility tests. Part I: general information and thermal tests: Pulp sensibility tests". International Endodontic Journal. 43 (9): 738–762. doi:10.1111/j.1365-2591.2010.01754.x. PMID 20609022.
  13. ^ Jespersen, James J.; Hellstein, John; Williamson, Anne; Johnson, William T.; Qian, Fang (March 2014). "Evaluation of Dental Pulp Sensibility Tests in a Clinical Setting". Journal of Endodontics. 40 (3): 351–354. doi:10.1016/j.joen.2013.11.009. PMID 24565651.
  14. ^ a b c Alghaithy, R. A.; Qualtrough, A. J. E. (February 2017). "Pulp sensibility and vitality tests for diagnosing pulpal health in permanent teeth: a critical review". International Endodontic Journal. 50 (2): 135–142. doi:10.1111/iej.12611. PMID 26789282.
  15. ^ Fuss, Zvi; Trowbridge, Henry; Bender, I.B.; Rickoff, Bruce; Sorin, Solomon (January 1986). "Assessment of reliability of electrical and thermal pulp testing agents". Journal of Endodontics. 12 (7): 301–305. doi:10.1016/S0099-2399(86)80112-1. PMID 3461119.
  16. ^ Tenyi, Ana; Nemeth, Lidija; Golež, Aljaž; Cankar, Ksenija; Milutinović, Aleksandra (2022-06-01). "Comparison of the vitality tests used in the dental clinical practice and histological analysis of the dental pulp". Bosnian Journal of Basic Medical Sciences. 22 (3): 374–381. doi:10.17305/bjbms.2021.6841. ISSN 2831-090X. PMC 9162753. PMID 35150478.
  17. ^ Thomas, Robyn (2010-02-11). "Pathways Of The Pulp (4th Ed) By: Stephen Cohen and Richard Burns (Eds)". Australian Endodontic Newsletter. 13 (1): 11. doi:10.1111/j.1747-4477.1987.tb00193.x. ISSN 0313-7384.
  18. ^ Baumgardner, K.R.; Walton, R.E.; Osborne, J.W.; Born, J.L. (October 1996). "Induced Hypoxia in Rat Pulp and Periapex Demonstrated by 3H-Misonidazole Retention". Journal of Dental Research. 75 (10): 1753–1760. doi:10.1177/00220345960750100801. hdl:2027.42/67588. ISSN 0022-0345. PMID 8955670. S2CID 18460204.
  19. ^ a b MATTHEWS, B.; VONGSAVAN, N. (January 1993). "Advantages and limitations of laser Doppler flow meters". International Endodontic Journal. 26 (1): 9–10. doi:10.1111/j.1365-2591.1993.tb00531.x. PMID 8473040.
  20. ^ Ingolfsson, AEgir Rafn; Tronstad, Leif; Hersh, Elliot V.; Riva, Charles E. (April 1994). "Efficacy of laser Doppler flowmetry in determining pulp vitality of human teeth". Dental Traumatology. 10 (2): 83–87. doi:10.1111/j.1600-9657.1994.tb00065.x. PMID 8062812.
  21. ^ Vongsavan, N.; Matthewst, B. (1 January 1996). "Experiments in pigs on the sources of laser Doppler blood-flow signals recorded from teeth". Archives of Oral Biology. 41 (1): 97–103. doi:10.1016/0003-9969(94)00076-X. PMID 8833597.
  22. ^ Polat, Serkan; Er, Kürşat; Akpinar, Kerem E; Polat, N.Tülin (January 2004). "The sources of laser Doppler blood-flow signals recorded from vital and root canal treated teeth". Archives of Oral Biology. 49 (1): 53–57. doi:10.1016/S0003-9969(03)00197-3. PMID 14693197.
  23. ^ Munshi, A.; Hegde, Amitha; Radhakrishnan, Sangeeth (January 2003). "Pulse oximetry: a diagnostic instrument in pulpal vitality testing". Journal of Clinical Pediatric Dentistry. 26 (2): 141–145. doi:10.17796/jcpd.26.2.2j25008jg6u86236 (inactive 1 November 2024). PMID 11874005.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  24. ^ Noblett, W. Craig; Wilcox, Lisa R.; Scamman, Franklin; Johnson, William T.; Diaz-Arnold, Ana (January 1996). "Detection of pulpal circulation in vitro by pulse oximetry". Journal of Endodontics. 22 (1): 1–5. doi:10.1016/S0099-2399(96)80226-3. PMID 8618078.
  25. ^ Tenyi, Ana; Nemeth, Lidija; Golež, Aljaž; Cankar, Ksenija; Milutinović, Aleksandra (2022-06-01). "Comparison of the vitality tests used in the dental clinical practice and histological analysis of the dental pulp". Bosnian Journal of Basic Medical Sciences. 22 (3): 374–381. doi:10.17305/bjbms.2021.6841. ISSN 2831-090X. PMC 9162753. PMID 35150478.
  26. ^ Nissan, R.; Trope, M.; Zhang, C. D.; Chance, B. (October 1992). "Dual wavelength spectrophotometry as a diagnostic test of the pulp chamber contents". Oral Surgery, Oral Medicine, and Oral Pathology. 74 (4): 508–514. doi:10.1016/0030-4220(92)90304-9. PMID 1408029.