Effects of the reduction of caffeine consumption on
               tinnitus perception

Figueiredo, Ricardo Rodrigues; Rates, Marcelo José Abras; Azevedo, Andréia Aparecida de; Moreira, Ronaldo Kennedy de Paula; Penido, Norma de Oliveira

doi:10.1016/j.bjorl.2014.05.033

Abstracts

INTRODUCTION:

For many years, excessive caffeine consumption has been touted as an aggravating factor for tinnitus. The pathophysiology behind this effect is probably related to the blockage of adenosine receptors by the action of caffeine on the central nervous system.

OBJECTIVE:

To evaluate the effects of reduction of coffee consumption on tinnitus sensation and to identify subgroups more prone to benefit from this therapeutic strategy. Study design: prospective.

METHODS:

Twenty-six tinnitus patients who consumed at least 150 mL of coffee per day were selected. All were asked to reduce their coffee consumption. The Tinnitus Handicap Inventory (THI) questionnaire was completed by the patients before and after the reduction of coffee consumption, as well as a visual-analogue scale (VAS) graduated from 1 to 10.

RESULTS:

THI and VAS scores were significantly reduced (p < 0.05). In the subgroups less than 60 years old, bilateral tinnitus and daily coffee consumption between 150 and 300 mL showed a significantly greater reduction of THI and VAS scores.

CONCLUSION:

Patients under 60 years of age with bilateral tinnitus and daily coffee consumption between 150 and 300 mL are more prone to benefit from consumption reduction. Thirty-day observation periods may be helpful for a better therapeutical decision.

Tinnitus; Caffeine; Coffee

INTRODUÇÃO:

O consumo abusivo de cafeína vem sendo descrito como fator de piora e causa do zumbido há muitos anos. A fisiopatologia deste efeito está provavelmente relacionada ao bloqueio dos receptores inibitórios adenosínicos pela cafeína no sistema nervoso central.

OBJETIVO:

Avaliar os efeitos da redução do consumo de cafeína na percepção do zumbido e identificar subgrupos de pacientes mais propensos a benefícios com esta proposta. Tipo de estudo: prospectivo.

MÉTODO:

Selecionados 26 pacientes com zumbido neurossensorial e consumo diário superior a 150 mL de café. Os efeitos da redução do consumo foram avaliados através do Tinnitus Handicap Inventory (THI) e da escala visual-análoga (EVA).

RESULTADOS:

Houve redução estatisticamente significativa (p < 0,05) nos escores do THI e EVA. Nos subgrupos com idade inferior a 60 anos, zumbido bilateral e consumo diário de café entre 150 e 300 mL apresentaram maior redução dos escores THI e EVA.

CONCLUSÃO:

Em pacientes com idade inferior a 60 anos, zumbido bilateral e consumo diário de café entre 150 e 300 mL apresentaram benefícios com a redução no consumo diário de cafeína. Períodos observacionais de 30 dias podem ser úteis para a decisão terapêutica.

Zumbido; Cafeína; Café

Introduction

Caffeine, also known as methyltheobromin, is part of the group of methylxanthines, and is considered the most widely used psychoactive substance in the world. The majority of its consumption is derived from dietary sources such as coffee, tea, cola soft drinks, and chocolate; the most striking behavioral effects are increases in alertness, energy, and concentration skills. These effects are more pronounced after ingestion of small to moderate amounts (50-300 mg).¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

The caffeine content by coffee cup varies depends on the form of preparation (Table 1).¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76. In Brazil, the per capita consumption, according to the Associação Brasileira de Indústrias do Café (ABIC), is currently about 73 L per year, and the filtration method of preparation is the most commonly used.²2. Associação Brasileira de Indústrias do Café (ABIC) [acessado 20 Ago 2010]. Disponível em: http//:www.abic.com.br
http//:www.abic.com.br... A worldwide trend toward increased coffee consumption has been noted. The caffeine content of other beverages varies, on average, from 32 to 42 mg/150 mL (tea), 32 to 70 mg/330 mL (cola beverages), and approximately 4 mg/150 mL (chocolate flavored milk).¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

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Table 1
Amount of caffeine in various forms of coffee preparation.

The absorption of caffeine in the gastrointestinal tract is rapid, reaching 99% after 45 min. Peak plasma levels are achieved between 15 and 120 min after oral ingestion, and the half-life is about 2.5-4.5 h. Caffeine is metabolized by the liver.¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

Currently, most authors believe that the main mechanism of action of caffeine is the antagonism of adenosinic receptors.¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76. ^, ³3. Daly JM . Mechanism of action of caffeine. Em: SG, editor. Caffeine, coffee and health. New York: Raven Press; 1993. p. 97-150. ^, ⁴4. Dixit A, Vaney N, Tandon OP. Effect of caffeine ingestion on cognitive brain function. Ind J Physiol Pharmacol. 2004;48:79. ^and ⁵5. Lorist MM, Snel J, Kok A. Influence of caffeine on information processing stages in well rested and fatigued subjects. Psycophysiology. 1994;113:411-21. Adenosine reduces the firing rate of neurons, exerting an inhibitory effect on synaptic transmission and in the release of various neurotransmitters. In 1993, Daly observed increased brain levels of norepinephrine, glutamate, and adrenaline after caffeine intake.³3. Daly JM . Mechanism of action of caffeine. Em: SG, editor. Caffeine, coffee and health. New York: Raven Press; 1993. p. 97-150. The adenosinic receptors involved with the effects of caffeine are A1 and A2. Neurostimulant effects of caffeine have been demonstrated in functional imaging studies.⁶6. Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9.

A2 adenosinic receptors interact with dopaminergic receptors in the nucleus striatum and nucleus accumbens by modulating them. Therefore, the blockage of these receptors, exerted by caffeine, could potentiate the dopaminergic neurotransmission.¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

Other demonstrated actions of caffeine include increased release of intracellular calcium and inhibition of phosphodiesterases; seemingly, these mechanisms are unrelated to the central effects of caffeine.¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

In addition to the neuroexcitatory effects, caffeine also has a vasoconstrictor effect, and this is the predominant effect at higher doses.⁶6. Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9. Studies with blood oxygenation level-dependant (BOLD) functional magnetic resonance imaging demonstrated a reduction in cerebral perfusion after caffeine intake. Some authors believe that the neurostimulant effects of caffeine are due primarily to its action on A1 receptors, whereas the vasoconstrictor effects are related to its effects on A2 receptors.⁶6. Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9.

Based on these neurostimulant effects of caffeine, several studies addressed the effects of this substance on the central auditory pathways.⁴4. Dixit A, Vaney N, Tandon OP. Effect of caffeine ingestion on cognitive brain function. Ind J Physiol Pharmacol. 2004;48:79. ^, ⁵5. Lorist MM, Snel J, Kok A. Influence of caffeine on information processing stages in well rested and fatigued subjects. Psycophysiology. 1994;113:411-21. ^, ⁶6. Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9. ^, ⁷7. Kawamura N, Maeda H, Nakamura J, Morita K, Nakazawa Y. Effects of caffeine on event-related potentials: comparison of oddball with single tone paradigms. Psychiatry Clin Neurosci. 1996;50:217-21. ^and ⁸8. Nehlig A, Boyet S. Dose-response study of caffeine effects on cerebral functioning activity with a specific focus on dependence. Brain Res. 2000;858:71-7. Lorist et al. found improvement of the central auditory processing after caffeine intake⁵5. Lorist MM, Snel J, Kok A. Influence of caffeine on information processing stages in well rested and fatigued subjects. Psycophysiology. 1994;113:411-21. and Kawamura et al.⁶6. Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9. found increase in the amplitude and area of P300 approximately 30 min after caffeine ingestion.

Dixit et al.⁴4. Dixit A, Vaney N, Tandon OP. Effect of caffeine ingestion on cognitive brain function. Ind J Physiol Pharmacol. 2004;48:79., also studying the effects of caffeine on P300, observed an increase in P3 amplitude and reduced reaction time, indicating facilitation of auditory processing and acceleration of motor responses. In another study, the same authors found a significant reduction in latencies of waves IV and V in auditory brainstem potentials (ABR), and a significant decrease in the I-V interval.⁹9. Dixit A,Vaney N, Tandon OP. Effect of caffeine on central auditory pathways: an evoked potential study. Hear Res. 2006; 220:61-6

In the cochlea, it was demonstrated that caffeine induced shortening of outer hair cells (OHC).¹⁰10. Slepecky S, Ulfendahl M, Flock A. Effects of caffeine and tetracaine on outer hair cells shortening suggest intracellular calcium involvment. Hear Res. 1988;32:11-22. ^, ¹¹11. Yamamoto T, Kakehata S, Yamada T, Saito T, Saito H, Akaike N. Caffeine rapidly decreases potassium condutance of dissociated outer hair cells of guinea pig cochlea. Brain Res. 1995;677:89-96. ^and ¹²12. Skellett RA, Crist JR, Fallon M, Bobbin RP. Caffeine-induced shortening of isolated outer hair cells: an osmotic mechanism of action. Hear Res. 1995;87:41-8. This fact would have some bearing on the rapid contraction of OHC, increasing the excitability of the peripheral auditory pathwaysThere is disagreement about the events involved in this shortening. Slepecky et al.¹⁰10. Slepecky S, Ulfendahl M, Flock A. Effects of caffeine and tetracaine on outer hair cells shortening suggest intracellular calcium involvment. Hear Res. 1988;32:11-22., in a 1988 study, suggested that the shortening of OHC occurs by mechanisms associated with rianodinic receptors. Conversely, Yamamoto et al.¹¹11. Yamamoto T, Kakehata S, Yamada T, Saito T, Saito H, Akaike N. Caffeine rapidly decreases potassium condutance of dissociated outer hair cells of guinea pig cochlea. Brain Res. 1995;677:89-96., in 1995, suggested that OHC depolarization occurs by potassium channel blockage. Finally, Skellett et al.¹²12. Skellett RA, Crist JR, Fallon M, Bobbin RP. Caffeine-induced shortening of isolated outer hair cells: an osmotic mechanism of action. Hear Res. 1995;87:41-8., in a study from 1995, suggested an osmotic mechanism.

Most clinical studies on the effects of caffeine in otoneurology refer to changes in the vestibular system.¹³13. Desmond ALD. Vestibular function: evolution and treatment. Em: Thieme. New York; 2004. p. 97-8. ^, ¹⁴14. Felipe L, Simões LC, Gonçalves DU, Mancini PC. Evaluation of the caffeine effect in the vestibular test. Braz J Otorhinolaryngol. 2005;71:758-62. ^and ¹⁵15. Ganança MM, Vieira R, Caovilla HH. Princípios em Otoneurologia. Rio de Janeiro: Atheneu; 1998. Several authors suggest a daily intake of up to three small cups (50 mL) of filtered coffee as a beneficial practice for the treatment, and may even potentiate the therapeutic effects of some medications.¹⁵15. Ganança MM, Vieira R, Caovilla HH. Princípios em Otoneurologia. Rio de Janeiro: Atheneu; 1998. Above this dose, the vasoconstrictor effects would predominate.

With regard to tinnitus, several authors suggest reducing the intake of caffeine as a supplementary treatment,¹⁶16. Azevedo AA, Figueiredo RR. Atualização em zumbido. Braz J Otorhinolaringol (Caderno de Debates). 2004;70:27-40. ^and ¹⁷17. Goodey R. Tinnitus treatment-state of the art. Em: Langguth BHG, Kleinjung T, Cacace A, Moller A, editores. Tinnitus: pathophysiology and treatment. 166ª ed. London: Elsevier; 2007. p. 237-46. but in the only controlled study ever conducted,¹⁸18. St. Claire L, Stothart G, Mc Kenna L, Rogers PJ. Caffeine abstinence: an ineffective and potentially distressing tinnitus therapy. Int J Aud. 2010;49:24-9. beneficial effects of caffeine reduction on tinnitus were not observed. The main objective of this study was to assess whether sensorineural tinnitus patients can obtain some benefit from the reduction of caffeine intake. The secondary objective was to try to identify the subgroups of patients most likely to benefit with this strategy.

Methods

This was a contemporary longitudinal cohort study. The sample size was initially determined considering as significant a difference of 20 points in THI score and of 2 points in VAS score (Fig. 1) in the interval from the beginning to the end of the study. Considering a statistical power of 0.80, the minimum sample size was set at 16 patients (for differences in THI scores and VSA inferior to 20 and 2 points, respectively, the required sample size would be even smaller).

Figure 1
Visual Analog Scale (VAS).

This study included 26 patients with sensorineural hearing loss, aged 24-76 years old, 15 males, treated in centers participating in the study between January 2008 and December 2009.

The following criteria were used:

Inclusion criteria

Patients with tinnitus for more than six months
Non-use of centrally acting drugs in the last six months
Tympanogram type A-n
Daily coffee intake exceeding three small cups/day (corresponding to 150 mL/day)
Age over 18 years old.

Exclusion criteria:

THI < 16 points
Tinnitus of muscular and vascular origin
Audiograms with conductive and mixed hearing loss
Association with disorders of the temporomandibular joint.

At first visit, patients underwent a complete otorhinolaryngological exam. In the same consultation, tonal and vocal audiometry and imitanciometry were performed. Patients included in the study completed the Tinnitus Handicap Inventory (THI), in its version validated for Brazilian Portuguese,¹⁹19. Schmidt LP, Teixeira VN, Dall'Igna C, Dallagnol D, Smith MM. Brazilian Portuguese Language version of the "Tinnitus Handicap Inventory": validity and reproducibility. Braz J Otorhinolaryngol. 2006;72:808-10. and also quantified the tinnitus with respect to the discomfort and intensity, according to a Visual Analog Scale (VAS) graded from 1 (minimal annoyance/intensity) to 10 (maximum annoyance/intensity).

After that, the patients were instructed to reduce their daily caffeine intake by at least 50% of their regular consumption; and all patients would consume quantities of less than 3 cups (50 mL per cup). For instance, a patient who consumed an average of 600 mL/day should reduce the intake to 150 mL/day or less, and a patient who consumed 200 mL/day should reduce this volume to 100 mL/day or less.

A weekly contact by phone call was established to confirm the reduction of consumption. A new reassessment with THI and VAS was performed after 30 days, and all patients who did not achieve the aforementioned reduction goal were excluded.

The absolute change of the situation before/after the treatment was given by the following formula:

Δ THI/VSA=(final THI/VSA−initial THI/VSA

As the main criterion for reduction of THI, the level of seven points was used, i.e. a reduction of seven points in the score was considered as an improvement, according to the study by Zeman et al. ²⁰20. Zeman R, Koller M, Figueiredo R, Azevedo A, Rates M, Coelho C, et al. Tinnitus handicap inventory for evaluating treatment effects: which changes are clinically relevant? Otolaryngol Head Neck Surg. 2011;145:282-7. Symptoms related to caffeine withdrawal were registered.

The statistical analysis consisted of the following tests:

Comparisons between the characteristics and improvement of THI were performed using Fisher's exact test (at least one expected frequency <5).

Then. the adjustment of the logistic model containing the characteristics with p-value <0.25 was performed. Only those characteristics with p-value <0.05 remained in the final model. All interactions were tested.

Finally, the Spearman correlation coefficient was applied to assess the degree of association between numerical variables and Δ THI/VAS.

The criterion for determining the significance was set at 5%. The statistical analysis was performed by SAS version 6.11 (SAS Institute, Inc. - Cary, North Carolina), R version 2.7.1, and EpiInfo version 6.04. The latter two are public domain programs.

The study was approved by the Ethics Committee for Medical Research under CAAE number - 0002.0.334.000-08.

Results

Of the 26 patients initially included, four did not return for the second evaluation. Table 2 shows general data of the sample, and Table 3 lists the subcategories distribution of the 22 patients who completed the study.

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Table 2
General characterization of sample.

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Table 3
Description of coffee intake levels, age, and laterality of the sample.

Of the 22 patients who completed the study, there was improvement in the THI scores (reduction of at least 7 points) in ten of them (45.5%). The observed mean decrease was 10.2 points for THI and 0.86 points for VSA; both were statistically significant (p = 0.030 and 0.017, respectively). Table 4 presents the description of initial and final THI and the variation (final - initial).

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Table 4
Description of initial and final THI, and variation (Δ THI = final THI - initial THI).

Table 5 shows the comparison of coffee intake, age, and laterality with improvement of THI. All features were selected for inclusion in the initial multivariate model.

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Table 5
Comparison between coffee intake, age and laterality and improvement of THI scores.

Interpreting one of the intersections, for instance, among the nine patients who consumed up to 300 mL of coffee per day, seven (77.8%) showed improvement in THI. Among the 13 patients who consumed more than 300 mL/day, three (23.1%) showed improvement in THI. With a p-value of 0.027, this feature was selected to be included in the initial multivariate model.

Table 6 shows the adjustments of the regression models. Three logistic regression models were elaborated.

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Table 6
Logistic regression model.

Thus, it was observed that those who consumed up to 300 mL of coffee had approximately 12 times the chance of improvement in THI versus patients who consume more than 300 mL of coffee (95% CI: 1.5-89.1).

In addition, patients younger than 60 years had eight times the chance of improvement in THI versus those aged over 60 years (95% CI 1.1-56.8). Patients with bilateral tinnitus had approximately 13 times the chance of improvement in THI versus those with unilateral tinnitus (95% CI, 1.2-133.9).

Analyzing the quantitative variable "coffee intake" (in mL) by the Spearman coefficient relative to Δ THI, Fig. 2 was obtained, confirming previous data (the higher the coffee intake, the lower the observed decrease in THI and VAS). Of the 22 patients who completed the study, only one (4.54%) showed a side effect (anxiety), possibly associated with the caffeine reduction. This patient consumed an average of 1200 mL of coffee daily.

Figure 2
Analysis of Δ THI, according to daily coffee intake (Spearman coefficient).

Discussion

Several articles on tinnitus have recommended the reduction of caffeine consumpion,¹⁶16. Azevedo AA, Figueiredo RR. Atualização em zumbido. Braz J Otorhinolaringol (Caderno de Debates). 2004;70:27-40. but until recently, there were no specific studies on this subject. Theoretically, the stimulating action of caffeine on the central nervous system can play a role in the excitability of the auditory pathways and, therefore, can modify some clinical aspects of tinnitus.⁹9. Dixit A,Vaney N, Tandon OP. Effect of caffeine on central auditory pathways: an evoked potential study. Hear Res. 2006; 220:61-6

In a recent study (2010)¹⁸18. St. Claire L, Stothart G, Mc Kenna L, Rogers PJ. Caffeine abstinence: an ineffective and potentially distressing tinnitus therapy. Int J Aud. 2010;49:24-9., the effects of the removal of caffeine on tinnitus in patients who consumed >150 mg of caffeine daily were evaluated. In this pseudo-randomized, crossed-over, placebo controlled study of 66 patients, no evidence to justify a reduction in caffeine intake was found. Conversely, some side effects caused by withdrawal from caffeine were noted. According to the authors, these effects could also lead to a worsening of tinnitus.

However, this study failed to assess the possible effects of reducing the caffeine in different subgroups presenting such symptoms. Considering that the division of patients into different subgroups has been repeatedly used in the study on tinnitus treatment, the authors consider this issue of utmost importance.¹⁵15. Ganança MM, Vieira R, Caovilla HH. Princípios em Otoneurologia. Rio de Janeiro: Atheneu; 1998. ^and ¹⁷17. Goodey R. Tinnitus treatment-state of the art. Em: Langguth BHG, Kleinjung T, Cacace A, Moller A, editores. Tinnitus: pathophysiology and treatment. 166ª ed. London: Elsevier; 2007. p. 237-46. In addition, the analysis of the placebo effect in studies with caffeine can be extremely difficult, since chronic caffeine users can easily recognize the removal of this substance, regardless of the flavor of the beverage.¹1. Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

Despite the statistical significance of data found in this study (a reduction of 10.2 points in THI and 0.86 points in VAS), it was observed that the effects of reducing caffeine intake on a tinnitus population as a whole would be small, according to the criteria used by Newman, which require as significant variations >20 points for THI.²¹21. Newman CW, Sandridge SA, Jacobson GP. Psychometric adequacy of the Tinnitus Handicap Inventory (THI) for evaluating treatment outcome. J Am Acad Audiol. 1998;9:153-60. Only four (18.4%) of 22 patients showed such reduction. Conversely, the study by Zeman et al. demonstrated that differences of 6-7 points in THI scores are clinically relevant.²⁰20. Zeman R, Koller M, Figueiredo R, Azevedo A, Rates M, Coelho C, et al. Tinnitus handicap inventory for evaluating treatment effects: which changes are clinically relevant? Otolaryngol Head Neck Surg. 2011;145:282-7. In this case, ten patients (45.5% of the total sample) of this study fit into this profile. In the subgroup analysis, it was found that in subgroups with <60 years, bilateral tinnitus, and initial daily intake up to 300 mL, the reduction in THI scores reaches close to 20 points. As a possible explanation for these differences, it may be surmised that elderly patients probably present a greater number of factors involved in the perception of tinnitus, such as presbycusis and use of multiple drugs to treat various medical conditions.

Patients with higher coffee intake may be more susceptible to symptoms after withdrawal from caffeine, as reported by St. Claire et al.¹⁸18. St. Claire L, Stothart G, Mc Kenna L, Rogers PJ. Caffeine abstinence: an ineffective and potentially distressing tinnitus therapy. Int J Aud. 2010;49:24-9. Although only one of the present study's patients have shown signs compatible with withdrawal, the possibility that the worsening of the tinnitus is a symptom related to abstinence cannot be ruled out, which could outweigh any potential benefit of a reduction in caffeine intake.

Furthermore, the present study did not examine the percentage of caffeine reduction in each patient. Thus, considering the methodology used, the greater the amount of caffeine consumed, the greater the impact caused by the reduction of intake, which could be responsible for a possible worsening of tinnitus, related to caffeine withdrawal.

Considering the data, the authors believe that this represents an appropriate management strategy for each patient. While there are no data supporting the beneficial effects of reducing caffeine for all tinnitus patients, some subgroups, such as young patients with bilateral tinnitus and those with moderate caffeine intake are more likely to improve.

Much like the procedures for vestibular disturbances, and considering the possible effects of an abrupt reduction of caffeine intake, perhaps the best option is a gradual reduction, rather than the complete suppression of this substance. Periods of 30 days of observation appear to be sufficient to evaluate a possible beneficial effect and should be routinely used in therapeutic tests.

Conclusion

The results obtained in this study suggest that there is no justification for the universal restriction of caffeine intake as a treatment for all patients with tinnitus. However, patients younger than 60 years, with bilateral tinnitus, and with daily coffee intake between 150 and 300 mL present greater benefits. The observation period of 30 days may be useful for the therapeutic decision.

References

¹
Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.
²
Associação Brasileira de Indústrias do Café (ABIC) [acessado 20 Ago 2010]. Disponível em: http//:www.abic.com.br
» http//:www.abic.com.br
³
Daly JM . Mechanism of action of caffeine. Em: SG, editor. Caffeine, coffee and health. New York: Raven Press; 1993. p. 97-150.
⁴
Dixit A, Vaney N, Tandon OP. Effect of caffeine ingestion on cognitive brain function. Ind J Physiol Pharmacol. 2004;48:79.
⁵
Lorist MM, Snel J, Kok A. Influence of caffeine on information processing stages in well rested and fatigued subjects. Psycophysiology. 1994;113:411-21.
⁶
Koppelstaeter F, Poeppel TD, Siedentopf CM, Ischebeck A, Verius M, Haala I, et al. Does caffeine modulate verbal working process memory? An fMRI study. Neuroimage. 2008;39:492-9.
⁷
Kawamura N, Maeda H, Nakamura J, Morita K, Nakazawa Y. Effects of caffeine on event-related potentials: comparison of oddball with single tone paradigms. Psychiatry Clin Neurosci. 1996;50:217-21.
⁸
Nehlig A, Boyet S. Dose-response study of caffeine effects on cerebral functioning activity with a specific focus on dependence. Brain Res. 2000;858:71-7.
⁹
Dixit A,Vaney N, Tandon OP. Effect of caffeine on central auditory pathways: an evoked potential study. Hear Res. 2006; 220:61-6
¹⁰
Slepecky S, Ulfendahl M, Flock A. Effects of caffeine and tetracaine on outer hair cells shortening suggest intracellular calcium involvment. Hear Res. 1988;32:11-22.
¹¹
Yamamoto T, Kakehata S, Yamada T, Saito T, Saito H, Akaike N. Caffeine rapidly decreases potassium condutance of dissociated outer hair cells of guinea pig cochlea. Brain Res. 1995;677:89-96.
¹²
Skellett RA, Crist JR, Fallon M, Bobbin RP. Caffeine-induced shortening of isolated outer hair cells: an osmotic mechanism of action. Hear Res. 1995;87:41-8.
¹³
Desmond ALD. Vestibular function: evolution and treatment. Em: Thieme. New York; 2004. p. 97-8.
¹⁴
Felipe L, Simões LC, Gonçalves DU, Mancini PC. Evaluation of the caffeine effect in the vestibular test. Braz J Otorhinolaryngol. 2005;71:758-62.
¹⁵
Ganança MM, Vieira R, Caovilla HH. Princípios em Otoneurologia. Rio de Janeiro: Atheneu; 1998.
¹⁶
Azevedo AA, Figueiredo RR. Atualização em zumbido. Braz J Otorhinolaringol (Caderno de Debates). 2004;70:27-40.
¹⁷
Goodey R. Tinnitus treatment-state of the art. Em: Langguth BHG, Kleinjung T, Cacace A, Moller A, editores. Tinnitus: pathophysiology and treatment. 166ª ed. London: Elsevier; 2007. p. 237-46.
¹⁸
St. Claire L, Stothart G, Mc Kenna L, Rogers PJ. Caffeine abstinence: an ineffective and potentially distressing tinnitus therapy. Int J Aud. 2010;49:24-9.
¹⁹
Schmidt LP, Teixeira VN, Dall'Igna C, Dallagnol D, Smith MM. Brazilian Portuguese Language version of the "Tinnitus Handicap Inventory": validity and reproducibility. Braz J Otorhinolaryngol. 2006;72:808-10.
²⁰
Zeman R, Koller M, Figueiredo R, Azevedo A, Rates M, Coelho C, et al. Tinnitus handicap inventory for evaluating treatment effects: which changes are clinically relevant? Otolaryngol Head Neck Surg. 2011;145:282-7.
²¹
Newman CW, Sandridge SA, Jacobson GP. Psychometric adequacy of the Tinnitus Handicap Inventory (THI) for evaluating treatment outcome. J Am Acad Audiol. 1998;9:153-60.

☆
Please cite this article as: Figueiredo RR, Rates MJ, de Azevedo AA, Moreira RK, Penido NO. Effects of the reduction of caffeine consumption on tinnitus perception. Braz J Otorhinolaryngol. 2014;80:416-21.

Publication Dates

Publication in this collection
Sep-Oct 2014

History

Received
03 Sept 2013
Accepted
17 Nov 2013

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Nehlig A. Are we dependent upon coffee and caffeine? A review on human and animal data. Neurosci Biobehav Rev. 1999;23:563-76.

[2] ²
Associação Brasileira de Indústrias do Café (ABIC) [acessado 20 Ago 2010]. Disponível em: http//:www.abic.com.br
» http//:www.abic.com.br

[3] ³
Daly JM . Mechanism of action of caffeine. Em: SG, editor. Caffeine, coffee and health. New York: Raven Press; 1993. p. 97-150.

[4] ⁴
Dixit A, Vaney N, Tandon OP. Effect of caffeine ingestion on cognitive brain function. Ind J Physiol Pharmacol. 2004;48:79.

[5] ⁵
Lorist MM, Snel J, Kok A. Influence of caffeine on information processing stages in well rested and fatigued subjects. Psycophysiology. 1994;113:411-21.

[6] ⁶
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Coffee preparation	Volume of cup (mL)	Caffeine content (mg/cup)
Coction (boiling)	150–190	111–177
Filtering	50–190	28–161
Espresso	50–150	74–99
Percolation	150–190	55–88
Instant (soluble)	50–190	19–34

Characteristics	Frequency
	n	%
Coffee intake (mL)
≤300	9	40.9
>300	13	59.1

Age (years)
<60	12	54.5
≥60	10	45.5

Laterality
Bilateral	14	63.6
Unilateral	8	36.4

Characteristic	Improvement				p-Value
	Yes		No
	n	%	n	%
Coffee intake (mL)
≤300	7	77.8	2	22.2	0.027^a
>300	3	23.1	10	76.9

Age (years)
<60	8	66.7	4	33.3	0.043^a
≥60	2	20.0	8	80.0

Laterality	9	64.3	5	35.7	0.03^a
Bilateral				287.5
Unilateral	1	12.5	7	87.5

Characteristics	n	Mean	SD	Minimum	1st Q	Median	3rd Q	Maximum
THI, initial	22	46.6	19.9	16.0	27.0	51.0	63.0	78.0
THI, final	22	36.4	18.4	14.0	16.0	34.0	52.5	66.0
THI variation	22	-10.2	19.4	-56.0	-19.0	-6.0	4.0	12.0

Variable	n	Mean	SD	Median	Minimum	Maximum
Age (years)	26	56.9	14.1	58.5	24	76
Tinnitus time (years)	26	6.44	6.30	5	0.5	20
Total coffee intake/day (mL)	26	509.6	292.6	400	150	1200
THI, initial	26	48.8	21.9	53	16	100
VAS, initial	26	6.88	1.84	6.5	5	10

Models	Coefficient	Standard error	p-Value	OR	95% CI
					Inferior	Superior
Model I
Constant	-1.2	0.7	0.067
Coffee intake (mL)
≤300	2.5	1.0	0.018	11.7	1.5	89.1
>300				1.0

Model II
Constant	-1.4	0.8	0.008
Age (years)
<60	2.1	1.0	0.038	8.0	1.1	56.8
≥60				1.0

Model II
Constant	-1.9	1.1	0.069
Laterality
Bilateral	2.5	1.2	0.036	12.6	1.2	133.9
Unilateral				1.0

Brasil

Brasil

Effects of the reduction of caffeine consumption on tinnitus perception ☆ ☆ Please cite this article as: Figueiredo RR, Rates MJ, de Azevedo AA, Moreira RK, Penido NO. Effects of the reduction of caffeine consumption on tinnitus perception. Braz J Otorhinolaryngol. 2014;80:416-21.

Abstracts

INTRODUCTION:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSION:

INTRODUÇÃO:

OBJETIVO:

MÉTODO:

RESULTADOS:

CONCLUSÃO:

Introduction

Methods

Results

Discussion

Conclusion

References

Publication Dates

History

Effects of the reduction of caffeine consumption on tinnitus perception ^☆ ☆ Please cite this article as: Figueiredo RR, Rates MJ, de Azevedo AA, Moreira RK, Penido NO. Effects of the reduction of caffeine consumption on tinnitus perception. Braz J Otorhinolaryngol. 2014;80:416-21.