Abstract
Purpose
Selective hypoglossal nerve stimulation has proven to be a successful treatment option in patients with obstructive sleep apnea. The aim of this pilot study was to investigate if there is a cross-innervation of the hypoglossal nerve in humans and if patients with this phenotype show a different response to hypoglossal nerve stimulation compared to those with ipsilateral-only innervation
Methods
Nineteen patients who previously received a selective hypoglossal nerve stimulation system (Inspire Medical Systems, Golden Valley, USA) were implanted with a nerve integrity system placing electrodes on both sides of the tongue. Tongue motions were recorded one and two months after surgery from transoral and transnasal views. Polysomnography (PSG) was also performed at two months. Electromyogram (EMG) signals and tongue motions after activation were compared with PSG findings.
Results
Cross-innervation showed significant correlation with bilateral tongue movement and bilateral tongue base opening, which were associated with better PSG outcomes.
Conclusion
Cross motor innervation of the hypoglossal nerve occurs in approximately 50% of humans, which is associated with a positive effect on PSG outcomes. Bilateral stimulation of the hypoglossal nerve may be a solution for non-responding patients with pronounced collapse at the soft palate during drug-induced sleep endoscopy.
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Introduction
Breathing cycle-dependent selective hypoglossal nerve stimulation (sHNS) has shown to be a successful treatment option in patients with obstructive sleep apnea (OSA) [1,2,3,4]. The hypoglossal nerve (XII) is responsible for all intrinsic and extrinsic muscles of the tongue [5]. XII has a solely motor function. Furthermore, the tongue is a complex muscle network, due to its phenomena to rotate nearly 360° [6]. This network of muscle fibers functions as a hydrostat. Either the muscles have no or only one rigid attachment [7]. The genioglossus muscle is the main opener of the upper airway. It arises from the mental spine of the mandible and inserts in the base of the tongue, without connection to another bone—one of the reasons why the upper airway is so vulnerable to collapse. During wakefulness, these muscle groups help to stiffen the upper airway walls and to prevent healthy subjects’ upper airways from collapsing. The different muscle groups of the tongue can be functionally divided into extrinsic retractors (styloglossus muscle and hyoglossus muscle), extrinsic protrusors (horizontal and oblique part of the genioglossus muscle), and intrinsic stiffeners of the tongue (transverse and vertical muscle, T/V) [5, 6].
The main target muscle for sHNS is the genioglossus muscle (GG) [8]. Its decrease in muscle tone during sleep can lead to obstructions [9]. If GG is activated during sleep by increasing tonic activation, the upper airway can be opened [10, 11]. Contracting the GG fibers pulls the tongue forward from its base and enlarges the upper airway [12]. Until today, not much is known of the complexity of the muscle groups and its innervation of the XII [5, 6, 13]. In 2010 and 2013, the anatomists Mu and Sanders described the innervation of the terminating distal branches of the hypoglossal nerve and the different functions of the muscles groups in a 3D model [5, 6].
In an early pilot study in 2001, Schwartz et al. demonstrated that unilateral stimulation of the hypoglossal nerve is feasible and a potential option for OSA patients [14]. In multicenter international trials and registers, sHNS showed efficacy, safety, and effectivenss in a clinical routine [15]. It is known for a while that different postoperative tongue motions are associated with heterogeneous therapy outcomes [12, 16]. The crucial part for the different tongue motions is the selective stimulation lead placement during the surgical procedure. A new surgical classification system of the terminating fibers of the XII was developed accordingly [17]. Another important point for improving clinical outcome is the opening of the soft palate during stimulation [18]. For this reason, tongue motions and its related correct selective stimulation of the XII fibers are one of the key steps for success [16].
The aim of this pilot study was to investigate if there is a cross-innervation of the XII in humans and if patients with this phenotype show a different response to sHNS compared to those with ipsilateral-only innervation.
Materials and methods
The study was approved by ethics committees and registered with http://www.clinicaltrials.gov (NCT02907398). All procedures followed were in accordance with the ethical standards of the responsible committee on human experimentation (institutional and national) and with the Helsinki Declaration of 1964 and later revision. Informed consent was signed by every patient. Consecutive patients, who received an sHNS implant with previously described inclusion criteria (Inspire II, Inspire Medical Systems, Maple Grove, MN, USA) at a single center in Munich, Germany, from October 2017 to November 2018 were included [3].
Intraoperative neuromonitoring
Intraoperative neuromonitoring was performed using a nerve integrity monitoring system (NIM 3.0, Medtronic Xomed, Jacksonville, FL, USA). The surgical steps have been previously described in detail [19,20,21] Furthermore, short-acting muscle relaxants were used for anesthesia to accommodate intraoperative examination of tongue stimulation in response to electrical stimulation. Four single-use 18-mm Prass Paired EMG-(electromyography) electrodes (Medtronic Xomed, Ref 8227304) were placed in the tongue: two on the right side and two on the contralateral left side [21].
This EMG was needed to distinguish between the main retractors (hyoglossus and styloglossus muscle) and main protrusors (horizontal and oblique genioglossus muscle). The electrodes for the retractors were placed 5 cm from the tip of the tongue just below the lateral corner of the tongue, superficially below the mucosa membrane on the left and right sides. The electrode for the protrusors were placed paramedian in the mouth floor on the left and right side.
During surgery, a bipolar electrical stimulation probe was used (Xomed Side-by-Side Bipolar Stimulating Probe, Medtronic Xomed, Ref 8225401) to differentiate the various nerve fibers [21]. After placement of the stimulation lead, the sHNS system was tested with an amplitude of 0.5 V (pulse width of 90 μs and a frequency of 33 Hz).
The EMG activity was recorded in all four channels with focus on the amplitudes:
1. genioglossus channel right, 2. genioglossus channel left, 3. hyoglossus channel right, and 4. hyoglossus channel left. The EMG signals were saved and later analyzed by a blinded person. For a cross over innervation of the XII, a maximum EMG amplitude difference of 1:10 was accepted. Larger ratios (> 1:10) were considered as ipsilateral innervations of the hypoglossal nerve.
Tongue motions were recorded at different time points:
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One month (M1) after surgery during the first activation of the system
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Two months (M2) after surgery during an in-lab polysomnography
Different tongue motions were recorded as described before [12]:
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Bilateral protrusion (BP)
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Right protrusion (RP)
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Mixed activation (MA)
Also, an awake transnasal flexible endoscopy was performed at M1 and M2 to assess the opening of the tongue base and soft palate during stimulation. At M1 and M2, the amplitude for stimulation of the functional threshold was used. The functional threshold is defined as the level of voltage at which bulk tongue motion is achieved [12]. At M2, the titrated amplitude for stimulation from the in-lab PSG was used.
Furthermore, the degree of palatoglossus coupling (PGC) was calculated as described before [18]: 0 = no change, 1 = some enlargement, and 2 = large enlargement.
Statistical analysis
Version 23.0 of the Statistical Package for the Social Sciences (SPSS) software (IBM, Armonk, NY) was used. Descriptive statistics were calculated for demographic variables. A paired t test was used to compare baseline and postimplantation values. The patients’ data were compared using the Mann–Whitney U test for metric data. Spearman rank correlation coefficient (R) was used for the analysis of correlations (0.00–0.19 = very weak correlation, 0.20–0.39 = weak correlation, 0.4–0.59 = moderate correlation, 0.60–0.79 = strong correlation, 0.80–1.00 = very strong correlation). Data are given as mean ± standard deviation if not otherwise stated. P values < 0.05 were considered statistically significant.
Ethical considerations
Informed consent was obtained for each patient. The study was approved by the local ethic committee (Faculty for Medicine, ethical committee, Technical University of Munich, Germany).
Data availability statement
All relevant data are within the paper.
Results
Between October, 2017 and November, 2018, 19 patients, who received an implant, were enrolled. The demographic baseline characteristics are shown in Table 1.
The measuring of the EMG amplitudes during stimulation of the right hypoglossal nerve, revealed in 9 (47%) patients a cross over (bilateral) innervation of the genioglossus muscle. Ten (53%) showed an ipsilateral innervation. Further details for every patient are shown in Table 2.
Nine patients showed a right protrusion at M1 and 6 patients at M2. The other 11 patients at M1 had a bilateral protrusion, meanwhile at M2, 13 patients revealed a bilateral tongue motion (Fig. 1). No mixed activations were recorded.
Almost 50% of the patients showed an ispilateral or bilateral opening of the tongue base during stimulation at M1 and M2 (Fig. 2). The calculated PGC effect was seen in more than 74% at M1 and M2. These 74% of patients had at least some enlargement at the level of the soft palate during stimulation.
Overall, the baseline (pre-implant) total and titrated apnea–hypopnea index (AHI) of all patients was reduced from 43.04 ± 16.19/h to 19.51 ± 17.59/h (total AHI at M2; p < 0.001) and to 6.7 ± 21.2/h (titrated AHI at M2; p < 0.001). The group of patients with bilateral innervation of the hypoglossal nerve (cross-innervation) showed a reduction in AHI from 39.07 ± 18.74/h to 15.98 ± 10.39/h (total AHI at M2; p < 0.005) and to 5.3 ± 28.1/h (titrated AHI at M2; p < 0.001). The ispilateral innervation group showed a reduction from 45.26 ± 13.57/h to 22.98 ± 23.67/h (total AHI at M2; p < 0.023) and to 7.0 ± 22.1/h (titrated AHI at M2; p < 0.001; Table 3). Further parameters for the apnea index (AI), hypopnea index (HI), oxygen disturbance index (ODI), minimum SpO2, and mean SpO2 are shown in detail in Table 3.
The cross-innervation showed a significant correlation with a bilateral tongue movement at M1 and M2 (R = 0.798, p < 0.001; R = 0.620, p = 0.006; Fig. 3). Furthermore, a significant correlation could be found between the bilateral innervation and bilateral tongue base opening at M1 and M2 (R = 0.671, p = 0.002; R = 0.671, p = 0.002). Additionally, patients with cross-innervation had a greater PGC effect than patients with ipsilateral innervation (R = 0.707, p = 0.006; R = 0.707, p = 0.001). These findings imply that patients with cross-innervation tend to have a bilateral tongue protrusion, hence a better opening of the airways at the level of the tongue and consequently a better PCG effect.
At the same time, PGC shows a significant correlation with the relative reduction of AHI at M2 (R = 0.482, p = 0.037). Cross-innervation of the hypoglossal nerve seems to be associated with a better PGC and reduction of AHI.
Discussion
Our pilot study confirmed the efficacy of sHNS in OSA patients as it has been described before [2, 22,23,24]. The highly selective placement of the stimulation lead and the associated correct activation of the muscle groups help to prevent the upper airway from collapsing and support an active opening. Therefore, the right nerve fibers have to be the target [21]. It is essential to exclude the lateral fibers of the XII. The main objective during surgery is to distinguish between the lateral and medial nerve fibers [19]. In our pilot study, the electrodes for neuromonitoring were not only on one side as usual in clinical routine, but identically on both sides of the tongue. This two-sided electrode placement supports the measurement of a contralateral innervation of the XII by recording the opposite EMG. Preliminary results have shown that a bilateral innervation of the XII seems to be concordant with a better opening on the soft palate [18]. This type of innervation could appear to be a key factor during HNS. Safirruddin et al. described variations in the opening of the retropalatal region during stimulation among patients [18, 25]. In all patients, regardless of therapy response, retrolingual opening during stimulation was present [18, 25]. But there is a difference in the opening of the soft palate between patients. One hypothesis from earlier studies to describe this effect on the soft palate is the palatoglossus coupling (PCG). The palatoglossus muscle is a thin muscle running in the anterior pillar from the soft palate into the tongue [18, 26, 27]. If during stimulation, the tongue is flattened and elongated in a stiffened manner; this muscle acts like an anchor and pulls the soft palate forward. The intrinsic transverse and vertical muscle fibers need to be activated to stiffen the tongue. The palatoglossus muscle exhibits activation to negative pressure in patients with OSA, which could play a role in restoring upper airway patency [27]. In such cases, the soft palate may have the ability to maintain patency during respiration, but the falling back of the mass of the tongue creates secondary palatal collapse in the presence of a primary base-of-tongue collapse etiology. This may be explanatory for how the stiffened, unhindered protrusion during stimulation helps to decrease or eliminate collapse of the soft palate. One hypothesis why OSA patients with sHNS are not fully responding to therapy is the persisting of obstructions at the soft palate [25, 28]. Even in some patients, a protrusion of the stiffened tongue can be detected. If a bilateral stimulation of the XII is performed, an activation of the intrinsic T/V muscles probably shows a stronger effect on the soft palate. This could be related in pulling both palatoglossus muscles forward. An anchor on both sides tying the soft palate to the tongue produce a stronger effect on the palate opening, thereby overcoming the vulnerability of the Starling resistor and Bernoulli effect. This hypothesis could be the explanation why a better clinical outcome in our sHNS patients could be detected with cross over innervation of the XII. Also, in patients with a measured intraoperatively ipsilateral innervation and initially confirmed mismatch of obstructions at the palate, who are not fully responding to therapy, a bilateral stimulation of the XII could potentially solve the problem.
Currently, there is no known predictor for whether any given patient will display a bilateral versus ipsilateral phenotype, and even with an ipsilateral innervation, it is not certain that these patients will fare worse as many are full-therapy responders. Further research is needed to distinguish preoperatively the instances in which bilateral stimulation of the XII could be clinically successful and warranted in the setting of the initial implant. Likewise, sub-optimal therapy responders with clear ipsilateral innervation-activation phenotype could be “upgraded” to bilateral stimulation to further this line of inquiry. The development of new stimulation systems may also include the development of bilateral stimulation strategies, for which patients with pronounced collapse at the soft palate during drug-induced sleep endoscopy might be good candidates. This preliminary data will help to set up further clinical trials on the existence and predictive value of cross motor innervation. At the moment, patients with a complete concentric collapse at the soft palate are excluded from sHNS. Probably these patients could still be responders for HNS, if cross motor innervation is presented.
Furthermore, another question would be, if a patient who shows a complete concentric collapse during drug-induced sleep endoscopy—an exclusion criterion for sHNS—could this patient even be a good responder to therapy due to a cross motor innervation of the hypoglossal nerve? [28] Or should he/she go one step further, which would mean to do a bilateral stimulation of the hypoglossal nerve to solve the obstructions at the soft palate? Further research is needed to answer these questions.
Conclusion
Based on the results of this pilot study, cross motor innervation of the hypoglossal nerve seems to appear in about 50% of humans. This bilateral innervation seems to have a more positive outcome on the soft palate during stimulation and seems to be associated with a better impact on the clinical outcome. A bilateral stimulation of the hypoglossal nerve could be a solution for non-responders at the level of the soft palate.
References
Heiser C, Maurer JT, Hofauer B, Sommer JU, Seitz A, Steffen A (2017) Outcomes of upper airway stimulation for obstructive sleep apnea in a multicenter German postmarket study. Otolaryngol Head Neck Surg 156(2):378–384
Steffen A, Sommer JU, Hofauer B, Maurer JT, Hasselbacher K, Heiser C (2018) Outcome after one year of upper airway stimulation for obstructive sleep apnea in a multicenter German post-market study. Laryngoscope 128(2):509–515
Heiser C, Knopf A, Bas M, Gahleitner C, Hofauer B (2017) Selective upper airway stimulation for obstructive sleep apnea: a single center clinical experience. Eur Arch Otorhinolaryngol 274(3):1727–1734
Woodson BT, Strohl KP, Soose RJ, Gillespie MB, Maurer JT, de Vries N, Padhya TA, Badr MS, Lin HS, Vanderveken OM, Mickelson S, Strollo PJ Jr (2018) Upper airway stimulation for obstructive sleep apnea: 5-year outcomes. Otolaryngol Head Neck Surg:194599818762383
Mu L, Sanders I (2010) Human tongue neuroanatomy: nerve supply and motor endplates. Clin Anat 23(7):777–791
Sanders I, Mu L (2013) A three-dimensional atlas of human tongue muscles. Anat Rec (Hoboken) 296(7):1102–1114
Fregosi RF, Ludlow CL (2014) Activation of upper airway muscles during breathing and swallowing. J Appl Physiol (1985) 116(3):291–301
Wijesuriya NS, Gainche L, Jordan AS, Berlowitz DJ, LeGuen M, Rochford PD, O'Donoghue FJ, Ruehland WR, Carberry JC, Butler JE, Eckert DJ (2018) Genioglossus reflex responses to negative upper airway pressure are altered in people with tetraplegia and obstructive sleep apnoea. J Physiol
Carberry JC, Hensen H, Fisher LP, Saboisky JP, Butler JE, Gandevia SC, Eckert DJ (2015) Mechanisms contributing to the response of upper-airway muscles to changes in airway pressure. J Appl Physiol (1985) 118(10):1221–1228
Kezirian EJ, Goding GS Jr, Malhotra A, O'Donoghue FJ, Zammit G, Wheatley JR, Catcheside PG, Smith PL, Schwartz AR, Walsh JH, Maddison KJ, Claman DM, Huntley T, Park SY, Campbell MC, Palme CE, Iber C, Eastwood PR, Hillman DR, Barnes M (2014) Hypoglossal nerve stimulation improves obstructive sleep apnea: 12-month outcomes. J Sleep Res 23(1):77–83
Oliven A, Tov N, Geitini L, Steinfeld U, Oliven R, Schwartz AR, Odeh M (2007) Effect of genioglossus contraction on pharyngeal lumen and airflow in sleep apnoea patients. Eur Respir J 30(4):748–758
Heiser C, Maurer JT, Steffen A (2016) Functional outcome of tongue motions with selective hypoglossal nerve stimulation in patients with obstructive sleep apnea. Sleep Breath 20(2):553–560
Kubin L, Jordan AS, Nicholas CL, Cori JM, Semmler JG, Trinder J (2015) Crossed motor innervation of the base of human tongue. J Neurophysiol 113(10):3499–3510
Schwartz AR, Bennett ML, Smith PL, De Backer W, Hedner J, Boudewyns A, Van de Heyning P, Ejnell H, Hochban W, Knaack L, Podszus T, Penzel T, Peter JH, Goding GS, Erickson DJ, Testerman R, Ottenhoff F, Eisele DW (2001) Therapeutic electrical stimulation of the hypoglossal nerve in obstructive sleep apnea. Arch Otolaryngol Head Neck Surg 127(10):1216–1223
Strollo PJ Jr, Soose RJ, Maurer JT, de Vries N, Cornelius J, Froymovich O, Hanson RD, Padhya TA, Steward DL, Gillespie MB, Woodson BT, Van de Heyning PH, Goetting MG, Vanderveken OM, Feldman N, Knaack L, Strohl KP, Group ST (2014) Upper-airway stimulation for obstructive sleep apnea. N Engl J Med 370(2):139–149
Steffen A, Kilic A, Konig IR, Suurna MV, Hofauer B, Heiser C (2017) Tongue motion variability with changes of upper airway stimulation electrode configuration and effects on treatment outcomes. Laryngoscope
Heiser C, Knopf A, Hofauer B (2017) Surgical anatomy of the hypoglossal nerve: a new classification system for selective upper airway stimulation. Head Neck 39(12):2371–2380
Heiser C, Edenharter G, Bas M, Wirth M, Hofauer B (2017) Palatoglossus coupling in selective upper airway stimulation. Laryngoscope 127(10):E378–E383
Heiser C, Thaler E, Boon M, Soose RJ, Woodson BT (2016) Updates of operative techniques for upper airway stimulation. Laryngoscope 126(Suppl 7):S12–S16
Heiser C, Thaler E, Soose RJ, Woodson BT, Boon M (2017) Technical tips during implantation of selective upper airway stimulation. Laryngoscope
Heiser C, Hofauer B, Lozier L, Woodson BT, Stark T (2016) Nerve monitoring-guided selective hypoglossal nerve stimulation in obstructive sleep apnea patients. Laryngoscope 126(12):2852–2858
Heiser C, Knopf A, Bas M, Gahleitner C, Hofauer B (2016) Selective upper airway stimulation for obstructive sleep apnea: a single center clinical experience. Eur Arch Otorhinolaryngol
Heiser C, Maurer JT, Steffen A (2016) Selective upper airway stimulation - German post market study. Sleep 39((Supplement)(0379)):136–137
Heiser C, Steffen A, Boon M, Hofauer B, Doghramji K, Maurer JT, Sommer JU, Soose R, Strollo PJ Jr, Schwab R, Thaler E, Withrow K, Kominsky A, Larsen C, Kezirian EJ, Hsia J, Chia S, Harwick J, Strohl K, Mehra R, ADHERE registry investigators (2019) Post-approval upper airway stimulation predictors of treatment effectiveness in the ADHERE registry. Eur Respir J 53(1)
Safiruddin F, Vanderveken OM, de Vries N, Maurer JT, Lee K, Ni Q, Strohl KP (2015) Effect of upper-airway stimulation for obstructive sleep apnoea on airway dimensions. Eur Respir J 45(1):129–138
Mortimore IL, Douglas NJ (1997) Palatal muscle EMG response to negative pressure in awake sleep apneic and control subjects. Am J Respir Crit Care Med 156(3 Pt 1):867–873
Van de Graaff WB, Gottfried SB, Mitra J, van Lunteren E, Cherniack NS, Strohl KP (1984) Respiratory function of hyoid muscles and hyoid arch. J Appl Physiol Respir Environ Exerc Physiol 57(1):197–204
Vanderveken OM, Maurer JT, Hohenhorst W, Hamans E, Lin HS, Vroegop AV, Anders C, de Vries N, Van de Heyning PH (2013) Evaluation of drug-induced sleep endoscopy as a patient selection tool for implanted upper airway stimulation for obstructive sleep apnea. J Clin Sleep Med 9(5):433–438
Acknowledgments
We would like to thank Luke Lozier for the scientific talks and interactions on this topic.
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Conflict of interest
Clemens Heiser is a consultant for Inspire Medical Systems and received consultancy fees, reimbursement of conference fees, and travel and accommodation expenses from Neuwirth Medical Products, Löwenstein, and Sutter Medizintechnik. Furthermore, he is a consultant and on the advisory board of Galvani.
Olivier Vanderveken has the following potential conflicts of interest related to the topic of the manuscript: research support and lecture fees from Inspire Medical Systems, research grant from and consultancy for Philips Respironics, research grant and lecture fees from Somnomed, consultancy for Nyxoah, research support from ReVent, research support from Nightbalance.
Benedikt Hofauer received personal fees and travel expenses from Inspire Medical Systems.
Günther Edenharter has no conflict of interest.
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Heiser, C., Vanderveken, O.M., Edenharter, G.M. et al. Cross motor innervation of the hypoglossal nerve—a pilot study of predictors for successful opening of the soft palate. Sleep Breath 25, 425–431 (2021). https://doi.org/10.1007/s11325-020-02112-2
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DOI: https://doi.org/10.1007/s11325-020-02112-2