Morphometric and Immunohistochemical Characteristics of the Adult Human Soft Palate Muscles.

The soft palate is the only structure that reversibly separates the respiratory and gastrointestinal systems. Most species can eat and breathe at the same time. Humans cannot do this and malfunction of the soft palate may allow food to enter the lungs and cause fatal aspiration pneumonia. Speech is the most defining characteristic of humans and the soft palate, along with the larynx and tongue, plays the key roles. In addition, palatal muscles are involved in snoring and obstructive sleep apnea. Considering the significance of the soft palate, its function is insufficiently understood. The objectives of this study were to document morphometric and immunohistochemical characteristics of adult human soft palate muscles, including fiber size, the fiber type, and myosin heavy chain (MyHC) composition for better understanding muscle functions. In this study, 15 soft palates were obtained from human autopsies. The palatal muscles were separated, cryosectioned, and stained using histological and immunohistochemical techniques. The results showed that there was a fast type II predominance in the musculus uvulae and palatopharyngeus and a slow type I predominance in the levator veli palatine. Approximately equal proportions of type I and type II fibers existed in both the palatoglossus and tensor veli palatine. Soft palate muscles also contained hybrid fibers and some specialized myofibers expressing slow-tonic and embryonic MyHC isoforms. These findings would help better understand muscle functions.

Functional characterization of extrinsic tongue muscles in the Pink1-/- rat model of Parkinson disease.

Parkinson disease (PD) is associated with speech and swallowing difficulties likely due to pathology in widespread brain and nervous system regions. In post-mortem studies of PD, pathology has been reported in pharyngeal and laryngeal nerves and muscles. However, it is unknown whether PD is associated with neuromuscular changes in the tongue. Prior work in a rat model of PD (Pink1-/-) showed oromotor and swallowing deficits in the premanifest stage which suggested sensorimotor impairments of these functions. The present study tested the hypothesis that Pink1-/- rats show altered tongue function coinciding with neuromuscular differences within tongue muscles compared to wildtype (WT). Male Pink1-/- and WT rats underwent behavioral tongue function assays at 4 and 6 months of age (n = 7-8 rats per group), which are time points early in the disease. At 6 months, genioglossus (GG) and styloglossus (SG) muscles were analyzed for myosin heavy chain isoforms (MyHC), α-synuclein levels, myofiber size, centrally nucleated myofibers, and neuromuscular junction (NMJ) innervation. Pink1-/- showed greater tongue press force variability, and greater tongue press forces and rates as compared to WT. Additionally, Pink1-/- showed relative increases of MyHC 2a in SG, but typical MyHC profiles in GG. Western blots revealed Pink1-/- had more α-synuclein protein than WT in GG, but not in SG. There were no differences between Pink1-/- and WT in myofiber size, centrally-nucleated myofibers, or NMJ innervation. α-synuclein protein was observed in nerves, NMJ, and vessels in both genotypes. Findings at these early disease stages suggest small changes or no changes in several peripheral biological measures, and intact motor innervation of tongue muscles. Future work should evaluate these measures at later disease stages to determine when robust pathological peripheral change contributes to functional change, and what CNS deficits cause behavioral changes. Understanding how PD affects central and peripheral mechanisms will help determine therapy targets for speech and swallowing disorders.

[Research on apoptosis changes of tensor veli palatini in patients with obstructive sleep apnea-hypopnea syndrome].

OBJECTIVE: To explore apoptosis changes of dilator muscles in the upper airway by detecting the expression of Bax, Bcl-2 in tensor veli palatini in patients with OSAHS. METHOD: The expression of Bax and Bcl-2 were detected in tensor veli palatini in 30 cases with OSAHS and 10 cases chronic tonsillitis without OSAHS by immunohistochemistry and image analytical system, and the results were analyzed. RESULT: (1) The expression levels of Bax in the OSAHS group increased significantly compared to control group (P < 0.05), but there were no significant differences of Bcl-2 expression between two groups, the ratio of Bax/Bcl-2 increased significantly (P < 0.05). (2) There were positive correlations between AHI and the expression levels of Bax (r = 0.697, P < 0.01) respectively in the test group. CONCLUSION: The results indicate that apoptosis occurred in tensor veli palatini in patients with OS AHS, and the more severity of OSAHS, the more apoptosis.

Upper airway muscle inflammation and denervation changes in obstructive sleep apnea.

Inflammatory cell infiltration and afferent neuropathy have been shown in the upper airway (UA) mucosa of subjects with obstructive sleep apnea (OSA). We hypothesized that inflammatory and denervation changes also involve the muscular layer of the pharynx in OSA. Morphometric analysis was performed on UA tissue from nonsnoring control subjects (n = 7) and patients with OSA (n = 11) following palatal surgery. As compared with control subjects, inflammatory cells were increased in the muscular layer of patients with OSA, with CD4+ and activated CD25+ T cells (both increased approximately threefold) predominating. Inflammation was also present in UA mucosa, but with a different pattern consisting of CD8+ (2.8-fold increase) and activated CD25+ (3.2-fold increase) T cell predominance. As ascertained by immunoreactivity for the panneuronal marker PGP9.5, there was a dramatic (5.7-fold) increase in intramuscular nerve fibers in OSA patients compared with control subjects, as well as direct evidence of denervation based on positive immunostaining of the muscle fiber sarcolemmal membrane for the neural cell adhesion molecule in patients with OSA. These data suggest that inflammatory cell infiltration and denervation changes affect not only the mucosa, but also the UA muscle of patients with OSA. This may have important implications for the ability to generate adequate muscular dilating forces during sleep.

Abnormal palatopharyngeal muscle morphology in sleep-disordered breathing.

The aim of the present study was to investigate whether histopathological changes can be detected in two soft palate muscles, the palatopharyngeus and the uvula, in 11 patients with long duration of sleep-disordered breathing (SDB). Muscle samples were collected from patients undergoing uvulo-palatopharyngoplasty (UPPP). Reference samples from the corresponding areas were obtained at autopsy from five previously healthy subjects. Muscle morphology, fibre type and myosin heavy chain (MyHC) compositions were analysed with enzyme-histochemical, immunohistochemical and biochemical techniques. The muscle samples from the patients, and especially those from the palatopharyngeus, showed several morphological abnormalities. The most striking findings were (i) increased amount of connective tissue, (ii) abnormal variability in fibre size, (iii) increased proportion of small-sized fibres, (iv) alterations in fibre type and MyHC compositions, (v) increased frequency of fibres containing developmental MyHC isoforms. Our findings point towards a pathological process of denervation and degeneration in the patient samples. Conclusively, the morphological abnormalities suggest a neuromuscular disorder of the soft palate in SDB patients.

Histological indications of a progressive snorers disease in an upper airway muscle.

The etiology of upper airway collapsibility in patients with snoring and obstructive sleep apnea (OSA) remains unclear. Local muscular abnormalities, including neurogenic lesions, could be a contributory factor. The aim of this study was to histologically evaluate the hypothesis of a progressive snorers disease. Biopsies of palatopharyngeal muscle were obtained from 21 patients with habitual snoring and different degrees of upper airway obstruction (10 patients with OSA) and 10 nonsnoring control subjects. Morphological abnormalities, including neurogenic signs (e.g., type grouping), were blindly quantified. The degree of abnormality was significantly increased in patients compared with control subjects. The individual score of abnormalities was significantly correlated to the percentage periodic obstructive breathing but not to oxygen desaturation index. Analyses of the individual fiber-size spectra demonstrated a significantly increased number of hypertrophied and/or atrophied fibers in patients compared with controls. The subjects were also divided into three groups according to their type of nocturnal breathing, i.e., nonsnorers, patients with < 20%, and patients with > or = 45% obstructive breathing. These groups correlated significantly with the degree of abnormality and pathological fiber-size spectra. In conclusion, these results support the hypothesis of a progressive local neurogenic lesion, caused by the trauma of snoring, as a possible contributory factor to upper airway collapsibility.

Upper airway collapsibility, and contractile and metabolic characteristics of musculus uvulae.

Physiologic, metabolic, and histochemical characteristics of one upper airway (UA) dilator muscle (musculus uvulae; MU) differ between sleep apnea hypopnea syndrome (SAHS) and nonapneic snorers. We hypothesized that these differences in MU characteristics could result from the cumulative effects of the diurnal and nocturnal intermittent contractions of UA muscles in order to compensate for a permanent increase in UA collapsibility. The aim of this study was to determine the influence of UA collapsibility on MU characteristics. Seventeen SAHS and three nonapneic snorers, who underwent an uvulo-palato-pharyngoplasty as a treatment for snoring or SAHS, participated in the study. Awake and sleeping UA critical pressure (Pcrit) was measured during continuous positive or negative airway pressure trials by analysis of the relationship between maximal inspiratory flow and the upstream pressure of flow-limited breathing cycles. Maximum isometric twitch (Pt) and tetanic tension (Po), fatigability measurements, activities of marker enzymes for anaerobic and aerobic-oxidative profile, and fiber type proportions and areas of MU were determined. There was a significant positive relationship between Pt, Po, and Pcrit measured during wakefulness and sleep. The fatigability index was negatively correlated with awake Pcrit values (r = -0.79). Activity level of the anaerobic enzymes as well as the percentage of surface occupied by type I and type IIA muscle fibers as correlated witb awake Pcrit. We conclude that the differences in awake UA collapsibility help to determine the contractile properties and metabolic and histochemical characteristics of MU.