A Cone Beam CT Study of Upper Airway Morphology in Perimenopausal and Postmenopausal Women.

PURPOSE: Menopause is accompanied by a decline in estrogen and progesterone. Several studies have demonstrated that upper airway patency decreases in women after menopause, while morphology changes are still a lack of evidence. This study aimed to explore upper airway morphology changes in perimenopausal and postmenopausal women.
METHODS: This retrospective cross-sectional study included 367 consecutive Chinese female patients over 25 years old who had routinely taken large-field cone beam computed tomography in the imaging library of Peking University School and Hospital of Stomatology from October 2016 to September 2020. A total of 283 males were screened as sex controls according to the same age group. Upper airway morphology, hyoid position and facial pattern were measured. The association between perimenopausal and postmenopausal years and upper airway morphology in both sexes was analyzed.
RESULTS: Perimenopausal women (aged 45-54 years) showed a significant decrease in the volume (3172.91mm3, 95% CI = 653.86-5691.96) and minimum cross-sectional area (37.08 mm2, 95% CI = 5.36-68.80), and a significant increase in the length (-1.96mm, 95% CI = -3.62 to -0.29) of upper airway compared to adjacent reproductive years (aged 35-44), while this difference was neither seen in other adjacent two reproductive age groups of females nor in the same age groups of males. In postmenopausal women (55 years and older), hyoid position was significantly lower (-2.74mm, 95% CI = -4.42 to -1.07) than either age group, while no similar changes were seen in men.
CONCLUSION: Women had smaller airway volume, reduced upper airway cross-sectional area and longer airway length in perimenopausal years, and a significantly lower hyoid position in postmenopausal years. These changes may be related to menopause itself and independent of the changes associated with aging.

Introduction

Menopause, the permanent cessation of menstrual cycles results from reduced secretion of the ovarian hormones estrogen and progesterone, marks the ending of reproductive life in women.1–3 The transition to menopause is a complex physiological process. Symptoms like hot flashes and night sweats, insomnia, and mood instability may be the first signs of ovarian function failure before menstruation stops.4

Menopause brings various unfavorable changes. Many chronic diseases are thought to occur mainly in men, including cardiovascular diseases, diabetes and stroke.5–9 However, due to the lack of protection from sex hormones, the gender differences of prevalence seem to be attenuated, even postmenopause women have higher risk of hypertension and heart disease than men.9,10 Studies have shown that it may be menopause itself rather than aging account for the pronounced increased risk.2,3,11 Each year of earlier menopause is associated with a 2% increase in all-cause mortality.12,13

In the reproductive years, sex hormones exert a profound protective effect on upper airway patency in women compared with men of a similar age.14–16 Progesterone is a known respiratory stimulant that increases upper airway muscle tone, but progesterone levels decline after menopause, and respiratory drive decreases during menopausal transition.17–19 Fat distribution also changes and is more likely to be distributed in the upper body and trunk area in postmenopausal years.20 The activity of genioglossus muscle decreases in menopausal women, while hormone replacement therapy increases genioglossus muscle activity significantly.21 All of these changes are detrimental to upper airway patency in women after menopausal years.

Physiological changes in upper airway may influence morphology. However, the morphology of upper airway in perimenopausal and postmenopausal women are still a lack of evidence. Cone beam computed tomography (cone beam CT) is an advancement in CT imaging, which uses low-dose cross-sectional technique and provides more rapid acquisition of a data set. It can successfully discriminate borders of soft and hard tissue structures and has been widely used to evaluate upper airway morphology and craniofacial anatomy.22–24 In this study, we collected cone beam CT images to study upper airway morphology in different stages of women and hypothesized that compared with reproductive years, there is a significant deterioration in the upper airway morphology in perimenopausal and postmenopausal women.

Materials and Methods

The present study was a retrospective cross-sectional study conducted at Peking University School and Hospital of Stomatology, Beijing. This study was performed in line with the principles of the Declaration of Helsinki. Approval was granted by the Ethics Committee of Peking University Stomatology School and Hospital [PKUSSIRB-202054026].

Participants

In this study, we retrospectively collected image data of all patients who had routinely taken large-field cone beam CT in the imaging library of the Department of Radiology, Peking University School and Hospital of Stomatology from October 2016 to September 2020. We excluded patients from the department of traumatology, oncology, orthognathic surgery or cleft lip and palate according to the application form. Other exclusion criteria were as follows: 1) history of oral maxillofacial fractures, 2) severe craniofacial destruction and defects, 3) severe Class II and Class III craniofacial deformities, and 4) edentulousness or incorrect occlusal position.

Recent study has suggested that the mean age at natural menopause in Chinese women is 49.3 ± 3.3 years (median 50.0 years),9 while other studies have found similar conclusion.25,26 Thus, we took 45–54 years as the perimenopausal group and ≥55 years as the postmenopausal group. Two groups of women in reproductive age, 25–34 years and 35–44 years, served as age controls. A total of 367 women meet the criteria above, and 283 men were screened as sex controls according to the same age group (Figure 1).

Figure 1

Screening process of the samples included in the analysis.

Imaging Analysis

All cone beam CT scans were performed in routine procedure. Patients were kept Frankfort plane (FH plane, where the uppermost point of the external auditory canal and the lowest point of the infraorbital rim are located) parallel to the horizontal plane in the seated position during scanning. Subjects were asked to stay awake, with the posterior teeth in occlusal contact and not chewing or swallowing.

The morphology of the upper airway and hyoid bone position were measured using Dolphin 11.95 (Patterson Dental Supply Inc, Chatsworth, CA). The upper boundary of the total upper airway was the line connecting the point of the sella turcica (S) and the point of the posterior nasal spine (PNS), the lower boundary was the plane parallel to the FH plane where the valley of the epiglottis (EV) was located. The volume (UV), length (UL), minimum cross-sectional area (Amin) of upper airway were measured in the mid-sagittal plane (Figure 2A).

Figure 2

Measurements of the upper airway morphology and hyoid bone position. (A) Airway measurements in the median sagittal plane. (B) Reconstructed lateral cephalogram.

In the reconstructed lateral cephalogram (Figure 2B), we used the angle of ANB to represent sagittal facial pattern, while the angle between FH plane (Frankfort plane) and MP plane (mandibular plane) and the angle between SN plane and MP plane were measured to represent vertical facial pattern. Distance between the superior anterior point of the hyoid bone (H) and MP plane was used to represent hyoid bone position (MPH). All data were measured three times repeatedly.

Statistical Analysis

Analysis was performed using SPSS 26.0 (Armonk, New York, USA). Kolmogorov–Smirnov test was used to test normality. One-way analysis of variance (ANOVA) was used for data processing between four age groups if the homogeneity of variance assumptions were satisfied; otherwise, Kruskal–Wallis analysis was employed. Independent samples t-test was used to compare between two age groups. Statistical significance was determined using a threshold p-value of 0.05.

Results

All patients were measured for craniofacial characteristics as facial pattern may affect upper airway morphology. As is shown in Table 1, no difference was found in sagittal and vertical facial pattern between age groups.

Table 1

Craniofacial Characteristics in Age Groups

Females	Age Groups (Mean ± SD)				Statistics	P value
	[25–34] y (n=115)	[35–44] y (n=85)	[45–54] y (n=77)	[≥55] y (n=90)
ANB (°)	4.04±2.62	4.13±2.32	4.08±2.26	4.08±2.25	F=0.023	0.995
MP-FH (°)	24.65±6.09	24.62±7.23	24.87±5.77	24.40±6.38	F=0.081	0.971
MP-SN (°)	34.30±6.23	34.46±8.36	35.44±5.99	35.33±6.96	F=0.666	0.573
Males	Age Groups (Mean ± SD)				Statistics	P value
	[25–34] y (n=67)	[35–44] y (n=90)	[45–54] y (n=69)	[≥55] y (n=57)
ANB (°)	3.96±2.04	4.08±2.71	4.16±2.11	3.98±2.52	χ2=1.184	0.757
MP-FH (°)	21.71±6.96	21.97±7.56	22.88±6.53	21.76±6.46	χ2=1.198	0.753
MP-SN (°)	29.86±6.31	30.31±8.14	31.90±6.11	30.91±6.46	F=1.127	0.339

Notes: Compared by ANOVA or Kruskal–Wallis analysis according to normality test results.

Abbreviations: ANB, the angle formed by the points A, N and B; MP, mandibular plane; FH, Frankfort plane; SN plane, the anterior cranial base plane.

Table 2 shows the differences in upper airway morphology for different age groups in men and women, respectively. Among four reproductive stages of women, significant differences were found in UV, Amin, UL and MPH. In the four age groups of males, there were significant differences in Amin, UL and MPH, while there were no significant differences in UV.

Table 2

Comparison of Upper Airway Morphology Between Age Groups in Females and Males

	Age Groups (Mean ± SD)				F	P value	P value of Age Groups Compared
	25–34 (y)	35–44 (y)	45–54 (y)	≥55 (y)			25–34 to 35–44 (y)	25–34 to 45–54 (y)	25–34 to ≥55 (y)	35–44 to 45–54 (y)	35–44 to ≥55 (y)	45–54 to ≥55 (y)
Females
UV (mm3)	29,041.3±7665.6	26,895.6±8995.8	23,722.9±6995.7	23,312.5±7468.1	11.90	0.000**	0.071	0.000**	0.000**	0.014*	0.005**	0.716
Amin (mm2)	243.6±100.1	215.6±108.4	178.6±94.6	159.9±87.2	14.44	0.000**	0.061	0.000**	0.000**	0.022*	0.000**	0.188
UL (mm)	70.7±5.3	71.1±5.7	73.1±4.9	73.4±6.5	5.31	0.001**	0.641	0.002**	0.002**	0.022*	0.016*	0.724
MPH (mm)	8.4±4.8	9.5±4.7	9.4±4.8	12.2±5.9	9.52	0.000**	0.128	0.167	0.000**	0.944	0.001**	0.001**
Males
UV (mm3)	33,262.9±9525.2	30,375.5±8930.2	29,760.4±10,726.8	31,270.7±8623.8	1.80	0.147	–	–	–	–	–	–
Amin (mm2)	269.9±125.7	217.7±111.8	209.3±140.1	215.2±109.9	3.58	0.014*	0.007**	0.009**	0.012*	0.674	0.893	0.796
UL (mm)	79.3±4.94	81.7±6.6	82.6±6.9	83.1±5.6	4.90	0.002**	0.014*	0.002**	0.000**	0.422	0.177	0.615
MPH (mm)	13.0±5.6	14.5±5.7	16.5±5.5	16.7±5.4	6.43	0.000**	0.09	0.000**	0.000**	0.034*	0.024*	0.820

Notes: Compared by independent samples t-test. *Indicates statistical significance (P< 0.05), **Indicates statistical significance (P< 0.01).

Abbreviations: UV, upper airway volume; UL, upper airway length; Amin, minimum cross-sectional area of upper airway between PNS and EV; MPH, distance between H and MP plane.

As the differences in upper airway morphology between the two adjacent age groups are more clinically significant, in Table 3 we further studied the absolute differences and 95% confidence intervals for each measurement between the three adjacent groups, 25–34 years versus 35–44 years, 35–44 years versus 45–55 years, and 45–55 years versus ≥55 years. In Figure 3, we showed the aging changes of upper airway morphology and hyoid position in males and females, respectively. In combination with Tables 2 and 3 and Figure 3, we found that upper airway morphology changed differently in men and women at different ages:

Table 3

Changes of Upper Airway Morphology Between Adjacent Age Groups

	Mean Change (95 CI%)
	[25–34] – [35–44] y	[35–44] – [45–54] y	[45–54] – [≥55] y
Upper airway volume (mm3)
Females	2145.71(−183.13, 4474.54)	3172.91(653.86, 5691.96)	410.17(−1813.31, 2633.65)
Males	2887.38(−41.33, 5816.10)	615.09(−2466.15, 3696.33)	−1510.28(−4993.76, 1973.20)
Minimum cross-sectional area of upper airway (mm2)a
Females	27.98(−1.27, 57.24)	37.08(5.36, 68.80)	18.61(−9.18, 46.41)
Males	52.16(14.59, 89.74)	8.43(−31.02, 47.87)	−5.90(−51.00, 39.21)
Upper airway length (mm)
Females	−0.37(−1.91, 1.18)	−1.96(−3.62, −0.29)	−0.32(−2.11, 1.47)
Males	−2.39(−4.29, −0.50)	−0.86(−2.99, 1.26)	−0.57(−2.82, 1.67)
Distance between H and MP plane (mm)
Females	−1.04(−2.38, 0.30)	0.05(−1.42, 1.53)	−2.74(−4.42, −1.07)
Males	−1.55(−3.34, 0.24)	−1.92(−3.69, −0.15)	−0.22(−2.16, 1.71)

Notes: Comparing the mean change between adjacent age groups by independent samples t-test and representing the absolute change with 95% CI. aMinimum cross-sectional area of upper airway is an area between PNS and EV.

Abbreviations: CI, confidence interval of the difference; MP plane, mandibular plane.

Figure 3

Upper airway morphology and hyoid position change between age groups in males and females.

Reproductive Years and Upper Airway Morphology

When comparing females aged 25–34 and 35–44 years, no differences were found in UV, Amin, UL, and MPH. While among males, Amin was significantly smaller (52.16mm2, 95% CI=14.59–89.74) in 35–44 years old than in the 25–34 years old group and UL was significantly larger (−2.39mm, 95% CI=−4.29 to −0.50) than in the 25–34 years old group.

Perimenopausal Years and Upper Airway Morphology

Compared to 35–44 years, men aged 45–54 years did not show significant changes in UV, Amin, and UL, but MPH increased (−1.92mm, 95% CI=−3.69 to −0.15). However, unlike men, women aged 45–54 years showed a decrease in UV (3172.91mm3, 95% CI=653.86–5691.96) and Amin (37.08mm2, 95% CI=5.36–68.80) compared to 35–44 years, and UL increases (−1.96mm, 95% CI=−3.62 to −0.29). Besides, gender differences in UV, Amin, and MPH appeared to be increasing in perimenopausal women compared to men of the same age in Figure 3.

Postmenopausal Years and Upper Airway Morphology

In the age of ≥55 years, men did not show significant changes in upper airway morphology compared to 45–54 years. Although women showed a similar trend in upper airway morphology, the hyoid bone position was significantly lower (−2.74mm, 95% CI=−4.42 to −1.07) after menopause, while no significant difference was seen in the hyoid bone position in reproductive and perimenopausal years. In addition, gender differences in UV and UL seem to be greater, while decrease in MPH in postmenopausal years in Figure 3.

Discussion

The aim of this retrospective cross-sectional study was to explore whether there is a difference in upper airway morphology in perimenopausal and postmenopausal women compared to reproductive years. After careful matching of craniofacial morphological characteristics, there were two main findings from our study: 1) Compared to women of reproductive age, perimenopausal women experienced significant changes in upper airway morphology, including a significant reduction in upper airway volume, an increase in upper airway length and a reduced upper airway cross-sectional area; 2) In postmenopausal years, hyoid position was significantly lower than either age group, while no similar changes were seen in men.

Several studies have demonstrated that sex hormones have a profound protective effect on upper airway patency during reproductive years.14–16 Progesterone has a respiratory stimulatory effect. It is commonly believed that women have enhanced ventilatory drive during the luteal phase of the menstrual cycle and pregnancy due to increased progesterone levels.17,21 Another sex hormone called estrogen can also increase respiratory excitatory effects by upregulating progesterone receptors.27 Therefore, the decline in estrogen and progesterone after menopause can compromise upper airway ventilation.28 Studies have shown that postmenopausal women have decreased ventilatory responsiveness to hypercapnia.29 In addition, estrogen deficiency is associated with systemic changes in fat distribution. With lower estrogen after menopause, fat is more likely to be distributed in the upper body and trunk area,20 which may increase fat deposition around the upper airway and do harm to the upper airway morphology.

In our findings, postmenopausal women showed a decrease in hyoid bone position, which may also be associated with the decline in sex hormones. Progesterone increases the activity of the upper airway dilator muscles. Studies have suggested that progesterone improves strength and reduces fatigue of genioglossus muscle,27,30 while hormone replacement therapy increases genioglossus muscle activity significantly.21

Age-induced changes in upper airway morphology may also contribute to changes in airway morphology after menopause, which affecting our judgement of the effect of menopause itself on changes in airway morphology. In this study, we screened men of the same age group as sex controls. Men and women inherently have morphological differences in upper airway due to physique factors.18,31 For example, airway dimensions were normally larger in males than those in females, and healthy men had a larger upper airway cross-sectional area than women while awake and seated.32–34 And the length of upper airway was also found to be higher in males than in females.18,35 Comparing gender differences alone would bias the results. Therefore, we only compared the age-related changing trends in upper airway morphology and hyoid position separately by gender. As men of the same age did not show same changes in this study, we can speculate that these differences were due to menopause itself rather than to aging in females.

The present study contains both limitations and strengths. The limitations are primarily due to retrospective study which have posed difficulties for deep analysis. Because of the lack of information on other possible influences on upper airway morphology such as BMI in the sample population, the results are potentially biased. However, the sample size of this study was large and patients in dental hospital rarely have serious systemic diseases compared to general hospitals, so the findings of this study might reflect a population trend and provide evidence on the effects of menopause on upper airway morphology.

Smaller airway volume, reduced upper airway cross-sectional area, longer airway length and lower hyoid position are all associated with increased upper airway collapsibility.36–40 Hypoventilation of the upper airway contributes to an increased incidence of obstructive sleep apnea (OSA).41–44 Studies have found that the prevalence of OSA doubles in females after menopause independently of age and BMI, which was associated with changes in hormone levels.45–47 Future subgroup analyses based on accurate hormone levels, BMI, sleep breathing events and other factors are still needed to further elucidate the effect of hormone levels on upper airway morphology and their association with the occurrence of sleep breathing events in perimenopausal and postmenopausal women.

Conclusion

In summary, our findings suggested that women had smaller airway volume, reduced upper airway cross-sectional area and longer airway length in perimenopausal years, and a significantly lower hyoid position in postmenopausal years. These changes may be related to menopause itself and independent of the changes associated with aging under the male as background.