Computed tomography of the temporal bones in children with developmental anomalies of the external and middle ear]

Computed polypositional high-resolution tomography (CT) was provided to 45 children with dysplasia of the external acoustic meatus (EAM). The computed tomograms were analyzed in accordance with the scheme which included the evaluation of the following structures: atresia or stenosis area, pneumatized mastoid process, tympanic cavity, ant rum, osteal opening of the Eustachian tube, chain of auditory ossicles, windows of the labyrinth, internal ear, facial nerve canal, and large vessels. Preoperative CT of the temporal bones allows for the evaluation of the above-listed structures, which is of paramount importance for the planning of the patient management policy. Also, CT enables the assessment of the risk of surgical intervention associated with a potential injury to the facial nerve, large vessels, and temporomandibular articulation. CT is to be an indispensable diagnostic modality for examination of children presenting with EAM dysplasia.     

Mechanisms of sound reception and conduction in the dolphin

Morphology of the dolphin’s lower jaw, model and behavioral experiments are discussed with the aim of exploring the mechanisms of sound reception and conduction to the lower jaw canals, taking into account the known concepts of acoustics and the theory of grouped antennas. It is shown that the left and right rows of mental foramens with the respective mandibular canal and tissues of the canals are forming the new external ear and the new external auditory duct whereby sound (in the frequency band of 0.1–160 kHz) is transmitted into the middle ear, in contrast to the dolphin’s nonfunctional outer ear. This new external ear is created by nature as a receiving array of traveling-wave antennas located in the throat of an acoustic horn (the respective mandibular canal). The results give reason to assume the existence of a similar new external ear in Odontoceti.     

Correction of low-set ear: superoposterior mobilization of the ear as a transposition flap pivoted on the ear canal with burring of the superoposterior canal wall

In a number of congenital, developmental, and postoperative conditions, many patients have a difference in the vertical and anteroposterior position of the ears. On correction of this deformity, the most difficult problem is the low and anterior location of the external auditory canal. To overcome this unyielding limitation, the authors perform superoposterior transposition of the low-set ear pivoted on the ear canal after making a new path for the canal by burring of the thick superoposterior canal wall. A mastoid hairline incision is followed by three-quarters circumferential subpericranial dissection around the bony ear canal posteriorly. A preauricular incision is followed by subcutaneous dissection anteriorly. By using the natural deformability of the cartilaginous ear canal, the S-shaped canal can be straightened through a new path made by burring of the thick superoposterior wall. Then the low-set ear can be mobilized superoposteriorly as a transposition flap pivoted on the ear canal with minimal tension by straightening of the canal. The corrected auricular position can be maintained by (1) several permanent sutures between the cavum conchae and the mastoid and deep temporal fascia, (2) a suspensory temporoparietal fascial loop, and (3) a skin support provided by the repair in an elevated position and V-Y-plasty or Z-plasty on the lower pole of the ear. From December of 1997 to October of 1998, three cases with a maximum follow-up of 15 months were examined. Symmetric ear position was achieved and maintained on both frontal and lateral views after the operation in all cases. This new technique for correction of low-set ear produces symmetric ear position in both vertical and anteroposterior dimensions for a long time. In addition, it can be performed with various other surgical procedures safely and simultaneously in a variety of pathologic conditions.     

Radiological evidence of Goldenhar syndrome in a paleopathological case from a South German ossuary

We investigated the skull of a juvenile living in Southern Germany between 1400 and 1800 A.D. A remarkable hemifacial microsomia led to further detailed computed tomographic examination especially of the petrous bone revealing a total bony atresia of the external auditory canal as well as distinct anomalies of the middle ear on the same side. The combination of these findings strongly suggests the diagnosis of Goldenhar syndrome. This very heterogeneous syndrome affects primarily aural, ocular, oral and mandibular development, whereby the constellation of anomalies indicate their origin at approximately 30-45 days of gestation, caused by genetic or intrauterine factors. Despite the lack of clinical information and the absence of soft tissue it was possible to perform a differential diagnosis in this palaeopathological case. Thereby, the use of modern modalities of image reconstructions in this computed tomographic clearly enhanced the supposed diagnosis.     

Directional hearing in the barn owl (Tyto alba)

Summary The acoustical properties of the external ear of the barn owl (Tyto alba) were studied by measuring sound pressure in the ear canal and outer ear cavity. Under normal conditions, pressure amplification by the external ear reaches about 20 dB between 3–9 kHz but decreases sharply above 10 kHz. The acoustic gain curve of the outer ear cavity alone is close to that of a finite-length exponential horn between 1.2–13 kHz with maximum gain reaching 20 dB between 5–9 kHz. Pressure gain by the facial ruff produces a maximum of 12 dB between 5–8 kHz and decreases rapidly above 9 kHz.The directional sensitivity of the external ear was obtained from pressure measurements in the ear canal. Directivity of the major lobe is explained, to a first approximation, by the sound diffraction properties of a circular aperture. Aperture size is based on the average radius (30 mm) of the open face of the ruff. Above 5 kHz, the external ear becomes highly directional and there is a 26° disparity in elevation between the acoustic axis of the left and right ear. In azimuth, directivity patterns are relocated closer to the midline as frequency increases and the acoustic axis moves at a rate of 20°/octave between 2–13 kHz. Movement of the axis can be explained, to a first approximation, by the acoustical diffraction properties of an obliquely truncated horn, due to the asymmetrical shape of the outer ear cavity.The directional sensitivity of the barn owl ear was studied by recording cochlear microphonic (CM) potentials from the round window membrane. Between 3–9 kHz, CM directivity patterns are clearly different to the directivity patterns of the external ear; CM directionality is abruptly lost above 10 kHz. Above 5 kHz, CM directivity patterns are characterized by an elongated major lobe containing the CM axis, forming a tilted band of high amplitude but low directionality (CM axial plane), closely bordered by minima or nulls. The highest directionality is found in theCM directional plane, approximately perpendicular to the CM axial plane. The left and right ear axial planes are symmetrical about the interaural midline (tilted 12° to the right of the midline of the head) and inclined by an average of 60° to the left and right respectively. In azimuth, the CM axis moves towards the midline at a rate of 37°/octave as frequency increases from 2–9 kHz, crossing into contralateral space near 7 kHz. In the CM directional plane, the directivity of the major lobe suggests that a pressure gradient may occur at the TM. The region of frontal space mapped by movement of the CM axis in azimuth closely matches the angle of sound incidence which would be expected to produce the maximum driving pressure at the TM. It is suggested that acoustical interference at the TM results from sound transmission through the interaural canal and therefore the ear is inherently directional. It is proposed that ear directionality in the barn owl may be explained by the combined effect of sound diffraction by the outer ear cavity and a pressure gradient at the TM.Abbreviations CM cochlear microphonic - RMS root mean square - SPL sound pressure level - TM tympanic membrane     

先天性小耳畸形危险因素研究进展

先天性小耳畸形即小耳症,主要指耳廓、外耳道的畸形、听力损害等,少数患者合并外耳道闭锁、中耳及面部畸形。尽管先天性小耳畸形的发病机制尚未完全明确,但已有研究证实其发生可能与环境和遗传因素有关。因此,对于相关流行病学调查的相关因素与风险因素的研究与规避,并以此指导开展针对性防治工作显得尤为重要。本文将从流行病学特征及相关危险因素两个方面对于病因学进行探讨与总结。     

Mammalian ear specializations in arid habitats: structural and functional evidence from sand cat (Felis margarita)

To test whether structural specializations of sand-cat ears are adaptations to their desert habitats we measured structural and acoustic features of their ears. The area of the external ear's pinna flange is similar to that of domestic cat. The dimensions of the ear canal are about twice domestic cat's, as is the volume of the middle-ear air space. The magnitude of the acoustic input-admittance at the tympanic membrane is about five times larger than that of domestic cat; both the middle-ear cavities and the ossicular chain contribute to the increase. Structure-based models suggest the acoustic admittance looking outward through the external ear is generally larger for sand cat than for domestic cat; the radiation power-efficiency is also larger in sand cat for frequencies below 2 kHz. Hearing sensitivity (estimated from measurements and model calculations) in sand cat is predicted to be about 8 dB greater than in domestic cat for frequencies below 2 kHz. Analysis of attenuation of sound in deserts implies that the increased sensitivity extends sand cat's hearing range beyond domestic cat by 0.4 km at 0.5 kHz. Thus, the structural specializations may provide habitat-specific survival value.     

Temporal bone CT in the diagnosis of acquired diseases of the external auditory canal

CT was used to examine 50 patients (100 temporal bones) aged 10 days to 60 years who had no signs of lesion of the external auditory canal (EAC) and 23 patients (27 temporal bones) aged 13 to 65 years who had clinical manifestations of acquired stenosis or obturation of the EAC. Polypositional CT of the temporal bone is the most informative technique of visualization of the osseous part of the EAC, at the same time the anterior and posterior EAC walls were evaluated in the axial projection and the upper and lower EAC walls were assessed in the coronary projection. According to CT data, formation of the osseous part of the EAC occurs within the first 7 years of a child's life. In the presence of EAC changes, CT may assess their pattern (a soft tissue or osseous one), their magnitude and location along the walls of the canal, the tympanic membrane, and other structures of the temporal bone. CT reveals the causes of acquired EAC obturation, stenosis, and atresia: osteocartilaginous exostoses, osteomas, polyps of the EAC, tumors of the temporal bone, as well as obturative keratosis and posttraumatic stenosis of the EAC. The detected EAC changes determine further management policy in a patient.     

Balanced auricular reconstruction in dystopic microtia with the presence of the external auditory canal

This article presents a new repositioning method in dystopic microtia (low-set microtia, anteriorly tilted microtia, or both) with the presence of the external auditory canal. In the case of low-set malformations, the dystopic auricular canal complex was freed from adjacent bony structure, shifted upward, and anchored to the thick periosteum of the suprameatal triangle or the adjacent superior portion of the temporal bone with nonabsorbable sutures. When the auricular vestige was large and dystopia was severe, the complex was shifted with attachment of the temporoparietal fascia on its cranial part. Meanwhile, when the auricular vestige was small and dystopia was mild, the complex was shifted without attachment of the temporoparietal fascia. Then, the ear framework fabricated with autogenous costal cartilage was positioned and wrapped with the temporoparietal fascial flap. In the case of anteriorly tilted malformations, the dystopic complex was freed, shifted posteriorly, and anchored to the periosteum of the suprameatal triangle. Preauricular dead space, resulting from shifting the complex, was obliterated with pieces of costal cartilage. Simultaneously, the ear framework was placed and wrapped with the temporoparietal fascial flap. No skin necrosis of the shifted complexes occurred in any of the cases. In one case, the facial nerve was transected during dissection and reanastomosed. Upward repositioning distances in low-set microtias were between 1 and 3.5 cm. Posteriorly repositioning distances in anteriorly tilted microtias were 2 and 3 cm. Thirteen patients with low-set malformations, two patients with anteriorly tilted malformations, and three patients with low-set and anteriorly tilted malformations underwent reconstructive operations. The new repositioning method is relatively simple, safe, and effective.     

An infestation of the mite Sancassania berlesei (Acari: Acaridae) in the external auditory canal of a Korean man

We here report the case of a storage mite, Sancassania berlesei, infestation in the external auditory canal of a 46-yr-old male. He complained of feeling a foreign body and itching in the left external auditory canal for 1 mo, with accompanying otalgia for 3 days. Considering the duration of the patient's complaint and the 8-9-day life cycle of the mite, the mites are believed to have lived in the patient's ear for more than 3 generations.     

Computerized x-ray tomography of fossil hominid skulls

The newest generation of Computerized Tomography (CT) scanning appears to provide x-ray pictures of the internal structures of a rather heavily mineralized Homo erectus skull, i.e., Pithecanthropus IV, notably of its temporal bones, that reveal more details than traditional x-ray procedures. An analysis of the right temporal bone shows that it is extremely pneumatized, that the oval shape of the external meatus does not result from fractures as previously suggested, and that the middle ear and the internal auditory meatus have probably been damaged during restoration. Labyrinthine structures can be seen, and the facial nerve canal appears to be of a relative small size.     

A method for repositioning the external ear

The malposition of an otherwise normal-appearing external ear is not uncommon in certain craniofacial syndromes. This paper presents a 10-year experience of 14 patients who underwent external ear repositioning. In this technique, a posterior incision is used to mobilize surrounding soft tissues circumferentially around the external auditory canal, which then serves as an axis for anterior rotation and elevation. Elevation of up to 8 mm and rotation up to 30 degrees can be achieved. Further elevation is limited by the ensuing constriction and resistance of the external auditory canal. More rotation can be achieved with a Z-plasty transposition of an inferiorly based postauricular skin flap.     

菱臼齿兽((犭亚)目、哺乳纲)耳区的骨骼结构

本文详细描述了菱臼齿兽耳区各个部分的基本结构;并指出了耳区结构与某些啮齿类的相似性,以及中耳鼓泡组成成份与戈壁(犭亚)兽(Anagale gobiensis)的区别。     

Middle-ear dynamics before and after ossicular replacement

The mechanism of hearing involves conduction of mechanical vibrations along the ossicular chain to the inner ear. An acoustic wave is collected and transformed as it passes down the ear canal and impacts on the tympanic membrane (ear drum). The drum is connected to the inner-ear by three ossicle bones (malleus, incus, and stapes) in a complex arrangement, which serves to further transform the mechanical vibration before it reaches the cochlea of the inner ear. What is the mechanical function of the ossicular chain, and what are the biomechanical consequences of surgical reconstruction with prostheses? To answer these questions, a three-dimensional finite element model of the outer ear canal and middle ear was generated. The dynamical behaviour was predicted for the normal ear, and an ear reconstructed with partial and total ossicular replacement prostheses. For the normal ear, stapes amplitudes of 1x10(-8) m at low frequencies decrease to 4x10(-10)m at approximately 3kHz with several resonance peeks in between, most significantly at approximately 1kHz. Thereafter a further resonance is predicted at 4kHz associated with the ear canal. The behaviour is changed fundamentally by adding a prosthesis; the partial replacement increases the vibratory coupling of the drum and the stapes compared to the normal ear whereas the total replacement does the opposite, and is predicted to have the disadvantage of bringing several new resonances of the ossicular chain into the hearing range. It is hypothesised that the function of the malleus-incus-stapes arrangement is to link the drum to the oval window with the flexibility required for impedance matching but the rigidity to prevent unconstrainable resonances from occurring in the hearing range. If this is true, then the structural stiffness of ossicular chain is the critical design variable for middle-ear replacement prostheses.     

应用肱骨近端内锁定系统治疗高龄肱骨近端骨折

目的:探讨应用肱骨近端内锁定系统(PHILOS)治疗高龄肱骨近端骨折的方法及疗效。方法:2007年10月至2010年02月间,我院使用PHILOS内固定钢板治疗高龄肱骨近端骨折45例,男19例,女26例,年龄54～75岁,平均66岁。根据Neer分型,一部分骨折4例,二部分骨折6例,三部分骨折17例,四部分骨折18例。手术采用三角肌钝性劈开入路,保护附着于大骨折块和大、小结节上的软组织,骨折复位后均行PHILOS固定。患肩功能按Neer肩关节评分系统进行评价。结果:本组随访时间10～24个月,平均16个月。骨折均愈合,平均愈合时间3个月。患侧肩关节评分优28例,良12例,可3例,差2例,优良率为88.9%。结论:PHILOS钢板可牢固固定高龄患者骨折,使骨折愈合与功能恢复相同步,适于粉碎性骨折和肱骨近端骨质疏松骨折的治疗。     

Numerical simulation of wave propagation in a realistic model of the human external ear

In this study, a numerical investigation is performed to evaluate the effects of high-pressure sinusoidal and blast wave's propagation around and inside of a human external ear. A series of computed tomography images are used to reconstruct a realistic three-dimensional (3D) model of a human ear canal and the auricle. The airflow field is then computed by solving the governing differential equations in the time domain using a computational fluid dynamics software. An unsteady algorithm is used to obtain the high-pressure wave propagation throughout the ear canal which is validated against the available analytical and numerical data in literature. The effects of frequency, wave shape, and the auricle on pressure distribution are then evaluated and discussed. The results clearly indicate that the frequency plays a key role on pressure distribution within the ear canal. At 4 kHz frequency, the pressure magnitude is much more amplified within the ear canal than the frequencies of 2 and 6 kHz, for the incident wave angle of 90° investigated in this study, attributable to the ‘4-kHz notch’ in patients with noise-induced hearing loss. According to the results, the pressure distribution patterns at the ear canal are very similar for both sinusoidal pressure waveform with the frequency of 2 kHz and blast wave. The ratio of the peak pressure value at the eardrum to that at the canal entrance increases from about 8% to 30% as the peak pressure value of the blast wave increases from 5 to 100 kPa for the incident wave angle of 90° investigated in this study. Furthermore, incorporation of the auricle to the ear canal model is associated with centerline pressure magnitudes of about 50% and 7% more than those of the ear canal model without the auricle throughout the ear canal for sinusoidal and blast waves, respectively, without any significant effect on pressure distribution pattern along the ear canal for the incident wave angle of 90° investigated in this study.     

DGGE法分析慢性化脓性中耳炎耳道菌群变化及药敏试验研究

目的解析正常成人及慢性化脓性中耳炎（CSOM）患者耳道内菌群结构的差别,寻找有效抑制致病菌同时对皮肤主导菌群影响不大的抗生素,指导临床合理用药。方法取20例正常成人及20例CSOM患者耳道分泌物行血琼脂平板划线法分离鉴定细菌,选择典型病例进行DGGE法分析耳道菌群多样性,对培养的常见细菌进行药物敏感试验,分析药敏结果。结果（1）20例正常成人耳道分泌物中18例培养分离出表皮葡萄球菌（90％）,2例培养阴性（10％）;20例CSOM患者耳道分泌物中离出金黄色葡萄球菌8例（40％）,铜绿假单胞菌5例（25％）,溶血性葡萄球菌、表皮葡萄球菌各2例（各10％）,阴沟肠杆菌、洋葱伯克霍尔德菌各1例（各5％）,无菌生长1例（5％）。（2）DGGE分析显示,正常成人耳道菌群种类比CSOM明显增多。（3）金黄色葡萄球菌、表皮葡萄球菌、铜绿假单胞菌对环丙沙星均敏感。表皮葡萄球菌对阿莫西林、头孢唑林、左旋氧氟沙星耐药而金黄色葡萄球菌对其敏感。结论（1）正常人耳道正常菌群多样性高于CSOM。（2）目前培养出的正常成人主要耳道菌群为表皮葡萄球菌,CSOM主要菌群为金黄色葡萄球菌、铜绿假单胞菌。（3）环丙沙星同时抑制正常菌群和致病菌的生长。阿莫西林、头孢唑林、左旋氧氟沙星在抑制金黄色葡萄球菌等致病菌的同时,可以在一定程度上保护正常菌群成员表皮葡萄球菌。     

胶原生物膜在耳内镜下中耳胆脂瘤乳突根治术中的应用效果分析

摘要 目的：探讨胶原生物膜在耳内镜下乳突根治术中的应用效果。方法：选取徐州医科大学附属医院2021年4月至2022年 2月收治的51例中耳胆脂瘤患者进行回顾性分析,其中研究组27例患者予以胶原生物膜修复皮肤缺损,对照组予以颞肌筋膜修复术腔皮肤缺损,观察两组患者术后临床症状,手术时长,术腔完全上皮化时间、干耳时间及术前术后听力改变。结果：研究组术后患者因外耳道进水,存在感染及肉芽生长者1例,予以清理后未再次生长;对照组术后发生1例外耳道口狭窄的情况,予以橡胶扩张管进行扩张并后并定期清理术腔肉芽、脱落痂皮,患者外耳道恢复良好。两组术前耳闷、耳痛、耳鸣及术后耳痛VAS评分无明显差异（P>0.05）;研究组术后耳闷及耳鸣VAS评分较对照组降低（P<0.05）。研究组平均手术时长、术后术腔完全上皮化时间及平均干耳时间短于对照组（P<0.05）。两组术前术后气骨导差（ABG）、平均气导听阈（AC）比较差异均无统计学意义（P＞0.05）。结论：作为术区移植物,胶原生物膜应用于耳内镜下中耳胆脂瘤乳突根治术可加快创面术腔的修复,减少局部创伤与操作步骤,改善临床症状,缩短手术时间、术后术腔完全上皮化时间及获得干耳时间,可作为临床上有效的修复材料。     

Canal systems in the temporal bone and their right-left differences

The first part of the facial canal is the pars labyrinthica. Its means lateral length is in our material 2.63 mm on the right and 3.03 mm on the left side. The mean width of the pore on the fundus area was 1.3 mm on the right side and 1.07 mm on the left. The geniculate fossa had a mean length of 2.54 mm on the right and of 3.14 mm on the left side. The widths of different areas of the pars labyrinthica and fossa geniculata were also measured. The angle between the first and second parts of the Fallopian canal was estimated with different methods. The mean width of the tympanic part of the facial canal was found to be 1.79 mm on the right side and 1.67 mm on the left, the mean width of the mastoideal part was 1.8 mm on the right side and 1.7 mm on the left. Distances of the mastoideal part of the Fallopian canal to mastoideal cells, ear drum, sigmoid sinus and external surface of the temporal bone were also measured. Measurements of the sigmoid sinus, the bulb of internal jugular vein and the cavum musculi stapedii are included, too. The ranges found in our material are also given.