下载文档原格式
八年制教学大纲要求掌握的英文词汇艾滋病AAIDS Acquired immune deficie ncy syn dromeB半规管Semicircular canal 半面痉挛Hemifacial spasm贝尔氏面瘫Bell's palsy鼻瓣Nasal valve鼻阈Nasal threshold鼻咽静脉丛Nasophary ngeal venous plexus鼻侧切开术Lateral rhino tomy鼻出血Epistaxis 鼻的胚胎发育Embryology of n ose鼻囊肿Cyst of nose 鼻炎Rhi nitis萎缩性atropic鼻窦炎Paran asal sinu sitis并发症complicati on 眶内并发症orbital complicati on 颅内并发症in tracra nial complicati on鼻息肉n asal polyps 鼻真菌病Rhino mycosis鼻腔良性肿瘤Nasal cavity benign n eoplasm鼻腔恶性肿瘤Nasal cavity malig nant n eoplasm鼻窦粘液囊肿Paran asal sinu ses mucocele鼻骨骨折Nasal bone fractrue鼻和鼻窦外伤Nasal and sinuses trauma鼻疖Furuncle of nose 鼻内镜Nasal en doscope 鼻内镜外科Nasal en doscopic surgery 鼻外筛窦切除术External ethmoidectomy鼻前庭炎Nasal vestibulitis鼻腔持续正压通气Nasal con ti nu ous positive airway pressure 鼻测压法Rhinomano metry鼻前庭囊肿Nasal vestibular鼻小柱Nasal Columella鼻咽癌Nasophary ngeal carci noma 鼻咽纤维血管瘤Nasophary ngeal an giofibroma鼻咽纤维镜检查Fibro nasophary ngoscopy鼻异物Foreig n body of nose 鼻中隔成形术Septuplasty 鼻中隔穿孑L Perforati on of n asal septum鼻中隔Little 区Little ' area of nasal septum鼻粘膜纤毛输送系统Mucociliary tran sport system鼻阻力Nasal airway resista nee鼻周期n asal cycle扁桃体ton sil切除术ton sillectomy周围脓肿periton sillar abscess恶性肿瘤malig nant tumor of ton sil扁桃体炎To nsillitis病灶性focus变应性鼻炎Allergic rhi nitis变应性鼻窦炎Allergic sin usitis真菌性鼻窦炎Fun gal sin usitisC迟发性膜迷路积水Delayed membra nous labyri nthi ne hydrops 传导性聋Con ductive deafness锤骨Malleus垂体瘤Pituitary ade noma纯音听力测试Pure tone audiometryCarhart 切迹Carhart's notchD耵聍栓塞Cerume n胆脂瘤Cholesteatoma夕卜耳道exter nal acoustic meatus中耳炎otitis media胆固醇肉芽肿Cholesteatoma gran uloma镫骨Stap es镫骨切除术Stapedectomy导抗测听Acoustic immitta nee measureme nt短增量敏感指数试验Short in creme nt sen sitivity index test电反应测听Electric response audiometry蝶窦Sphe noid sinu ses蝶窦开放Sphe no idectomy窦口鼻道复合体Ostiomeatal complex多项睡眠描记Polyso mno gramE耳鼻喉科Otolary ngology额镜Head mirror腭咽成形术Palatophary ngoplasty耳的解剖An atomy of ear颞骨temporal bone外耳exter nal ear前庭vestibule耳蜗cochlea半规管semicircular canal蜗神经cochlea n erve耳道炎Otitis exter nal auditory canal先天性耳前痿管Congen ital preauricular fistula耳廓假性囊肿Pseudocyst of auricle耳硬化症Otosclerosis耳声发射Otoaustic emissio n 耳蜗电图Electrocochleogram 耳鸣Tinn itus 耳聋Deafness先天性congen ital感音神经性sen sori neural传导性con ductive遗传性gen etic噪声性no ise-i nduced老年性prebyacousis 感染性in fective自身免疫性autoim mune耳蜗植入Cochlea impla ntF分泌性中耳炎Secretory otitis mediaGGelle's 试验Gelle's test 鼓膜切开术Myrin ggotomy鼓室成形术Tympa no plastyH喉科学Laryn gology喉的软骨Laryn geal cartilage喉的韧带Laryn geal ligame nt喉肌Lary ngeal muscle喉弹性圆锥Elastic cone of lary nx喉间隙Lary ngeal space 喉癌Lary ngeal carc inoma喉恶性肿瘤Malig nant tumor of lary nx喉咽部恶性肿瘤Malig nant tumor of lary ngophary nx喉蹼Lary ngeal webs喉喘鸣Lary ngeal stridor喉痉挛Lary ngeal s pasm喉阻塞Laryn gealobstruct ion喉异物Foreig n body of lary nx喉炎Laryn gitis喉全切除术Total lary ngectomy喉部分切除术Partial lary ngectomy喉返神经麻痹Recurre nt laryn geal nerve paralysis喉感觉障碍Laryn geal paresthesia海绵窦血栓性静脉炎Thrombophlebitis of the cavernous后鼻孑L Choa nae, posterior n ares后鼻孔闭锁Choa nal atresia呼吸道异物Foreig n body of airway壶腹Ampulla 环甲膜切开术Con iotomy会厌软骨Epiglottic cartilage 急性会厌炎Acute epiglottitisJ急性喉气管支气管炎Acute lary ngotracheobro nchitis嵴顶结石症Can alithiasis甲状舌囊肿Thyroglossal Cyst颈淋巴结清扫术Neck dissecti on 颈外动脉结扌L术Ligati on of exter nal carotid artery颈静脉球体瘤Glomus jugular tumor 茎突Styloid process 颈部肿块Neck massesK客观测听法Objective audiometry口咽癌Orophary ngeal carci noma眶尖综合症Orbital apex syn dromeL颅底外科Surgery of skull-base螺旋器Spiral organM迷路炎Labyri nthitis 迷路痿管Labyri nth in e fistula迷路窗膜破裂membra nous ruptures of labyri nthine window 迷路切除术Labyri nthectomy面神经facial nerve 面瘫Facial nerve paralysis 面神经减压术Facial nerve decompressi on面神经畸形Facial nerve ano maliesN 脑脊液漏Cerebrospi nal leaks脑膜脑膨出En cephalome nin gocele内淋巴囊手术En dolymphatic sac surgery平衡试验Equilibrium test平稳跟踪试验smooth pursuit testQ 气管科学Bron chology气管镜tracheoscopy气管异物foreig n bodies of trachlea气管内插管En dotracheal in tubation气管切开术Tracheotomy前庭水管Vestibular aqueduct前庭生理Vestibular physiology前庭眼反射Vestibulo-ocular reflex 前庭性眼振Vestibular nystagmus前庭代偿Vestibular compe nsati on前庭习服Vestibular rehabilitati on前庭功能检查Vestibular fun ctio nal test前庭诱发电位Vestibular evoked pote ntial前庭性眩晕Vestibular vertigo前庭神经元炎Vestibular n euro nitis前庭神经切断术Vestibular n euroctomy桥小脑角Cerebellop on ti ne an gle球后视神经炎RetrobulbarR 任克间歇Rein ke's space孚L突根治术Radical mastoidectomy乳突炎Mastoiditis 隐蔽性MaskedS 鳃源性痿管及囊肿Bran chial fistula and cyst扫视试验Saccade test筛前神经An terior ethmoid nerve筛前动脉An terior ethmoid artery上颌窦囊肿Cyst of maxillary sinus上颌窦根治术Caldwell-Luc 'operation上颌动脉结扌L术Internal maxillary artery ligati on上颌窦穿刺Puncture of maxillary sinus声带息肉Polyp of vocal cord声带小结vocal no des声门上癌Supraglottic carci noma声门癌Glottic carci noma声门下癌Subglottic carc inoma神经电图检查Electro neurography神经兴奋性试验Nerve excitability食管科学Esophagology食管异物foreign body嗓音疾病Voice disorderT听骨链Ossicular cha in听觉皮层Auditory cortex 听觉反射通道Auditory central pathway听觉生理Physiology of audiology听功能Audiologic function纯音测听pure tone audiometry声导抗测听acoustic immita nee measureme nt电反应测听electric response audiometry耳声发射otoacoustic emissi on听神经瘤Acoustic n euroma吞咽困难DysphagiaW夕卜耳道闭锁Atresia of external acoustic meatus夕卜耳道胆脂瘤Cholesteatoma of exter nal acoustic meatus外耳道耵聍栓塞Impact cerumen外淋巴漏Perilymph fistula位置性试验Positio nal test位置性眩晕Positio nal vertigo蜗神经Cochlear nerve蜗后性聋Retrocochlear deafnessX眩晕外科治疗Surgical treatme nt of vertigo内淋巴囊手术en dolymphatic sac surgery 迷路切除术labyri nthectomy 旋转试验Rotation test吸气性呼吸困难In spiratory dysp nea先天性胆脂瘤Congeni tai cholesteatoma先天性耳前痿管Congen ital preauricular fistula纤维支气管镜Fibrobr on choscope纤维食道镜Fibrolary ngoscope显微喉镜Microlary ngoscope腺样体炎Aden oiditis腺样体切除术Ade noidectomy嗅神经Olfactory fun ctio nal test 嗅觉检查法Olfactory fun ctio nal test悬雍垂腭咽成形术Uvulopalatophary ngoplasty血管运动性鼻炎Vasomotor rhini tis习服疗法Retraining therapyY牙源性上颌窦炎odon toge nic maxillary sinu sitis卩因鼓管Phary ngotympa nic tube or Eustachia n tube卩因隐窝Phary ngeal recess咽炎Phary ngitis卩因旁间隙Paraphary ngeal space言语疾病Speech disorder岩部炎Petrositis岩尖综合征Orbital apex syndrome 眼震电图Eletr on ystagmograpy乙状窦血栓性静脉炎Sigmoid sin us thrombophlebitisZ砧骨In cus中鼻甲Middle turbi nate中鼻道Middle meatus助听器Heari ng aid姿势描记法Posturography 自描听力计测听法Bekesy audiometry 自发性眼震Spontan eous n ystagmus 自身免疫性内耳病Autoim mune inner ear disease 阻塞性睡眠呼吸暂停综合征Obstructive sleep apn ea-hypop nea syn drome 真菌病Mycosis 中耳炎Otitis media肉芽性granulo matous胆脂瘤cholesteatoma。
![固定剂量制剂[发明专利]](https://img.taocdn.com/s1/m/64cb0ccf0722192e4436f6c0.png)
专利名称:固定剂量制剂
专利类型:发明专利
发明人:默罕默德·阿卜杜纳赛尔,普拉蒂巴·S·皮尔冈卡尔,阿尼库马尔·甘德希
申请号:CN201880049937.4
申请日:20180525
公开号:CN110996914A
公开日:
20200410
专利内容由知识产权出版社提供
摘要:本文公开了包含Bempedoic酸以及Bempedoic酸和依折麦布的新组合物、试剂盒、使用方法和制备所述新组合物的方法。
尤其是,本文的制剂提供了对两种药品而言均具有优异的稳定性和释放特性的药物组合物。
这些改善的制剂可用于治疗和预防心血管疾病。
申请人:艾斯柏伦治疗公司
地址:美国密歇根州
国籍:US
代理机构:北京康信知识产权代理有限责任公司
代理人:李小爽
更多信息请下载全文后查看。
OMEGA’s new infrared sensor with wirelesstransmitter features a remote IR sensor and radio wireless transmitter in a NEMA enclosure. The miniature sensor head is ideal for measuring temperatures from -18 to 538°C (0 to 1000°F) in confined, hard-to-reach places and harshenvironments. The wireless transmitter is mounted in a NEMA 4 (IP65) plastic enclosure. When activated the unit will transmit readings continuously at pre-set time interval that was programmed by the user during the initial setup. Each unit measures and transmits: IR sensor reading, ambient temperature, RF signal strength and battery condition to the host and is displayed on the PC screen in real time using the provided software. Each unit includes free software that converts your PC into a strip chart recorder ordata logger so readings can be saved and later printed or exported to a spread sheet file.Operating TemperatureWireless Transmitter: -10 to 70°C (14 to 158°F)Sensor Head: 0 to 70°C (32 to 158°F)Sensor Head with OS100-WC (Water Cooling Jacket): 0 to 200°C (32 to 392°F)Operating Relative Humidity: Less than 95% RH, non-condensingWater Flow Rate (OS100-WC): 0.25 GPM, room temperature Thermal Shock: About 30 minutes for 25°C (77°F) abrupt ambient temperature change Warm-Up Period: 3 minutesAir Flow Rate (OS100-AP):1 CFM (0.5 L/s)Battery Life (Typ): 1.5 @ 1 sample/minute reading rate @ 25°C (77°F)Laser Sight Accessory (OS100-LS)Wavelength (Color): 630 to 670 nm (red)Operating Distance (Laser Dot): Up to 9.1 m (30')Max Output Optical Power: Less than 1 mW @ -6°C (22°F) ambient temperatureEuropean Classification: Class 2, EN60825-1/11.2001Specifications(See for complete specifications)Temperature Range: -18 to 538°C (0 to 1000°F)Accuracy @ 22°C (72°F) Ambient Temperature and Emissivity of 0.95 or Greater: ±2% rdg or 2.2°C (4°F), whichever is greaterOptical Field of View: 6:1 (distance/spot size)Sensor Head Cable: 1.8 m (6') standard; up to 15 m (50') total length capable Repeatability: ±1% rdgSpectral Response: 5 to 14 micronsResponse Time: 100 ms (0 to 63% of final value)Emissivity Range: 0.1 to 1.00, adjustableU -18 to 538°C (0 to 1000°F) Measurement Range U A djustable Emissivity from 0.10 to 1.0U F ree Software ConvertsYour PC Into a Multi- Channel Chart Recorder or Data Logger U L ow Power Operation and Sleep Mode For Long Battery Life U W eather Resistant NEMA 4X (IP65) EnclosureF C C /I n d u str y C a n a d a A p p r o v e dF o r A v ai l a b l e R e c e i v er s , S e e o me g a .c o mUWIR-2-NEMA shown smaller thanactual size.IR sensor head.W e a t h e rP r o o f /W al lM o u n t ed Non-Contact Infrared Temperature SensorWith Wireless Transmitter6:1 spot size ratioOS100-AP air purge collar to keep the lens free of particles or debris.Both shown smallerthan actual size.Maximum Operating Current: 45 mA @ 3 VdcFDA Classification: Complies with 21 CFR 1040.10, Class II laser product Beam Diameter: 5 mm (0.20")Beam Divergence: <2 mradOperating Temperature: 0 to 50°C (32 to 122°F)Operating Relative Humidity: Less than 95% RH, non-condensingbattery assembly.Ordering Examples: UWIR-2-NEMA, wireless infrared transmitter, UWTC-REC1, 48-channel USB receiver, UWTC-BATT-C, spare battery, and OS100-MB, sensor head bracket.UWIR-2-NEMA, wireless infrared transmitter, UWTC-REC2-D-MA, 48-channel transceiver/host with 1-channel 4 to 20 mA analog output, alarm and local display, UWTC-BATT-C, spare battery, and OS100-MB, sensor head bracket. OCW-3, OMEGACARE SM extends standard 1-yearwarranty to a total of 4 years.Power:(1.5 x 2")LASER RADIATION - DO NOT STARE INTO BEAM CAUTIONTYPE AND RULES PRINT BLACK 100%BACKGROUND YELLOW 100%Shown actual size.OS100-LS laser sight fits in front of the IR head for accurate positioning.。
<731>LOSS ON DRYINGThe procedure set forth in this chapter determines the amount of volatile matter of any kind that is driven off under the conditions specified.For substances appearing to contain water as the only volatile constituent, the procedure given in the chapter,Water Determination921,is appropriate,and is specified in the individual monograph.Mix and accurately weigh the substance to be tested,and,unless otherwise directed in the individual monograph,conduct the determination on1to 2g.If the test specimen is in the form of large crystals,reduce the particle size to about2mm by quickly crushing.Tare a glass-stoppered, shallow weighing bottle that has been dried for30minutes under the same conditions to be employed in the determination.Put the test specimen in the bottle,replace the cover,and accurately weigh the bottle and the contents.By gentle,sidewise shaking,distribute the test specimen as evenly as practicable to a depth of about5mm generally,and not more than10mm in the case of bulky materials.Place the loaded bottle in the drying chamber,removing the stopper and leaving it also in the chamber. Dry the test specimen at the temperature and for the time specified in the monograph.[NOTE—The temperature specified in the monograph is to be regarded as being within the range of±2of the stated figure.]Upon opening the chamber,close the bottle promptly,and allow it to come to room temperature in a desiccator before weighing.If the substance melts at a lower temperature than that specified for the determination of Loss on drying,maintain the bottle with its contents for1to2hours at a temperature5to10below the melting temperature, then dry at the specified temperature.Where the specimen under test is Capsules,use a portion of the mixed contents of not fewer than4capsules.Where the specimen under test is Tablets,use powder from not fewer than 4tablets ground to a fine powder.Where the individual monograph directs that loss on drying be determined by thermogravimetric analysis,a sensitive electrobalance is to be used.Where drying in vacuum over a desiccant is directed in the individual monograph,a vacuum desiccator or a vacuum drying pistol,or other suitable vacuum drying apparatus,is to be used.Where drying in a desiccator is specified,exercise particular care to ensure that the desiccant is kept fully effective by frequent replacement.Where drying in a capillary-stoppered bottle*in vacuum is directed in the individual monograph,use a bottle or tube fitted with a stopper having a225±25µm diameter capillary,and maintain the heating chamber at a pressure of5mm or less of mercury.At the end of the heating period, admit dry air to the heating chamber,remove the bottle,and with the capillary stopper still in place allow it to cool in a desiccator before weighing.本章中给出的方法阐述了在特定的条件下物质中的挥发性成分的测定。
开启片剂完整性的窗户日本东芝公司,剑桥大学摘要:由日本东芝公司和剑桥大学合作成立的公司向《医药技术》解释了FDA支持的技术如何在不损坏片剂的情况下测定其完整性。
太赫脉冲成像的一个应用是检查肠溶制剂的完整性,以确保它们在到达肠溶之前不会溶解。
关键词:片剂完整性,太赫脉冲成像。
能够检测片剂的结构完整性和化学成分而无需将它们打碎的一种技术,已经通过了概念验证阶段,正在进行法规申请。
由英国私募Teraview公司研发并且以太赫光(介于无线电波和光波之间)为基础。
该成像技术为配方研发和质量控制中的湿溶出试验提供了一个更好的选择。
该技术还可以缩短新产品的研发时间,并且根据厂商的情况,随时间推移甚至可能发展成为一个用于制药生产线的实时片剂检测系统。
TPI技术通过发射太赫射线绘制出片剂和涂层厚度的三维差异图谱,在有结构或化学变化时太赫射线被反射回。
反射脉冲的时间延迟累加成该片剂的三维图像。
该系统使用太赫发射极,采用一个机器臂捡起片剂并且使其通过太赫光束,用一个扫描仪收集反射光并且建成三维图像(见图)。
技术研发太赫技术发源于二十世纪九十年代中期13本东芝公司位于英国的东芝欧洲研究中心,该中心与剑桥大学的物理学系有着密切的联系。
日本东芝公司当时正在研究新一代的半导体,研究的副产品是发现了这些半导体实际上是太赫光非常好的发射源和检测器。
二十世纪九十年代后期,日本东芝公司授权研究小组寻求该技术可能的应用,包括成像和化学传感光谱学,并与葛兰素史克和辉瑞以及其它公司建立了关系,以探讨其在制药业的应用。
虽然早期的结果表明该技术有前景,但日本东芝公司却不愿深入研究下去,原因是此应用与日本东芝公司在消费电子行业的任何业务兴趣都没有交叉。
这一决定的结果是研究中心的首席执行官DonArnone和剑桥桥大学物理学系的教授Michael Pepper先生于2001年成立了Teraview公司一作为研究中心的子公司。
TPI imaga 2000是第一个商品化太赫成像系统,该系统经优化用于成品片剂及其核心完整性和性能的无破坏检测。
造纸专业常用英文缩略语(一)造纸专业常用英文缩略语A AA = atomic absorption原子吸收ABS = acrylonitrile-buladrene styrene丙烯腈—丁;烯—苯乙烯ACAR = angular correlation of annihilation radiation消除辐射的角相关性AM = acrylamide丙烯酰胺AOX = adsorbable organic halides可吸附的有机卤化物AP = plkali pulp 碱法纸浆APAM = anionic polyacrylamide阴离子型聚丙烯酰胺ASB = aerotion stabilization basin稳定曝气池AST = activated sludge treatment活性污泥处理B BCT = best convential pollutant cotrol technology最常用污染物控制技术BDMT = bone dry metric tons绝干公吨BME = bipolar membrane electro dialysis两极膜电透析BMP = best management practices最优管理实践BOD = biochemical oxygen demand生化耗氧量BP = boiling point沸点BPK = bleached papergrade kraft and soda(生产)白纸用硫酸盐和荷性纳法浆BPT = best practicable control technology最佳实用控制技术BTU = british thermal unit英热单位BW = basis weight定量C CAD = computer aided design计算机辅助设计CBLI = chemistry-based leak indicator化学(法)示漏器CC = consistency controller浓度调节器CFD = computational fluid dynamics计算流体动力学CI = colour index比色指数= cofidence interval置信区间CL = colored ledger彩色底板CLSM = confocal laser scanning microscopy共焦激光扫描显微镜CMC = carboxy methylated cellulose羧甲基纤维素COMS = compliance optimization modeling system寻优模型系统CP = chemical pulp化学浆 = chemical pure化学纯CPPC = coordinated phosphate/pH chemistry controller配位磷酸盐/pH调节器CR = consistency regulator浓度调节器CRP = chloride removal process氯化物排出法CSD = condensate steam distillation column冷凝汽馏塔CTMP = chemical treatment in terms of sulphonation硫化期间的化学处理= chemithermomechanical pulp化学热磨机械浆CTU = centigrade thermal unit公制热量单位CV = coefficient variation偏离系数 = crystal violet结晶紫D D = dioxide二氧化物DAF = dissolved air floatation(溶)气浮DCS = dissolved and colloidal substances溶解与胶态物 = distributed control system集散控制系统DELS = Doppler electrophoretic light scattering多普勒电泳光扫描DIP = deinked pulp 脱墨纸浆DKP = deinked kraft pulp脱墨牛皮纸浆DLK = double-line clippings双线限位DMS = dynamic mechanical spectroscopy动力谱学DMSO = dimethyl sulfoxide二甲亚砜DMT = dimethyl terephthalate对邻苯二甲酸二甲酯DO = dissolved oxygen溶解氧DP = degree of polymerization聚合度DSC = differential scanning calorimetry微分扫描量热法DVC = digital valve controller数字伐控制器E EC = embedded costs插入成本ECF = elemental chlorine free无元素氯(漂白) EDTA = ethylene eiamine tetraacetic acid乙二胺四乙酸EPC = experimental prismatic calcite实验棱镜方解石ERV = estimated replacement value预计取代值ESP = electrostatic precipitator静电滤尘器 = emergency shutdown procedure事故停机程序EVA = ethylene vinyl acetate乙烯乙酸乙烯酯ESPRA = empire state paper research associates国立造纸研究会EVOH = ethylene -vinyl alcohol乙烯-乙烯醇F FAS = formamidine sulfinic acid甲脒亚磺酸FBB = folding box board折叠箱纸板FBK = fully bleached kraft全漂牛皮纸FC = flow controller流量控制器FID = free induction decays自由感应衰减FP = freezing point冰点;凝固点G GDP = gross domestic product本国生产总值GEMS = general energy and materials balance system通用能量和物料平衡系统GLC = gas-liquid chromatography气液色谱GPC = gel permeation chromatographic analysis 凝胶渗透色谱分析GPM = gallons per minute加仑/分钟H HC = high consistency高浓HCR = high consistency refiner高浓磨浆机HD = high density高密度HPR = high production rate高生产率HPSEC = high-performance size-exclusion chromatography高性能粒度筛析色谱法HRT = hydraulic retention time水力停留时间HTH = high test hypochlorite高级漂粉HV = high voltage高压HW = hardwood 硬木I IMPM = interactive multiplanar model相互作用的多面模型IPST = institute of paper science and technology造纸科技研究院IWC = international water consultants国际水质顾问团J JIT = just-in-time正好;准时K KP = kraft pulp牛皮浆;硫酸盐浆L LC = level controller液面控制器LCC = lignin-carbohydrate complexes木素-碳水化合物复合体LCL = lower control limits控制下限LCR = level cotroller and recorder液面控制记录仪LDPE = low density poly ethylene低密度聚乙烯LDV = laser Doppler velocimetry激光多普勒测速法LIVG = low inlet velocity gasification process低入口速度气化工艺LPR = low production rate低生产率LRD = long rang dependence广范围相关LVDT = linear position transducer线性位移变送器LWC = lightweight coated低定量涂布的M MACT = maximum achievable control technology最大可达控制技术MAP = modified atmosphere packaging改良常压包装法MC = marginal cost 边际成本 = medium consistency中浓(度) MDI = methylendiphenyl diisocyanate亚甲苯二苯二异氰酸酯MeB = methylene blue亚甲基兰,四甲基兰MEK = methyl ethyl ketone甲(基)乙(基)酮MF = machine finished机械整饰的MG = machine glazed机械上光的 = malachte green孔雀绿MISS = mixed liquor suspended solids (有机物与活性污泥 )混合液中悬浮固体MOW = mixed office waste混合办公废纸MRP = matal removal process金属(离子)脱除过程MSW = municipal solid waste城市固体废物MVP = moisture vapor permeability水蒸汽渗透性MWL = milled wood lignin磨木木素N NC = nitrocellulose 硝化纤维素NF = nanofiltration超滤 (毫微过滤) NMR = nuclear magnetic resonance核磁共振NSPS = new source performance standards新的资源性能标准NSSC = neutral sulfite semi -chemical pulp中性亚硫酸半化学浆O OCC = old corrugated container旧瓦楞纸箱OD = over dry绝干;烘干OEE = overall equipment efficiency总设备效率OIT = oxidative induction temperature氧化起始温度O&M = operating and maintenance 使用与维护ONP = old newspaper旧新闻纸OPP = oriented polypropylene取向聚丙烯OPR = oil penetration rates渗油率OWL = oxidized white liquor氧化白液P PAL = positron annihilation life time正电子湮没寿命PC = pressure controller压力调节器PCA = principal components analysis 主成分分析PCC = precipitated calcium carbonate沉淀碳酸钙PCR = pressure controller and recorder压力调节记录仪PDSC = pressure differential scanning colorimetry压差扫描量热术PEMS = predictive emissions modeling system预测排放模型系统PEO = poly ethylene oxide 聚氧化乙烯PGS = papergrade sulfite造纸用硫磺PGW = pressurized groundwood压力磨木浆PM = paper machine 造纸机;抄纸机PM/ECCM = preventive maintenance and essential care and condition monitoring预防维修/基本维修及状态监测PP = polypropylene聚丙烯PSES = pretreatment standards for existing sources现存资源预测标准PSM = process safety management(生产)过程安全管理PTFE = polytetrafluoroethylene聚四氟乙烯PTR = photothermal radiometry光热辐射分析法PVC = polyvinylchloride聚氯乙烯PVDC = polyvinyl dichloride聚二氯乙烯PVSK = polyvinylsulfate聚乙烯硫酸酯R RDH = rapid displacement heating快速置换加热法RH = relative humidity相对湿度RMP = refiner mechanical pulp木片磨木浆;盘磨机械浆RN = regular number纸板标准号RT = radiographic testing射线照相试验,X射线检验S SBK = solid bleached kraft(同质)漂白牛皮纸SBR = sequencing batch reactors程序化间歇反应器SC = super calendered超级压光的SDI = silt density index淤泥浓度指数SE = supplemental energy补充能量;辅助能SEC = size exclusion chromatographic粒度筛析色谱法SEM = scanning electron microscope扫描电子显微镜SEM-EDS = scanning electron microscope-energy dispersive spectrometry扫描电子显微镜—能量分散能谱测定法SGW = stone ground wood磨石磨木浆SIF = stress intensity factor应力强度系数;应力强化因子SOPs = standard operating procedures标准作业程序SP = sulphite pulp亚硫酸盐纸浆SPC = satislical process control过程控制SRT = solids retention time粒子留着时间SUB = solid unbleached board(同质)本色浆纸板SW = softwood软木;针叶树SWL = sulphite waste liguor亚硫酸盐废液T TAC = totally applied chlorine总用氯量TC = temperature controller温度调节器TCDF = tetrachlorodibenzofuran四氯二苯并呋喃TCF = totally chlorine-free全无氯(漂白) TCR = temperature controller and recorder温度调节记录仪TGA = thermal gravimetric analysis热重分析TLA = thin layer activation薄层活性化TMP = thermo mechanical pulp热磨机械浆TP = thermo-plastic热塑性的TQ = threshold quantity临界量(值) TRS = total reduced sulfur总还原硫TS = tensile strength抗张强度TSS = total suspended solids总悬浮固体量U UBB = unbeached board本色(浆)纸板UBK = unbeached kraft本色牛皮纸UCL = upper control limits控制上限UT = ultrasonic testing 超声试验UV = ultraviolet紫外光V VOC = volatile organic compound挥发性有机化合物W WAS = waste-activated sludge废活性污泥WFMT = wet fluorescent magnetic particle test湿荧光磁粉试验WL = white ledger白色帐簿纸WLC = white-lined chipboard白浆衬里的粗纸板WP = wood pulp木浆WVTR = water vapor transmission rate水蒸汽传递速度Y YI = yellow index返黄值;返黄指数YP = yield point屈服(软化)点制浆中的中英文术语 造纸专业常用英文缩略语(二)半化学浆semi-chemical pulp用化学处理,例如蒸煮,从植树物纤维原料中部分地除去非纤维素成分而制得的纸浆,为了达到纤维分离需要进行随后的机械处理拌浆机breader,breaker beater装有(或不装)底刀并装有一个带钝刀辊子的碎浆机。
低聚糖阿魏酸酯对美拉德反应挥发性产物的影响姚胜文,赵倩竹,鲜傲霜,麦嘉琪,叶丽君,林之蕙,欧仕益(暨南大学食品科学与工程系,广东广州 510632)摘要:低聚糖阿魏酸酯(FOs)是一类新型功能性食品,美国食品药品监督管理局(US FDA)已允许将其在焙烤食品等多种食品中添加,但其对焙烤食品风味的影响未见报道。
本文采用顶空固相微萃取结合气相色谱-质谱联用技术(HS-SPME/GC-MS),研究了玉米皮低聚糖阿魏酸酯在葡萄糖分别与天冬氨酸、天冬酰胺、谷氨酸构成的3个美拉德反应模拟体系和面团焙烤模拟体系中对挥发性物质的影响。
结果表明,添加低聚糖阿魏酸酯(1%和5%)显著促进糠醛和不良风味物质对乙烯基愈疮木酚的形成,抑制吡嗪、麦芽酚、壬醛、雪松醇等焙烤特征性风味物质的形成;在焙烤面团中,添加低聚糖阿魏酸酯后还产生了二甲基二硫醚、二甲基三硫醚两种不良风味物质。
因此,FOs虽然被允许在焙烤食品中大量添加,但是考虑到其对风味具有潜在的不良影响,在应用时应谨慎。
关键词:低聚糖阿魏酸酯;美拉德反应;焙烤食品;风味物质;顶空固相微萃取文章篇号:1673-9078(2016)3-113-118 DOI: 10.13982/j.mfst.1673-9078.2016.3.019 Effect of Feruloylated Oligosaccharides on the Volatile Products ofMaillard ReactionYAO Sheng-wen, ZHAO Qian-zhu, XIAN Ao-shuang, MAI Jia-qi, YE Li-jun, LIN Zhi-hui, Ou Shi-yi (Department of Food Science and Engineering, Jinan University, Guangzhou 510632, China) Abstract: Feruloylated oligosaccharides (FOs) are a new type of functional foods and their addition to bakery products was approved by the Food and Drug Administration of the United States (US FDA) in 2010. However, there have been no reports on their influence on the flavor of bakery products. Here, headspace solid-phase micro-extraction coupled with gas chromatography mass spectrometry (HS-SPME/GC-MS) was used to investigate the effect of FOs prepared from maize bran on the formation of volatile compounds in three Maillard reaction models (glucose with aspartic acid, asparagine, or glutamic acid) and the baked dough model. The results showed that in all reaction models studied, the addition of FOs at 1% and 5% concentration significantly increased the formation of furfural and an unpleasant flavor compound (2-methoxy-4-vinyl-phenol), but suppressed the formation of several pleasant flavor-producing compounds such as pyrazines, maltol, nonanal, and cedrol. Moreover, the addition of FOs into the dough produced two unpleasant flavor-producing compounds (dimethyl disulfide and dimethyl trisulfide) after baking. Therefore, although FOs are allowed to be added in a large amount to bakery products, caution is advised due to the potentially undesirable effect on flavor.Key words: feruloylated oligosaccharides; Maillard reaction; bakery products; flavors; headspace–solid phase microextraction低聚糖阿魏酸酯(FOs)是一种阿魏酸与低聚糖通过酯键键合在一起的水溶性化合物,是一类兼具阿魏酸和低聚糖生理功能的的功能性食品配料。
Distortion Product Otoacoustic Emissions inacute acoustic traumaJens OekenHNO-Universitätsklinik, Leipzig, GermanyAcute acoustic traumas are caused by exposure to extremely high noise levels ranging from milliseconds to several hours' duration. In pure tone audiometry they range from the C5 dipto basomediocochlear sensorineural hearing loss. Their pathogenesis is assumed to consist of micromechanical-traumatic and biochemical-metabolic damage to the outer hair cells. In order to establish the changes to the DPOAE (distortion products of otoacoustic emissions), 17 patients were examined after sustaining acute acoustic trauma. The causes included firework explosions, anti-tank rocket launchers, vehicle tyre bursting, rock concerts, hand-gun shots,sub-machine gun fire, hand grenade explosion, exploding car battery. The pure tone audiogram, tympanogram, tinnitus maskability and DPOAE (both DP-gram and growth ratein various frequencies) were determined in all patients. If the event had occurred some time ago, measurements were taken only once; in acute cases measurements were repeated at different times. In nine patients with persistent hearing impairment, clear DPs were found inthe unaffected frequencies but were completely absent in the affected frequency range. Fourof these patients were unilaterally and two patients were bilaterally affected; three patientshad a different (not noise-induced) hearing loss on the opposite side. In eight patients with regressive hearing loss, DPs were by contrast detectable throughout the entire frequency range, their amplitudes only rising slightly as hearing recovered. Of these eight patients, threewere unilaterally and five bilaterally affected. DPOAE seem to indicate the likelihood of recovery of hearing threshold after an acute acoustic trauma. In cases with DPs completely absent in the affected frequency range, the prognosis seems to be much worse than in caseswith present DPs in the frequency range of hearing.Key words: acute acoustic trauma, distortion-product otoacoustic emissions (DPOAE), sensorineural hearing lossINTRODUCTION drawn between blast trauma syndrome Both chronic and acute noise exposure lead to (Knalltrauma), explosion trauma inner-ear damage, the scale of which depends on (Explosionstrauma) and acute noise traumathe duration and intensity of exposure. Acute (akutes Lärmtrauma) (Rüedi & Fuller, 1946; acoustic trauma is a generic term for various Lehnhardt, 1993; Ward, 1991), whereas in the types of noise-induced hearing loss caused by Anglo-Saxon speaking countries no furthervery short but extraordinarily intense noise differentiation is made. The various damage impacts (such as explosions or individual noxes involved are also discriminated gunshots), other causes include exposure to high accordingly: exposure to a volume exceeding noise levels for several hours (for instance 150 dB SPL for over 1.5 ms for instance leads to attending loud rock concerts). That is why in the 'explosion trauma', whereas if the duration of the German-speaking countries a distinction is pressure peak is shorter than 1.5 ms, we speak of'blast trauma' (Pilgram, 1994). Explosion trauma can also result in additional damage to the middle ear. By contrast, the term 'acute noise trauma' corresponds instead a temporary threshold shift (TTS), the cause of which is generally exposure to noise levels above 100 dBSPL for a number of hours (Lehnhardt, 1993). Sometimes it can also turn into a PTS (permanent threshold shift). Hearing losses as shown by the PTA are relatively uniform. Less serious cases show a C5 dip; basocochlear sensorineural hearing losses are encountered in serious cases; and additionally the mid frequencies may be affected in very serious cases (Dieroff, 1994; Lehnhardt, 1993; Ward, 1991). Audiometric tests comprise usually only puretone audiogram (PTA) and tinnitus measurement by masking; other methods have not yet proved successful. Thus the question of whether spontaneous recovery from acute acoustic trauma is likely can only be indirectly concluded from the degree of hearing loss and the course of the threshold over the first 72 hours. According to Pilgramm (1985), spontaneous recovery islikely if 24 hours after initial measurement hearing impairment does not exceed 40 dB HL or hearing has improved by 20 dB. However, as the lesion caused by acute noise chiefly occurs in the outer hair cells and in the high frequency range, it ought to be possible to derive additional information on hearing loss by measuring frequency-specific distortion products of OAE (DPOAE) (Avan & Bonfils, 1993). So far only results about chronic occupational noise-induced hearing loss have been published, which show that DPOAE provide valuable information about the frequency areas, where the outer hair cells, and therefore the cochlear amplifier, do not work(Oeken & Müller, 1995; Sliwinska & Sulkowski, 1996; Plinkert & de Maddalena 1997). DPOAE measurement might also allow conclusions on the etiology (i.e. micromechanical-traumatic or biochemical-metabolic damage to the outer hair cells) and hence the chances of spontaneous recovery. MATERIAL AND METHODS Patients Between 1995 and 1998, 17 patients wereexamined after acute acoustic trauma. 16patients were male, one female; their average age at the time of the event was 29 years (youngest 13 years, oldest 54 years); their average age upon examination was 32 years. Six patients suffering persistent hearing damage were examined a long time after the event; 11 patients were examined soon after intense noiseexposure.ExaminationEach patient underwent otorhinolaryngological examination, pure tone audiometry, tinnitus measurement with masking and DPOAE measurement. Furthermore, tympanometry was used to rule out middle-ear damage to the affected organs. A single measurement was taken in those patients who had experienced the event some time ago; those who had recently sufferedintense noise exposure were measured threetimes (on the day of registration in the clinic, some days later, and about one or two months after the second measurement). All patients who visited the clinic soon after the event underwent a therapy with vasoactive substances (i.v. infusion with pentoxifyllin). This is the same treatment which is used in cases of sudden deafness in Germany. The aim is to get a faster recovery. It is not known to have any direct interference with DPOAE. DPOAE measurementAll measurements were taken using the systemof the Institute of Laryngology and Otology, London (ILO 92). The 2f 1-f 2 Distortion Product was studied using the following parameters (Hauser & Probst, 1991; Nielsen et al., 1993):· Ratio of the primary tone frequencies f 1/f 2 = 1.22; stimulus level of the primary tones: L1 =70 dB SPL, L 2 = 65 dB SPL; definition of theDP-gram: 4 measuring points per octave; averaging was used until the 'noise floor' did not change any longer · Measurement of the growth rate: ratio of theprimary tone frequencies f 1/f 2 = 1.22; volume of the primary tones falling in 5 dB increments starting with L 1 = 70 dB SPL, L 2 = 65 dB SPL; 'noise floor' is defined as two standard deviations above the mean noise level in the region of the DP frequency.· The frequency of f 2 was matched to the PTA(Kummer et al., 1995).RESULTS Persistent cases In nine patients acute acoustic trauma had led to persistent hearing loss. Six patients were exposed to the noise impact more than a year ago, three patients were exposed only a few days previously. The latter were controlled for two months. Four patients had a unilateral hearing loss and normacusis on the opposite ear, three were unilaterally affected with different hearing impairment on the opposite ear, and two had a bilateral hearing loss.a) Unilateral hearing impairment with normacusis of the opposite ear The four cases of unilateral hearing loss were caused by a lorry tyre bursting, a car tyre bursting, a car battery exploding (Figure 1), and a firework explosion. In all cases, different degrees of high-frequency loss were established by audiometry. In two cases normacusis prevailed up to 3 kHz, afterwhich the threshold dropped to between 65 and 70 dB HL. In the other two cases, normacusisprevailed up to 1.5 kHz, while in the higherfrequency range the threshold dropped to 50-60dB HL. All patients suffered high-frequencytinnitus following the noise exposures. In three patients clear DPs were ascertained inthe DP-gram up to the frequency range in which persistent hearing loss started in the PTA. The amplitudes were in all cases well pronounced with a s/n-difference of 12-20 dB SPL. In one patient, DPs were detected throughout the entire frequency range despite persistent hearing loss. As was to be expected, clear DPs were detected across the whole frequency range in the unaffected ear (s/n-diff. 15-25 dB SPL).The DP-gram findings were largely confirmed by growth rate. In the frequency ranges in which DPs were clearly evident growth rates verifyingthe physiological nature of the DPs. In those frequencies in which the DP-gram showed no DPs no growth rate could be produced. In the special case with DPs despite a persisting hearing loss in the high frequency area the growth rate was very steep and more linear. The growth rate of the normal hearing contralateral ears was found to be typical in all frequencies. b) Unilateral hearing impairment with differing impairment of the opposite earThe causes were an anti-tank rocket launcher, sub-machine gunfire, and a pneumatic drill on metal. The opposite ear was affected in two cases by conductive hearing loss due to chronicmiddle-ear infection and in one case by deafness caused by previous sudden hearing loss. Audiometry established in the affected ear normacusis up to 1.5 kHz with subsequent threshold decline down to 100 dB HL at 3 kHz in the first case, normacusis up to 4 kHz withii1a1bD i st or t i on Pr oduct -gr amD i st or t i on Pr oduct -gr am2020dB s p l dB s p l Fig. 1 Unilateral persistent hearing loss in a 29-year-old patient following the explosion of acar battery about a month prior to measurement a) pure tone audiogram b) DP-gram threshold decline down to 70 dB HL at 6 kHz in the second case, and normacusis up to 1.5 kHz with threshold decline down to 60-70 dB HL as of 2 kHz in the third case. Tinnitus resulted in the affected ear in all three cases after intense noise exposure, which in one case (the patient with contralateral deafness dueto acute hearing loss) was combined with broadband noise in the opposite ear. In the DP-gram, DPs were clearly apparent in the damaged ear up to the frequency range at which persistent hearing loss started in the PTA. Theamplitudes were well pronounced with s/ndifferences from 10 to 25 dB SPL. DPs were naturally not found in the contralateral ears owing to previous illness. The growth rate findings largely corresponded tothose described under A), the difference beingthat the opposite ear could not be used for comparison. c) Bilateral hearing impairment The first case was caused by a hand grenadeexploding in the immediate vicinity (Fig. 2), thesecond was caused by an anti-tank rocket launcher going off. Audiometry established in the first case bilateral normacusis up to 3 kHz, after which the left earHi ( Hi2aD i st or t i on Pr oduct -gr am D i st or t i on Pr oduct -gr am20202bdB s p l dB s p l Fig. 2 Bilateral persistent hearing loss in a 28-year-old patient after the explosion of a handgrenade about five years prior to measurement suffered a hearing loss of up to 60 dB HL at 6 kHz. The second patient suffered asymmetrical hearing loss, comprising normacusis up to 3 kHz and then threshold drop to 50 and 90 dB HL on the right, and normacusis up to 1 kHz followed by steady threshold decline down to 80 dB HL at 6 kHz on the left.Both patients suffered persisting tinnitus: in the first case bilaterally as a high-frequency tone and in the second case as a unilateral high-frequency hiss in the worse affected ear. In the first case the DP-gram corresponded to the audiogram. DPs were apparent bilaterally up to f 2=3 kHz, whereas in the higher frequency range a) pure tone audiogram b) DP-gram there were no DPs. The amplitudes continuously dropped in the range of f 2=1.5 to f 2=3 kHz (s/ndiff. from 17 dB to 6 dB SPL). In the second case, no DPs could be measured on the right despite repeated measurement, while on the left only low-amplitude DPs were detected in the range of f 2=0.7 to f 2=1.5 (s/n-diff. of 5 dB SPL). In the frequency ranges in which DPs wereclearly detectable in the DP-gram, the growth rate exhibited typical characteristics, i.e. in the second case no growth rate could be measured on the right (despite normacusis up to 3 kHz).Hi Hi Hi Hi-10 3a0 10 20 30 40 50 60 8000400020001000500250125 Fr equency (H z)70 80 90 100 110 12020D i st or t i on Pr oductgr amD i st or t i on Pr oductgr am203bdB s p l dB s p l dB s p l dB s p l -10 0 3c10 20 30 40 50 60 8000400020001000500250125 Fr equency (H z)70 80 90 100 1101203dD i st ort i on Pr oduct -gr amD i st or t i on Pr oduct -gr am2020Fig. 3 Unilateral regressive hearing loss in a 25-year-old patient after the explosion of a fire cracker.a) Pure tone audiogram 3 days after the event b) DP-gram 3 days after the event c) Pure tone audiogram 10 days after the event d) DP-gram 10 days after the eventSummary - DPOAE in persistent hearing loss after acute noise trauma When the DPOAE of all 11 affected ears are taken into account we could find an expected result in 8 ears where we could measure clear DP-amplitudes (s/n-difference 10 until 25 dB SPL) in the unaffected and absent DPs in the noise-affected frequency area. Growth rates confirmed the findings of the DP-Gram, they showed the "non-linear" behaviour infrequencies of existing DPs. In three ears we found an atypical result, two ears showed no DPs at all in frequency areas of normacusis, one ear showed DPs over the whole frequency range though noise-induced hearing loss in the high frequencies. Regressive casesEight persons were found to be suffering regressive hearing loss - three unilateral and five bilateral. All patients were examined repeatedly shortly after the event until the complete recovery of the hearing. a) Unilateral hearing loss The causes were two times an exploding firecracker at New Year (Fig. 3) and a blank cartridge pistol firing. Initial audiometric measurement when the patients first reported to the clinic (i.e. a fewdays after the intense noise exposure) revealed in the first two cases normacusis up to 1.5 resp. 2 kHz followed by threshold decline down to 40 dB at 2 kHz, which decreased to 30 dB HL at 6 kHz in the first case and a threshold decline down to 50 dB at 4 kHz in the second case. The third case was characterised by a C5 dip of 35 dBHL.The three patients suffered from highfrequency tinnitus, which all described as a high whistle. Clear DPs over the whole frequency range were detected bilaterally in the DP-gram during initial measurement. The amplitudes on the impairedside were reduced in comparison to the opposite ear. The reduction seems to be related to the hearing loss. In both cases with the hearing loss of 30 to 40 dB HL the averaged difference of the DP-amplitudes between both ears in the affected frequency area was 2.2 resp. 8 dB SPL, in the case with hearing loss of 60 dB HL the difference was 18 dB SPL. The growth rate was found to be typical in all frequencies. Once normacusis was reached, the DP-gram indicated in the both cases with hearing loss of 30 to 40 dB HL a minor rise in DP amplitudes by 1.25 and 3 dB SPL (averaged in the affected frequency range). In the case of the 60 dB HL hearing loss the DP-amplitudes increased by16,1 dB SPL.The change in the growth rate was insignificant in the first two cases compared to initial measurement (point of dipping into the noise floor 5 dB SPL lower). In the third case there was a more obvious difference, the point ofdipping into the noise floor was 15 dB SPLlower. b) Bilateral hearing loss The causes in two cases were attending a rockconcert (Fig. 4) and in three cases a fire crackerexploding at New Year. In four cases audiometry revealed a bilateral C5 dip of 30 to 40 dB HL in the frequencies of 3 and 4 kHz. In the fifth case normacusis prevailed up to 4 kHz, followed by a threshold decline of 20 dB at 6 kHz and 50 dB HL at 8 kHz. All patients suffered from high-frequency tinnitus. Clear DPs were detectable in all cases throughout the entire frequency range. No difference between the two sides could beestablished due to the lack of a normally hearingreference ear caused by bilateral hearing impairment.Hi ( HiHi ( Hi4a-10 0 10 20 30 8000400020001000500250125 Fr equency (H z)40 50 60 70 80 90 100 110120D i st or t i on Pr oduct -gr amD i st or t i on Pr oduct -gr am20204bdB s p ldB s p l dB s p l -10 4c0 10 20 30 8000400020001000500250125 Fr equency (H z)40 50 60 70 80 90 100 110120D i st or t i on Pr oduct -gr am D i st or t i on Pr oduct -gr am20204dFig. 4 Bilateral regressive hearing in an 18 year-old patient after attending a rock concerta) Pure tone audiogram 2 days after the event b) DP-gram 2 days after the event c) Pure tone audiogram 10 days after the event d) DP-gram 10 days after the eventAfter reaching normacusis, a minor rise in the amplitudes was recorded on both sides (in the frequency area f2=3 to 4 kHz averaged increases of -0.33 to 7 dB SPL). In the growth rate, the point of dipping into the noise floor was found to be lower by about 15-20 dB in the principally affected frequencies of 3 and 4 kHz.Summary - DPOAE in regressive hearing loss after acute noise traumaSummarising all 13 affected ears the following features are common: DP-amplitudes are measurable over the whole frequency range. Only in three cases a comparison to a unaffected reference ear with normal hearing is possible. The averaged differences in the affected frequencies between the impaired and normal hearing ear were 2.2, 8 and 18 dB SPL. In 11 ears an increase of DP-amplitudes (averaged at the affected frequency area) could be demonstrated after hearing recovery (1.25, 1.43, 3.07, 3.2, 3.25, 5.5, 5.8, 7.12, 15.1 dB SPL). In two ears the amplitudes were nearly the same after recovery (-0.33, 0.15 dB SPL). Concerning the growth rate lower points of dipping into the noise floor could be measured. These were 3 times 5, 5 times 10, 4 times 15, once 20 dB SPL lower.DISCUSSIONThe pathogenesis of acute acoustic trauma is assumed to consist of mechanical-traumatic damage with micro-lacerations at the level of the basilar membrane and thus the direct destruction of sensory cells, as well as biochemicalmetabolic damage with the oedematous swelling of the hair cells (Alexander & Githler, 1951; Beck, 1955; Dieroff & Beck, 1964; Spoendlin, 1958 & 1971; Gogniashwili, 1972; Engström & Ades, 1960). Being able to identify what innerear lesions are involved in individual cases would be of considerable practical interest as this is critical for prognosis of the regression or persistence of hearing impairment. Measuring DPOAE could provide the solution. Although the measurement of DPOAE upon chronic noise-induced hearing loss has already been successfully used (Oeken & Müller, 1995; Sliwinska & Sulkowski, 1996; Plinkert & de Maddalena, 1997), there has so far been a lack of publications on DPOAE measurement after acute acoustic trauma. Despite an insufficient number for statistical evaluation, our measurements demonstrated that with nearly all persisting hearing impairment, the DPOAE had also disappeared in the frequency range of hearing loss. This indicated that the cochlear amplifier in this basilar membrane segment was no longer functioning, which in turn was probably attributable to the destruction of outer hair cells. The disappearance of DPOAE was found in both the DP-gram and the growth rate. Solely in cases in which the hearing loss is only fully pronounced in the 6 kHz range is the frequency specificity of DPOAE probably insufficient, with DPs being present despite persistent hearing impairment.Nevertheless, it can in principle be stated that the complete absence of DPOAE constitutes an unfavourable prognosis factor. Of special interest is not so much the correlation between the degree of hearing loss and the absence of DPOAE but rather ascertaining the breakdown of the function of the cochlear amplifier itself.By contrast, DPs are detectable throughout the entire frequency range in all regressive cases; there are no segments in which DPOAE are completely absent. During the process of recovery, DP amplitudes only increase slightly, to an extent which is inversely proportional to the hearing loss. This can be verified in both the DP-gram and the growth rate. Interestingly enough, this corresponds to the DPOAE changes after TTS found by Oeken & Menz (1996), which were produced by 20 minutes of white noise at 90 dB SPL in 102 ears belonging to people with unimpaired hearing. Here too, asignificant but quantitatively minor drop in the DP amplitudes was found after statistical analysis. The cochlear amplifier appears to be still functioning and persistent hearing impairment is unlikely. However, further investigations are necessary to find out whether existence of DPOAE can really provide an information about the prognosis of a hearing recovery independently of the degree of the hearing loss. To resume, it can be stated that DPOAE measurement can be used to a further differentiation of noise-induced damage to the inner ear. Whereas in chronic acoustic traumaemphasis is placed on detecting cochlear lesion (especially in medical opinion), measuring the DPOAE upon acute acoustic trauma could be relevant to prognosis - something which is ofconsiderable importance for both therapy decisions and patient advice. CONCLUSIONS1. DPOAE measurement can provide further information about the function of outer hair cells in cases of acute acoustic trauma.2. Cases in which clear DPs are measurable despite hearing loss are more likely to be blessed by spontaneous recovery. Cases in which no DPs can be detected in the affected frequencies will more probably lead to persistent hearing loss.3. Measurement of the DP-gram alone is sufficient; the growth rate provides no additional information.ACKNOWLEDGEMENTSThis work was kindly supported by the "Hauptverband der gewerblichenBerufsgenossenschaften" ("Confederation of Commercial Professional Associations").This paper was presented at the 3rd European Conference on Protection Against Noise (PAN), 12-15 March 1998, Stockholm Sweden organised and supported by the European Commission BIOMED 2 concerted action PAN (Contract BMH 4-CT96-0110). Correspondence Address:Jens OekenHNO-Universitätsklinik, Liebigstr. 18a, D04103 Leipzig, Germany Tel: +49 341 97 21816 Fax: +49 341 97 21709 email: oekj@server3.medizin.uni-leipzig.de REFERENCESAlexander, E. and Githier, J. (1951) Histological examination of cochlear structure following exposure tojet engine noise. J. Comp. Physiol . 44, 513Avan, P. and Bonfils, P. (1993) Frequency specificity of human distortion product otoacoustic emissions. Audiology 32, 12-26 Beck, C. (1955) Kernveränderungen der Haarzellen nachBeschallung. Arch. Klin.-Exp. Ohr.-, Nas.- u. Kehlk.-Heilk. 167, 262-269 Dieroff, H.G. (1994) Lärmschwerhörigkeit. Fischer Jena Stuttgart, pp 187-189Dieroff, H.G. and Beck, C. (1964) Experimentellmikroskopische Studie zur Frage der Lokalisation von bleibenden Hörschäden nach Industrieiärmbeiastung mit tonalen Geräuschanteilen. Arch. Ohr-. Nas.- u. Kehik.-Heilk. 184, 33Engström, H. and Ades, W. (1960) Effect of high intensity noise on inner ear sensory epithelia. Acta Oto-laryng (Stockh.) Suppl. 158, 219-224Gogniashwili, O.S. (1972) Electron microscopic investigation of the organ of Corti after noise trauma. Bull. of the Academy of Sciences of the Georgian SSR 68, 1Hauser, R. and Probst, R. (1991) The influence ofsystematic primary tone level variation L2-L1 on the acoustic distortion product emission 2f1-f2 in normalhearing ears. J. Acoust. Soc. Am. 89, 280-286Kummer, P., Janssen, T., Arnold, W. (1995) Suppressiontuning characteristics of the 2f1-f2 distortion-product otoacoustic emission in humans. J.Acoust.Soc.Am. 98(1):197-210Lehnhardt, E. and Koch, T. (1993) Akustisches Trauma In: Oto-Rhino-Laryngologie in Klinik und Praxis. Naumann, H.H., Helms, J., Herberhold C. and Kastenbauer, E. (eds.). Bd. 1. Thieme Stuttgart, pp 757-767Nielsen, L.H., Popeika, G.R., Rasmussen, A.N. and Osterhammel, P.A. (1993) Clinical significance of probetone frequency ratio on distortion product otoacoustic emissions. Scand Audiol 22, 159-164Oeken, J. and Menz, D. (1996) Amplitudenveränderungen von Distorsionsprodukten otoakustischer Emissionen nach akuter Lärmeinwirkung. Laryngo-Rhino-Otol. 75, 265-269Oeken, J. and Müller, H. (1995) DPOAE bei chronischer Lärmschwerhörigkeit - Vorschlag zur Begutachtung. Laryngo-Rhino-Otol. 74, 473-480Pilgram, M. and Schumann, K. (1985) Hyperbaric oxygen therapy for acute acoustic trauma. Arch. Otorhinolaryngol. 241, 247-257Pilgram, M. (1994) Akutes akustisches Trauma durch Schußbelastung. In Lärmschwerhörigkeit. Dieroff, H.G. (ed.). Fischer Jena Stuttgart, pp 142-157Plinkert, P.K. and de Maddalena, H. (1996) Die Ableitung otoakustischer Emissionen bei der Begutachtung der chronischen Lärmschwerhörigkeit. HNO 44, 313-318Rüedi, L. and Furrer, W. (1946) Das akustische Trauma. Pract. Otorhinolaryngol. 8, 177-372Rüedi, L. and Furrer, W. (1946) Physics and physiology of acoustic trauma. J.Acoust.Soc.Amer. 18, 409-412 Sliwinska-Kowalska, M. and Sulkowski, W. (1995) Otoacoustic emissions in assessment of occupational noise-induced hearing loss. Proceedings European Conference on Audiology, Noordwijkerhout 335-338 Spoendlin, H. (1958) Submikroskopische Veränderungen am Corti'schen Organ des Meerschweinchens nach akustischer Belastung. Pract. Oto-rhino-laryng. (Basel) 20, 197Spoendlin, H. (1971) Primary structural changes in the organ of Corti after acoustic overstimulation. Acta Otolaryngol. 71, 166-176Spoendlin, H. (1971) Degeneration behaviour of the cochlear nerve. Arch. Klin.-Exp. Ohr.-, Nas.- u. Kehlk.-Heilk. 200, 275-291 Ward, W.D. (1991) Noise-Induced Hearing Damage. In Otolaryngology Vol. 2. Paparella, M.M., Shumrick, D.A., Gluckmann, J.L. and Meyerhoff, W.L. (eds.) Saunders-Company, Philadelphia, London, Toronto, Montreal, Sydney, Tokyo, pp 1639-165266。
