Microneedles for the inner ear

Aksit, Aykut

January 2022

The cochlea, or inner ear, is a space fully enclosed within the temporal bone of the skull, except for two membrane-covered portals connecting it to the middle ear space. One of these portals is the round window, which is covered by the Round Window Membrane (RWM). A longstanding clinical goal is to gain reliable and precise access to the cochlea with the purpose of delivering therapeutics to treat a plethora of auditory and vestibular disorders, or to aspirate fluids for diagnostic purposes. Standard of care for several difficult-to-treat diseases calls for injection of a therapeutic substance through the tympanic membrane into the middle ear space, after which a portion of the substance diffuses across the RWM into the cochlea. The efficacy of this technique is limited by an inconsistent rate of molecular transport across the RWM. Other solutions for delivery require either traumatic drilling through the bone of the cochlea, or perforating the delicate RWM, which is prone to rupturing with the use of regular surgical tools. For conducting precision diagnostics, even fewer options exist. In our research group, utilizing a newly available technology called Two-Photon Lithography, (2PP) we have developed a suite of ultra-sharp microneedles that are able to create repeatable and reliable perforations in the RWM without tearing. These holes were seen to spontaneously heal within 48 hours, and did not cause any audiological or functional consequences. Furthermore, we have designed needles that can, while inserted into the cochlea, inject or aspirate fluid of microliter quantities, to and from the inner ear, safely. In this thesis, I will discuss the development of these microneedles: their methods, design, use, and modeling. The results show that the microneedles hold great promise to diagnose and treat hearing and balance disorders.

Mechanical engineering

Medicine

Cochlea

http://id.worldcat.org/fast/990454

Ear--Diseases--Treatment

Characterization of a broad-spectrum antimicrobial peptide from Enterococcus mundtii active against bacteria associated with middle ear infections

Knoetze, Hendriette

12 1900

Thesis (MSc)--University of Stellenbosch, 2006. / ENGLISH ABSTRACT: Strain ST4SA, isolated from soya beans, was identified as Enterococcus mundtii. BacST4SA, a bacteriocin produced by strain ST4SA inhibited the growth of Acinetobacter baumannii, Bacillus cereus, Clostridium tyrobutyricum, Enterococcus faecalis, Enterococcus faecium, Lactobacillus sakei, Propionibacterium spp., Streptococcus caprinus, Pediococcus sp., Listeria monocytogenes, Staphylococcus aureus, Streptococcus pneumoniae, and unidentified middle ear isolates A, BW, DW, F, G, and H. BacST4SA was active against Pseudomonas aeruginosa G, BG, I, J, B and E, although variable degrees of resistance were observed for some strains. BacST4SA is positively charged, hydrophobic, contains the YGNGV sequence in the N-terminal, a double-glycine processing site and a disulphide bridge, all of which is typical of a class IIa bacteriocin. The operon, which contains a structural-, ATP-dependent transporter- and immunity gene, is located on a 50-kb plasmid. The 58-amino acid prepeptide is homologous to mundticin KS, mundticin AT06 and bacteriocin QU 2, and differs from enterocin CRL35 by only two amino acids. The 674-amino acid ATP-dependent transporter, consisting of a peptidase C39B domain, an ABC-transporter and an ABC-DLP family domain, displayed 98.9% homology to mundticin KS and 99.25% to enterocin CRL35. The 98-amino acid immunity gene of bacST4SA is completely homologous to enterocin CRL35 and 96.9% to mundticin KS. BacST4SA is 3.950 kDa in size, based on electron spray mass spectrometry. The peptide was isolated from the cell-free supernatant, precipitated with 80% saturated ammonium sulphate, dialysed and freeze-dried to 1 638 400 AU (arbitrary units) per ml. No change in antimicrobial activity was recorded when bacST4SA was incubated in buffer ranging from pH 2 to 12, heated to 100 °C for 90 min and 121 °C for 20 min, and when incubated in the presence of Tween 20, Tween 80, Triton X-100, SDS, urea, EDTA, middle ear fluid and blood. Optimal levels of bacST4SA production (51 200 AU/ml) was recorded after 14 h of growth in MRS broth at 30°C. Maximum production (102 400 AU/ml) was recorded in modified MRS media supplemented with tryptone, yeast extract, a combination of tryptone and yeast extract, K2HPO4 (10.0 or 20.0 g/l), or with the addition of DL-6,8-thoictic acid, L-ascorbic acid, and thiamine, respectively. BacST4SA is bactericidal towards E. faecium HKLHS and bacteriostatic towards S. pneumoniae 40 and middle ear isolates F, BW and H. The peptide adsorbed maximal (94%) to S. pneumoniae 40, P. aeruginosa 25 and E. faecium HKLHS. BacST4SA forms pores in the cytoplasmic membrane of sensitive cells, leading to dissipation of the cell membrane and leakage of cytoplasmic material. BacST4SA was compared with various other antimicrobial treatment agents, and revealed similar to a higher activity towards a number of these agents. BacST4SA revealed a similar level of activity against E. faecium HKLHS and middle ear pathogens P. aeruginosa J and S. pneumoniae 27 when compared with tetracycline (30μg). However, bacST4SA revealed much higher activity when compared to nasal sprays, aminoglycosides, cephalosporins, fluoroquinolones, lincosamides, macrolides, nitroimidazole, penicillin, quinolones, sulfonamides, chloramphenicol, furanzolidone, fusidic acid, rifampicin, trimethoprim, trimethoprim-sulfamethoxazole and vancomycin when tested in vitro. / AFRIKAANSE OPSOMMING: Stam ST4SA, geïsoleer uit sojabone, is as Enterococcus mundtii geidentifiseer. BacST4SA, ‘n bakteriosien geproduseer deur stam ST4SA het die groei van Acinetobacter baumannii, Bacillus cereus, Clostridium tyrobutyricum, Enterococcus faecalis, Enterococcus faecium, Lactobacillus sakei, Propionibacterium spp., Streptococcus caprinus, Pediococcus sp., Listeria monocytogenes, Staphylococcus aureus, Streptococcus pneumoniae en ongeïdentifiseerde middeloor isolate A, BW, DW, F, G, en H geinhibeer. BacST4SA is aktief teen Pseudomonas aeruginosa stamme G, BG, I, J, B en E, alhoewel effense weerstand soms waargeneem is. BacST4SA het ‘n netto positiewe lading, is hidrofobies, bevat die YGNGV-volgorde in die N-terminaal, ‘n dubbel-glisien prosesserings setel en ‘n disulfied brug, kenmerkend van klas IIa bakteriosiene. Die operon, wat bestaan uit ‘n strukturele geen, ‘n ATP-afhanklike transport sisteem geen en ‘n immuniteits-geen, is op ‘n 50 kb plasmied gelokaliseer. Die voorloper peptied (58 aminosure lank), is homoloog aan mundticin KS, mundticin AT06 en bakteriosien QU 2 en verskil van enterocin CRL35 met slegs twee aminosure. Die ATP-afhanklike transporter (674 aminosure lank) bestaan uit ‘n peptidase C39B domein, ‘n ABC-transporter en ‘n ABC-DLP tipe domein en is 98.9% homoloog aan mundticin KS and 99.25% aan enterocin CRL35. Die immuniteits-geen (98 aminosure lank) van bacST4SA is ten volle homoloog aan enterocin CRL35 en 96.9% homoloog aan mundticin KS. BacST4SA is 3.950 kDa groot, gebaseer op elektrosproei-massa spektrometrie. Die peptied is uit selvrye supernatant geïsoleer, met 80% versadigde ammonium sulfaat gepresipiteer, gedialiseer en gevriesdroog tot ’n finale konsentrasie van 1 638 400 AE (arbitrêre eenhede) per ml. Geen verandering in antimikrobiese aktiwiteit is waargeneem tydens inkubasie van bacST4SA in buffer van pH 2 tot 12, tydens verhitting (100 °C vir 90 min en 121 °C vir 20 min) en tydens inkubasie in die teenwoordigheid van Tween 20, Tween 80, Triton X-100, SDS, ureum, EDTA, middeloor vloeistof en bloed. Optimale vlakke van bacST4SA produksie (51 200 AE/ml) is na 14 h groei in MRS media by 30°C waargeneem. Maksimale vlakke van die peptied (102 400 AE/ml) is geproduseer in gemodifiseerde MRS medium, aangevul met triptoon, gisekstrak, ‘n kombinasie van triptoon en gisekstrak, K2HPO4 (10.0 of 20.0 g/l), of met byvoeging van DL-6,8-thioktiensuur, L-askorbiensuur, en tiamien onderskeidelik. BacST4SA is bakteriosidies teenoor E. faecium HKLHS en bakteristaties teenoor S. pneumoniae 40 en middeloor isolate F, BW en H. Die peptied adsorbeer optimaal (94%) aan S. pneumoniae 40, P. aeruginosa 25 en E. faecium HKLHS. BacST4SA vorm porieë in die selmembraan van sensitiewe selle en lei tot vernietiging van die selmembraan en lekkasie van die sitoplasma inhoud. In vergelykende studies het bacST4SA ‘n soortgelyke en selfs hoër antimikrobiese aktiwiteit teenoor ‘n aantal bekende antimikrobiese middels getoon. Die aktiwiteit van bacST4SA is soortgelyk aan dié van tetrasiklien (30μg) in toetse teen E. faecium HKLHS en middeloor patogene P. aeruginosa J en S. pneumoniae 27. BacST4SA het egter in ’n in vitro vergelyking met neussproeie, aminoglisiedes, cephalosporiene, fluoroquinolone, lincosamides, makroliede, nitroimidazole, penisilien, quinolone, sulfonamide, chloramphenicol, furanzolidone, fusiensuur, rifampisien, trimethoprim, trimethoprim-sulfamethoxazool en vankomisien ‘n baie hoër aktiwiteit teen patogene getoon.

Ear -- Infections -- Treatment

Middle ear -- Diseases -- Treatment

Peptide antibiotics

Bacteriocins

Otitis media -- Treatment

Enterococcus

Enterococcal infections

Theses -- Microbiology

Dissertations -- Microbiology

Reconstitution of mouse inner ear sensory development from pluripotent stem cells

Koehler, Karl R.

01 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The inner ear contains specialized sensory epithelia that detect head movements, gravity and sound. Hearing loss and imbalance are primarily caused by degeneration of the mechanosensitive hair cells in sensory epithelia or the sensory neurons that connect the inner ear to the brain. The controlled derivation of inner ear sensory epithelia and neurons from pluripotent stem cells will be essential for generating in vitro models of inner ear disorders or developing cell-based therapies. Despite some recent success in deriving hair cells from mouse embryonic stem (ES) cells, it is currently unclear how to derive inner ear sensory cells in a fully defined and reproducible manner. Progress has likely been hindered by what is known about induction of the nonneural and preplacodal ectoderm, two critical precursors during inner ear development. The studies presented here report the step-wise differentiation of inner ear sensory epithelia from mouse ES cells in three-dimensional culture. We show that nonneural, preplacodal and pre-otic epithelia can be generated from ES cell aggregates by precise temporal control of BMP, TGFβ and FGF signaling, mimicking in vivo development. Later, in a self-guided process, vesicles containing supporting cells emerge from the presumptive otic epithelium and give rise to hair cells with stereocilia bundles and kinocilium. Remarkably, the vesicles developed into large cysts with sensory epithelia reminiscent of vestibular sense organs (i.e. the utricle, saccule and crista), which sense head movements and gravity in the animal. We have designated these stem cell-derived structures inner ear organoids. In addition, we discovered that sensory-like neurons develop alongside the organoids and form putative synapses with hair cells in a similar fashion to the hair cell-to-neuron circuit that forms in the developing embryo. Our data thus establish a novel in vitro model of inner ear organogenesis that can be used to gain deeper insight into inner ear development and disorder.

Inner ear

Pluripotent stem cells

Hair cells

Labyrinth (Ear) -- Cytology

Labyrinth (Ear) -- Cytopathology

Labyrinth (Ear) -- Pathophysiology

Labyrinth (Ear) -- Research

Labyrinth (Ear) -- Diseases -- Treatment

Epithelial cells

Deafness

Cellular therapy

Cochlea -- Pathophysiology

Hearing disorders

Multipotent stem cells

Embryonic stem cells

Cell differentiation

Mice as laboratory animals