{"id":1842,"date":"2023-03-11T10:02:02","date_gmt":"2023-03-11T10:02:02","guid":{"rendered":"https:\/\/bacta-implants.com\/?page_id=1842"},"modified":"2024-06-18T14:34:18","modified_gmt":"2024-06-18T14:34:18","slug":"publikationen","status":"publish","type":"page","link":"https:\/\/bacta-implants.com\/en\/publikationen\/","title":{"rendered":"Publications"},"content":{"rendered":"<h2 class=\"gb-headline gb-headline-804f52b0 gb-headline-text\">Publications<\/h2>\n\n\n\n<p>2023<\/p>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-0889961 is-style-default\" data-block-id=\"0889961\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-6df9d71 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"6df9d71\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-6df9d71-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-6df9d71-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-b8235f3\" data-block-id=\"b8235f3\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-d945138\" id=\"matin-mann-f-gao-z-wei-c-repp-f-artukarslan-e-john-s-alcacer-labrador-d-lenarz-t-strong-scheper-v-strong-a-href-https-doi-org-10-3390-jimaging-9020051-target-blank-rel-noreferrer-noopener-development-and-in-silico-and-ex-vivo-validation-of-a-software-for-a-semi-automated-segmentation-of-the-round-window-niche-to-design-a-patient-specific-implant-to-treat-inner-ear-disorders-a-j-imaging-february-2023\" data-block-id=\"d945138\"><style>.stk-d945138 .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Matin-Mann F, Gao Z, Wei C, Repp F, Artukarslan E, John S, Alcacer Labrador D, Lenarz T,\u00a0<strong>Scheper V<\/strong>.\u00a0<a href=\"https:\/\/doi.org\/10.3390\/jimaging9020051\" target=\"_blank\" rel=\"noreferrer noopener\">Development and In-Silico and Ex-Vivo Validation of a Software for a Semi-Automated Segmentation of the Round Window Niche to Design a Patient Specific Implant to Treat Inner Ear Disorders<\/a>\u00a0J. Imaging, February 2023<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-d9aa7b5\" data-block-id=\"d9aa7b5\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-d9aa7b5\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-9-aa-7-b-5-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-9-aa-7-b-5-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-ceb239a stk-block-accordion__content\" data-v=\"4\" data-block-id=\"ceb239a\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-ceb239a-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-ceb239a-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-7108565\" data-block-id=\"7108565\"><style>.stk-7108565 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">The aim of this study was to develop and validate a semi-automated segmentation approach that identifies the round window niche (RWN) and round window membrane (RWM) for use in the development of patient individualized round window niche implants (RNI) to treat inner ear disorders. Twenty cone beam computed tomography (CBCT) datasets of unilateral temporal bones of patients were included in the study. Defined anatomical landmarks such as the RWM were used to develop a customized 3D Slicer\u2122 plugin for semi-automated segmentation of the RWN<a href=\"https:\/\/doi.org\/10.3390\/jimaging9020051\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-5091e30 is-style-default\" data-block-id=\"5091e30\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-31e2200 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"31e2200\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-31e2200-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-31e2200-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-d64560a\" data-block-id=\"d64560a\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-f89ec27\" id=\"strong-knabel-m-strong-drager-g-lenarz-t-strong-scheper-v-strong-a-href-https-www-journals-infinite-science-de-index-php-ammm-article-view-803-development-and-validation-of-a-3-d-printed-artificial-round-window-niche-for-use-in-release-kinetics-analysis-of-round-window-niche-implants-a-transactions-on-additive-manufacturing-meets-medicine-trans-ammm-vol-5-no-1-september-2023\" data-block-id=\"f89ec27\"><style>.stk-f89ec27 .stk-block-heading__text{text-shadow:none !important}<\/style><p class=\"stk-block-heading__text\"><strong>Knabel M<\/strong>, Dr\u00e4ger G, Lenarz T, <strong>Scheper V<\/strong>.\u00a0<a href=\"https:\/\/www.journals.infinite-science.de\/index.php\/ammm\/article\/view\/803\">Development and validation of a 3D-printed artificial round window niche for use in release kinetics analysis of round window niche implants<\/a> Transactions on Additive Manufacturing Meets Medicine, Trans. AMMM, Vol. 5 No. 1, September 2023<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-6a0fc29\" data-block-id=\"6a0fc29\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-6a0fc29\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-6-a-0-fc-29-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-6-a-0-fc-29-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-dde92c4 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"dde92c4\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-dde92c4-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-dde92c4-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-410f90c\" data-block-id=\"410f90c\"><p class=\"stk-block-text__text\">The regular way to determine the in vitro release rates of drugs from implantable drug delivery systems consists of the complete immersion of the implant into a medium. The medium surrounds the implant, and the diffusion of the drugs occurs across the whole implant surface directly into the medium. This method does not accurately model the release rates if the real diffusion only happens across only one part of the surface of the implant, through a membrane, and into a small volume of medium. It also does &#8230;<\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<p>2022<\/p>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-174948a is-style-default\" data-block-id=\"174948a\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-005301e stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"005301e\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-005301e-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-005301e-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-3a0c821\" data-block-id=\"3a0c821\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-dd11efc\" id=\"title-for-this-block-mau-r-schick-p-matin-mann-f-gao-z-alcacer-labrador-d-john-s-repp-f-lenarz-t-weitschies-w-strong-scheper-v-strong-seidlitz-a-seitz-h-a-href-https-doi-org-10-18416-ammm-2022-2209666-target-blank-rel-noreferrer-noopener-digital-light-processing-and-drug-stability-of-dexamethasone-loaded-implant-prototypes-for-medical-treatment-of-the-inner-ear-a-transactions-on-additive-manufacturing-meets-medicine-september-2022\" data-block-id=\"dd11efc\"><style>.stk-dd11efc .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Mau R, Schick P, Matin-Mann F, Gao Z, Alcacer Labrador D, John S, Repp F, Lenarz T, Weitschies W,\u00a0<strong>Scheper V<\/strong>, Seidlitz A, Seitz H.\u00a0<a href=\"https:\/\/doi.org\/10.18416\/AMMM.2022.2209666\" target=\"_blank\" rel=\"noreferrer noopener\">Digital light processing and drug stability of Dexamethasone-loaded implant prototypes for medical treatment of the inner ear<\/a>\u00a0Transactions on Additive Manufacturing Meets Medicine, September 2022<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-d626ef1\" data-block-id=\"d626ef1\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-d626ef1\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-626-ef-1-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-626-ef-1-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-730aa2f stk-block-accordion__content\" data-v=\"4\" data-block-id=\"730aa2f\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-730aa2f-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-730aa2f-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-54e8e11\" data-block-id=\"54e8e11\"><style>.stk-54e8e11 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">3D printed, patient-individualized drug-eluting implants for the round window niche (RWN) are an innovative, minimally invasive concept for the medical treatment of inner ear disorders. In this study, we investigate the 3D printing via digital light processing (DLP) and the long-term drug stability of Dexamethasone(DEX)-loaded implant prototypes (storage of 12 months at 25&nbsp;\u00b0C\/60 % relative humidity and 40 \u00b0C\/75 % relative humidity (\u201caccelerated\u201d)<a href=\"https:\/\/doi.org\/10.18416\/AMMM.2022.2209666\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-e8ceba7 is-style-default\" data-block-id=\"e8ceba7\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-a5b84ff stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"a5b84ff\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-a5b84ff-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-a5b84ff-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-db14242\" data-block-id=\"db14242\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-d2cc0bb\" id=\"mau-r-nazir-j-gao-z-alcacer-labrador-d-repp-f-john-s-lenarz-t-strong-scheper-v-strong-seitz-h-matin-mann-f-a-href-https-doi-org-10-1515-cdbme-2022-1041-target-blank-rel-noreferrer-noopener-digital-light-processing-of-round-window-niche-implant-prototypes-for-implantation-studies-a-current-directions-in-biomedical-engineering-september-2022\" data-block-id=\"d2cc0bb\"><style>.stk-d2cc0bb .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Mau R, Nazir J, Gao Z, Alcacer Labrador D, Repp F, John S, Lenarz T,&nbsp;<strong>Scheper V<\/strong>, Seitz H, Matin-Mann F.&nbsp;<a href=\"https:\/\/doi.org\/10.1515\/cdbme-2022-1041\" target=\"_blank\" rel=\"noreferrer noopener\">Digital Light Processing of Round Window Niche Implant Prototypes for Implantation Studies<\/a>&nbsp;Current Directions in Biomedical Engineering, September 2022<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-33c30a8\" data-block-id=\"33c30a8\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-33c30a8\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-33-c-30-a-8-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-33-c-30-a-8-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-69522ce stk-block-accordion__content\" data-v=\"4\" data-block-id=\"69522ce\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-69522ce-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-69522ce-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-fecdc04\" data-block-id=\"fecdc04\"><style>.stk-fecdc04 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">A new approach that offers the potential for local drug delivery to the inner ear is a 3D printed, patient individualized, drug-loaded implant that precisely fits into the round window niche (RWN). Anatomically correct digital light processing (DLP) 3D printed implant prototypes are beneficial for preoperative planning and rehearsal of implantation techniques due to tactile feedback. The aim is to define desired mechanical material properties for future RWN implants<a href=\"https:\/\/doi.org\/10.1515\/cdbme-2022-1041\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-d97a678 is-style-default\" data-block-id=\"d97a678\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-f0c8437 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"f0c8437\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-f0c8437-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-f0c8437-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-1a255b6\" data-block-id=\"1a255b6\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-21b2f57\" id=\"matin-mann-f-gao-z-schwieger-j-ulbricht-m-domsta-v-senekowitsch-s-weitschies-w-seidlitz-a-doll-k-stiesch-m-lenarz-t-strong-scheper-v-strong-a-href-https-doi-org-10-3390-pharmaceutics-14061242-target-blank-rel-noreferrer-noopener-individualized-additively-manufactured-drug-releasing-external-ear-canal-implant-for-prevention-of-postoperative-restenosis-development-in-vitro-testing-and-proof-of-concept-in-an-individual-curative-trial-a-pharmaceutics-june-2022\" data-block-id=\"21b2f57\"><style>.stk-21b2f57 .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Matin-Mann F, Gao Z, Schwieger J, Ulbricht M, Domsta V, Senekowitsch S, Weitschies W, Seidlitz A, Doll K, Stiesch M, Lenarz T,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/doi.org\/10.3390\/pharmaceutics14061242\" target=\"_blank\" rel=\"noreferrer noopener\">Individualized, Additively Manufactured Drug-Releasing External Ear Canal Implant for Prevention of Postoperative Restenosis: Development, In Vitro Testing, and Proof of Concept in an Individual Curative Trial<\/a>&nbsp;Pharmaceutics, June 2022<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-38641ab\" data-block-id=\"38641ab\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-38641ab\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-38641-ab-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-38641-ab-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-5ebb1ed stk-block-accordion__content\" data-v=\"4\" data-block-id=\"5ebb1ed\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-5ebb1ed-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-5ebb1ed-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-c43ba91\" data-block-id=\"c43ba91\"><style>.stk-c43ba91 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Postoperative restenosis in patients with external ear canal (EEC) atresia or stenosis is a common complication following canaloplasty. Our aim in this study was to explore the feasibility of using a three dimensionally (3D)-printed, patient-individualized, drug ((dexamethasone (DEX)), and ciprofloxacin (cipro))-releasing external ear canal implant (EECI) as a postoperative stent after canaloplasty<a href=\"https:\/\/www.mdpi.com\/1999-4923\/14\/6\/1242\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<p>2021<\/p>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-f42231d is-style-default\" data-block-id=\"f42231d\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-b8f1cf5 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"b8f1cf5\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-b8f1cf5-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-b8f1cf5-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-f993ff1\" data-block-id=\"f993ff1\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-743602d\" id=\"gao-z-schwieger-j-matin-mann-f-behrens-p-lenarz-t-strong-scheper-v-strong-a-href-https-www-mdpi-com-2218-273-x-11-12-1896-htm-target-blank-rel-noreferrer-noopener-dexamethasone-for-inner-ear-therapy-biocompatibility-and-bio-efficacy-of-different-dexamethasone-formulations-in-vitro-a-biomolecules-december-2021\" data-block-id=\"743602d\"><style>.stk-743602d .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Gao Z, Schwieger J, Matin-Mann F, Behrens P, Lenarz T,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/www.mdpi.com\/2218-273X\/11\/12\/1896\/htm\" target=\"_blank\" rel=\"noreferrer noopener\">Dexamethasone for Inner Ear Therapy: Biocompatibility and Bio-Efficacy of Different Dexamethasone Formulations In Vitro<\/a>&nbsp;Biomolecules, December 2021<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-d6e25cf\" data-block-id=\"d6e25cf\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-d6e25cf\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-6-e-25-cf-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-d-6-e-25-cf-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-4791dd6 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"4791dd6\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-4791dd6-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-4791dd6-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-1043066\" data-block-id=\"1043066\"><style>.stk-1043066 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Dexamethasone is widely used in preclinical studies and clinical trials to treat inner ear disorders. The results of those studies vary widely, maybe due to the different dexamethasone formulations used. Laboratory (lab) and medical grade (med) dexamethasone (DEX, C<sub>22<\/sub>H<sub>29<\/sub>FO<sub>5<\/sub>) and dexamethasone dihydrogen phosphate-disodium (DPS, C<sub>22<\/sub>H<sub>28<\/sub>FNa<sub>2<\/sub>O<sub>8<\/sub>P) were investigated for biocompatibility and bio-efficacy in vitro<a href=\"https:\/\/www.mdpi.com\/2218-273X\/11\/12\/1896\/htm\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-97a264a is-style-default\" data-block-id=\"97a264a\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-e43b0a5 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"e43b0a5\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-e43b0a5-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-e43b0a5-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-8087ad8\" data-block-id=\"8087ad8\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-d165ad6\" id=\"gao-z-matin-mann-f-wei-c-lenarz-t-weber-c-john-s-strong-scheper-v-strong-a-href-https-www-degruyter-com-document-doi-10-1515-cdbme-2021-2103-html-target-blank-rel-noreferrer-noopener-3-d-printed-individualized-frontal-neo-ostium-implant-in-endoscopic-sinus-surgery-a-proof-of-concept-study-a-current-directions-in-biomedical-engineering-december-2021\" data-block-id=\"d165ad6\"><style>.stk-d165ad6 .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Gao Z, Matin-Mann F, Wei C, Lenarz T, Weber C, John S,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/www.degruyter.com\/document\/doi\/10.1515\/cdbme-2021-2103\/html\" target=\"_blank\" rel=\"noreferrer noopener\">3D Printed Individualized Frontal Neo-Ostium Implant in Endoscopic Sinus Surgery \u2013 a Proof of Concept Study<\/a>&nbsp;Current Directions in Biomedical Engineering, December 2021<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-9b98992\" data-block-id=\"9b98992\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-9b98992\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-9-b-98992-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-9-b-98992-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-7f49a58 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"7f49a58\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-7f49a58-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-7f49a58-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-ef11cf7\" data-block-id=\"ef11cf7\"><style>.stk-ef11cf7 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">3D-printing paves the way forpersonalized drug therapyvia implantsindividualized for the patient specific anatomy in chronic paranasal sinus diseases.This study bringstogether the workflowof modeling, manufacturing, and sterilization of3D-printed individualized frontal neo-ostium implants(FOI)for optimization of Endoscopic Sinus Surgery (ESS)and validates the implantability of the printed devices<a href=\"https:\/\/www.degruyter.com\/document\/doi\/10.1515\/cdbme-2021-2103\/html\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-e184f9b is-style-default\" data-block-id=\"e184f9b\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-a48f94b stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"a48f94b\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-a48f94b-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-a48f94b-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-b4b6e71\" data-block-id=\"b4b6e71\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-4f4357d\" id=\"mau-r-juttner-g-gao-z-matin-f-alcacer-labrador-d-repp-f-john-s-strong-scheper-v-strong-lenarz-t-seitz-h-a-href-https-www-degruyter-com-document-doi-10-1515-cdbme-2021-2101-html-target-blank-rel-noreferrer-noopener-micro-injection-molding-of-individualised-implants-using-3-d-printed-molds-manufactured-via-digital-light-processing-a-current-directions-in-biomedical-engineering-december-2021\" data-block-id=\"4f4357d\"><style>.stk-4f4357d .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Mau R, J\u00fcttner G, Gao Z, Matin F, Alcacer Labrador D, Repp F, John S,&nbsp;<strong>Scheper V<\/strong>, Lenarz T, Seitz H.&nbsp;<a href=\"https:\/\/www.degruyter.com\/document\/doi\/10.1515\/cdbme-2021-2101\/html\" target=\"_blank\" rel=\"noreferrer noopener\">Micro injection molding of individualised implants using 3D printed molds manufactured via digital light processing<\/a>&nbsp;Current Directions in Biomedical Engineering, December 2021<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-e5692e8\" data-block-id=\"e5692e8\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-e5692e8\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-e-5692-e-8-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-e-5692-e-8-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-3487328 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"3487328\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-3487328-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-3487328-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-f4173fc\" data-block-id=\"f4173fc\"><style>.stk-f4173fc .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Here, we demonstrate a manufacturing process for individualised, small-sized implant prototypes. Our process is promising for the manufacturing of drug-releasing (micro)implants to be implanted in the round window niche (RWN-I, solid body, free-form-shaped design, 1.1 x 2.7 x 3.1 mm) and for frontal neo-ostium implants (FO-I, tube-like design, length ~ 7 mm, \u00d8 ~ 2\u20136 mm) for frontal sinus drainage. Implant prototypes are manufactured using micro injection molding (\u03bcIM)<a href=\"https:\/\/www.degruyter.com\/document\/doi\/10.1515\/cdbme-2021-2101\/html\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-91d67b6 is-style-default\" data-block-id=\"91d67b6\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-aa1e917 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"aa1e917\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-aa1e917-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-aa1e917-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-805e942\" data-block-id=\"805e942\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-a34ab39\" id=\"matin-f-gao-z-bronzlik-p-lenarz-t-strong-scheper-v-strong-a-href-https-doi-org-10-18416-ammm-2021-2109505-target-blank-rel-noreferrer-noopener-a-3-d-printed-patient-specific-artificial-outer-ear-model-for-use-in-auricle-reconstruction-surgery-a-clinical-feasibility-study-a-transactions-on-additive-manufacturing-meets-medicine-vol-3-no-1-2021\" data-block-id=\"a34ab39\"><style>.stk-a34ab39 .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Matin F, Gao Z, Bronzlik P, Lenarz T,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/doi.org\/10.18416\/AMMM.2021.2109505\" target=\"_blank\" rel=\"noreferrer noopener\">A 3D printed patient specific artificial outer ear model for use in auricle reconstruction surgery: a clinical feasibility study<\/a>&nbsp;Transactions on Additive Manufacturing Meets Medicine, Vol 3 No 1 (2021)<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-6be1b0f\" data-block-id=\"6be1b0f\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-6be1b0f\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-6-be-1-b-0-f-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-6-be-1-b-0-f-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-1b1fa52 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"1b1fa52\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-1b1fa52-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-1b1fa52-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-bf776a7\" data-block-id=\"bf776a7\"><style>.stk-bf776a7 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Auricle reconstruction is a routine surgery in the field of Otolaryngology but the design of the reconstruction is based on the clinicians guess of the correct previous anatomy. Using additive manufacturing processes to build a model the surgeon can refer to may be a good substitute for conventional surgery<a href=\"https:\/\/www.journals.infinite-science.de\/index.php\/ammm\/article\/view\/505\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-ea96a09 is-style-default\" data-block-id=\"ea96a09\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-192cecb stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"192cecb\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-192cecb-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-192cecb-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-0ee8507\" data-block-id=\"0ee8507\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-e347081\" id=\"mau-r-juttner-g-gao-z-matin-f-alcacer-labrador-d-repp-f-john-s-strong-scheper-v-strong-lenarz-t-seitz-h-a-href-https-doi-org-10-18416-ammm-2021-2109537-target-blank-rel-noreferrer-noopener-rapid-tooling-for-micro-injection-molding-of-micro-medical-devices-via-digital-light-processing-a-transactions-on-additive-manufacturing-meets-medicine-vol-3-no-1-2021\" data-block-id=\"e347081\"><style>.stk-e347081 .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Mau R, J\u00fcttner G, Gao Z, Matin F, Alcacer Labrador D, Repp F, John S,&nbsp;<strong>Scheper V<\/strong>, Lenarz T, Seitz H.&nbsp;<a href=\"https:\/\/doi.org\/10.18416\/AMMM.2021.2109537\" target=\"_blank\" rel=\"noreferrer noopener\">Rapid tooling for micro injection molding of micro medical devices via digital light processing<\/a>&nbsp;Transactions on Additive Manufacturing Meets Medicine, Vol 3 No 1 (2021)<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-535eb58\" data-block-id=\"535eb58\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-535eb58\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-535-eb-58-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-535-eb-58-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-b4b9b0d stk-block-accordion__content\" data-v=\"4\" data-block-id=\"b4b9b0d\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-b4b9b0d-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-b4b9b0d-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-65f4a32\" data-block-id=\"65f4a32\"><style>.stk-65f4a32 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">High-resolution additive manufacturing methods such as digital light processing (DLP) offer promising opportunities for rapid tooling for micro injection molding (\u00b5IM). There are possible savings in time and costs for \u00b5IM of small and micro plastic parts for sensors, electronics and (bio)medical products<a href=\"https:\/\/www.journals.infinite-science.de\/index.php\/ammm\/article\/view\/537\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-a5036a5 is-style-default\" data-block-id=\"a5036a5\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-d66f205 stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"d66f205\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-d66f205-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-d66f205-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-5c021f9\" data-block-id=\"5c021f9\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-b043c5f\" id=\"matin-f-gao-z-repp-f-john-s-lenarz-t-strong-scheper-v-strong-a-href-https-doi-org-10-3390-jimaging-7050079-target-blank-rel-noreferrer-noopener-determination-of-the-round-window-niche-anatomy-using-cone-beam-computed-tomography-imaging-as-preparatory-work-for-individualized-drug-releasing-implants-a-journal-of-imaging-2021-april-23\" data-block-id=\"b043c5f\"><style>.stk-b043c5f .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Matin F, Gao Z, Repp F, John S, Lenarz T,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/doi.org\/10.3390\/jimaging7050079\" target=\"_blank\" rel=\"noreferrer noopener\">Determination of the Round Window Niche Anatomy Using Cone Beam Computed Tomography Imaging as Preparatory Work for Individualized Drug-Releasing Implants<\/a>&nbsp;Journal of Imaging, 2021 April 23.<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-ae2e489\" data-block-id=\"ae2e489\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-ae2e489\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-ae-2-e-489-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-ae-2-e-489-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-92a3d94 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"92a3d94\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-92a3d94-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-92a3d94-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-60367c9\" data-block-id=\"60367c9\"><style>.stk-60367c9 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Modern therapy of inner ear disorders is increasingly shifting to local drug delivery using a growing number of pharmaceuticals. Access to the inner ear is usually made via the round window membrane (RWM), located in the bony round window niche (RWN). We hypothesize that the individual shape and size of the RWN have to be taken into account for safe reliable and controlled drug delivery<a href=\"https:\/\/www.mdpi.com\/2313-433X\/7\/5\/79\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-f91c1d8 is-style-default\" data-block-id=\"f91c1d8\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-a1a3dde stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"a1a3dde\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-a1a3dde-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-a1a3dde-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-f41f457\" data-block-id=\"f41f457\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-0b3d19d\" id=\"schurzig-d-frohlich-m-raggl-s-strong-scheper-v-strong-lenarz-t-rau-ts-a-href-https-www-mdpi-com-2075-1729-11-5-373-target-blank-rel-noreferrer-noopener-uncoiling-the-human-cochlea-physical-scala-tympani-models-to-study-pharmacokinetics-inside-the-inner-ear-a-life-2021-april-21\" data-block-id=\"0b3d19d\"><style>.stk-0b3d19d .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Schurzig D, Fr\u00f6hlich M, Raggl S,&nbsp;<strong>Scheper V<\/strong>, Lenarz T, Rau TS.&nbsp;<a href=\"https:\/\/www.mdpi.com\/2075-1729\/11\/5\/373\" target=\"_blank\" rel=\"noreferrer noopener\">Uncoiling the Human Cochlea\u2014Physical Scala Tympani Models to Study Pharmacokinetics Inside the Inner Ear<\/a>&nbsp;Life, 2021 April 21.<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-229543a\" data-block-id=\"229543a\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-229543a\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-229543-a-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-229543-a-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-a65c476 stk-block-accordion__content\" data-v=\"4\" data-block-id=\"a65c476\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-a65c476-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-a65c476-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-77f712e\" data-block-id=\"77f712e\"><style>.stk-77f712e .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">In the field of cochlear implantation, artificial\/physical models of the inner ear are often employed to investigate certain phenomena like the forces occurring during implant insertions. Up to now, no such models are available for the analysis of diffusion processes inside the cochlea although drug delivery is playing an increasingly important role in this field<a href=\"https:\/\/www.mdpi.com\/2075-1729\/11\/5\/373\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>\n\n\n\n<p>2020<\/p>\n\n\n\n<details class=\"wp-block-stackable-accordion stk-block-accordion stk-inner-blocks stk-block-content stk-block stk-fdd3198 is-style-default\" data-block-id=\"fdd3198\">\n<summary class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-c11933b stk--container-small stk-block-accordion__heading\" data-v=\"4\" data-block-id=\"c11933b\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-c11933b-container stk-hover-parent\"><div class=\"stk-block-content stk-inner-blocks stk-c11933b-inner-blocks\">\n<div class=\"wp-block-stackable-icon-label stk-block-icon-label stk-block stk-7b8a4ca\" data-block-id=\"7b8a4ca\"><div class=\"stk-row stk-inner-blocks stk-block-content\">\n<div class=\"wp-block-stackable-heading stk-block-heading stk-block-heading--v2 stk-block stk-5da8b0d\" id=\"gao-z-matin-f-weber-c-john-s-lenarz-t-strong-scheper-v-strong-a-href-https-www-mdpi-com-2075-1729-10-12-353-target-blank-rel-noreferrer-noopener-high-variability-of-postsurgical-anatomy-supports-the-need-for-individualized-drug-eluting-implants-to-treat-chronic-rhinosinusitis-a-life-basel-2020-dec-17\" data-block-id=\"5da8b0d\"><style>.stk-5da8b0d .stk-block-heading__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-heading__text\">Gao Z, Matin F, Weber C, John S, Lenarz T,&nbsp;<strong>Scheper V<\/strong>.&nbsp;<a href=\"https:\/\/www.mdpi.com\/2075-1729\/10\/12\/353\" target=\"_blank\" rel=\"noreferrer noopener\">High Variability of Postsurgical Anatomy Supports the Need for Individualized Drug-Eluting Implants to Treat Chronic Rhinosinusitis<\/a>&nbsp;Life (Basel), 2020 Dec 17.<\/p><\/div>\n\n\n\n<div class=\"wp-block-stackable-icon stk-block-icon stk-block stk-4209742\" data-block-id=\"4209742\"><span class=\"stk--svg-wrapper\"><div class=\"stk--inner-svg\"><svg style=\"height:0;width:0\"><defs><lineargradient id=\"linear-gradient-4209742\" x1=\"0\" x2=\"100%\" y1=\"0\" y2=\"0\"><stop offset=\"0%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-4209742-color-1)\"><\/stop><stop offset=\"100%\" style=\"stop-opacity:1;stop-color:var(--linear-gradient-4209742-color-2)\"><\/stop><\/lineargradient><\/defs><\/svg><svg data-prefix=\"fas\" data-icon=\"chevron-down\" class=\"svg-inline--fa fa-chevron-down fa-w-14\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" viewbox=\"0 0 448 512\" aria-hidden=\"true\" width=\"32\" height=\"32\"><path fill=\"currentColor\" d=\"M207.029 381.476L12.686 187.132c-9.373-9.373-9.373-24.569 0-33.941l22.667-22.667c9.357-9.357 24.522-9.375 33.901-.04L224 284.505l154.745-154.021c9.379-9.335 24.544-9.317 33.901.04l22.667 22.667c9.373 9.373 9.373 24.569 0 33.941L240.971 381.476c-9.373 9.372-24.569 9.372-33.942 0z\"><\/path><\/svg><\/div><\/span><\/div>\n<\/div><\/div>\n<\/div><\/div><\/summary>\n\n\n\n<div class=\"wp-block-stackable-column stk-block-column stk-column stk-block stk-c983bdc stk-block-accordion__content\" data-v=\"4\" data-block-id=\"c983bdc\"><div class=\"stk-column-wrapper stk-block-column__content stk-container stk-c983bdc-container stk--no-background stk--no-padding\"><div class=\"stk-block-content stk-inner-blocks stk-c983bdc-inner-blocks\">\n<div class=\"wp-block-stackable-text stk-block-text stk-block stk-84ea006\" data-block-id=\"84ea006\"><style>.stk-84ea006 .stk-block-text__text{font-family:\"Open Sans\",Sans-serif !important}<\/style><p class=\"stk-block-text__text\">Chronic rhinosinusitis (CRS) is a common disease in the general population that is increasing in incidence and prevalence, severely affecting patients\u2019 quality of life. Medical treatment for CRS includes self-management techniques, topical and oral medical treatments, and functional endoscopic sinus surgery (FESS). FESS is a standard procedure to restore sinus ventilation and drainage by physically enlarging the inflamed sinus passageways<a href=\"https:\/\/www.mdpi.com\/2075-1729\/10\/12\/353\" target=\"_blank\" rel=\"noreferrer noopener\">&#8230;<\/a><\/p><\/div>\n<\/div><\/div><\/div>\n<\/details>","protected":false},"excerpt":{"rendered":"<p>Publikationen 2023 Matin-Mann F, Gao Z, Wei C, Repp F, Artukarslan E, John S, Alcacer Labrador D, Lenarz T,\u00a0Scheper V.\u00a0Development and In-Silico and Ex-Vivo Validation of a Software for a Semi-Automated Segmentation of the Round Window Niche to Design a Patient Specific Implant to Treat Inner Ear Disorders\u00a0J. Imaging, February 2023 The aim of this [&hellip;]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_uag_custom_page_level_css":"","site-sidebar-layout":"default","site-content-layout":"","ast-site-content-layout":"default","site-content-style":"default","site-sidebar-style":"default","ast-global-header-display":"","ast-banner-title-visibility":"","ast-main-header-display":"","ast-hfb-above-header-display":"","ast-hfb-below-header-display":"","ast-hfb-mobile-header-display":"","site-post-title":"disabled","ast-breadcrumbs-content":"","ast-featured-img":"","footer-sml-layout":"","ast-disable-related-posts":"","theme-transparent-header-meta":"","adv-header-id-meta":"","stick-header-meta":"","header-above-stick-meta":"","header-main-stick-meta":"","header-below-stick-meta":"","astra-migrate-meta-layouts":"set","ast-page-background-enabled":"default","ast-page-background-meta":{"desktop":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"tablet":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"mobile":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""}},"ast-content-background-meta":{"desktop":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"tablet":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"mobile":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""}},"footnotes":""},"class_list":["post-1842","page","type-page","status-publish","hentry"],"uagb_featured_image_src":{"full":false,"thumbnail":false,"medium":false,"medium_large":false,"large":false,"1536x1536":false,"2048x2048":false,"trp-custom-language-flag":false},"uagb_author_info":{"display_name":"admin","author_link":"https:\/\/bacta-implants.com\/en\/author\/admin\/"},"uagb_comment_info":0,"uagb_excerpt":"Publikationen 2023 Matin-Mann F, Gao Z, Wei C, Repp F, Artukarslan E, John S, Alcacer Labrador D, Lenarz T,\u00a0Scheper V.\u00a0Development and In-Silico and Ex-Vivo Validation of a Software for a Semi-Automated Segmentation of the Round Window Niche to Design a Patient Specific Implant to Treat Inner Ear Disorders\u00a0J. Imaging, February 2023 The aim of this&hellip;","_links":{"self":[{"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/pages\/1842","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/comments?post=1842"}],"version-history":[{"count":21,"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/pages\/1842\/revisions"}],"predecessor-version":[{"id":3471,"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/pages\/1842\/revisions\/3471"}],"wp:attachment":[{"href":"https:\/\/bacta-implants.com\/en\/wp-json\/wp\/v2\/media?parent=1842"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}