Start of manufacturing activity at Gyneco-DENT-2000 LTD. (Q3921177): Difference between revisions

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Property / summary
 
With the help of the production line to be procured, we can provide new feet, manufacturing activities and services to dentists and surgeons in the country, and we can produce 3D printed drilling templates that are essential for the perfect implantation of dental implants. The design in the so-called Guided Surgery software (coDiagnostiX) requires the production of 2 types of digital files (made of a patient). 1. With the CT device to be acquired, a DICOM-format recording of the patient’s facial and jaw conditions and anatomical formulas is made. 2. After traditional imprinting, the patient’s rectile oral formulas are visible to the shoulder, which is shown on a model by the dental technician. It digitises this model with a special dental scanner and forms an STL file format, which is sent to the dentist as 2, the design file. The third — definitely recommended file — also in STL file format and is also produced by the dental technician, prepares a prosthetic (replacement) plan. The coDiagnostiX software also displays this file. By collecting these data, we did the best we could to ensure that the implants to be implanted into the patient’s jawbones — in order to anchor the dentures — are in perfect place and position according to the patient’s oral conditions, and serve the future dental prosthesis. This process is called backward planning. In the software, the implants are placed in a virtual position, followed by the design of the template. This plan is verified by a validated centre operated by the software distributor and partner and sends back the correct plan. The resulting computer data is then transferred to the 3D printer, and then the finished surgical template can be manufactured with the help of the 3D printer. The 3D printer you want to buy for this purpose prints the template, then the printed template puts so-called titanium bushings into the printed template. These bushings fixed in the surgical template guide the instrument(s) of the physician performing the implantation. Without error, they put the implants in the pre-planned position in terms of depth and axis. Through development, our market position will be significantly strengthened. We will be able to carry out the previously outsourced template manufacturing process after the purchase of the machines, so we will significantly reduce our costs and expect a significant increase in revenue through toll production. As a result of the development, manufacturing activity is shortened to 1 day, thus shortening the production process, which takes up to 1 week with the involvement of external companies and foreign companies. With the help of the manufacturer line, we can produce a large number of surgical templates in sufficient quantity and quality, so we can manufacture tolls for dentists in the country and use the templates in our own surgical interventions. Based on the needs of the market, we can expect significant orders after the installation of the machines. (English)
Property / summary: With the help of the production line to be procured, we can provide new feet, manufacturing activities and services to dentists and surgeons in the country, and we can produce 3D printed drilling templates that are essential for the perfect implantation of dental implants. The design in the so-called Guided Surgery software (coDiagnostiX) requires the production of 2 types of digital files (made of a patient). 1. With the CT device to be acquired, a DICOM-format recording of the patient’s facial and jaw conditions and anatomical formulas is made. 2. After traditional imprinting, the patient’s rectile oral formulas are visible to the shoulder, which is shown on a model by the dental technician. It digitises this model with a special dental scanner and forms an STL file format, which is sent to the dentist as 2, the design file. The third — definitely recommended file — also in STL file format and is also produced by the dental technician, prepares a prosthetic (replacement) plan. The coDiagnostiX software also displays this file. By collecting these data, we did the best we could to ensure that the implants to be implanted into the patient’s jawbones — in order to anchor the dentures — are in perfect place and position according to the patient’s oral conditions, and serve the future dental prosthesis. This process is called backward planning. In the software, the implants are placed in a virtual position, followed by the design of the template. This plan is verified by a validated centre operated by the software distributor and partner and sends back the correct plan. The resulting computer data is then transferred to the 3D printer, and then the finished surgical template can be manufactured with the help of the 3D printer. The 3D printer you want to buy for this purpose prints the template, then the printed template puts so-called titanium bushings into the printed template. These bushings fixed in the surgical template guide the instrument(s) of the physician performing the implantation. Without error, they put the implants in the pre-planned position in terms of depth and axis. Through development, our market position will be significantly strengthened. We will be able to carry out the previously outsourced template manufacturing process after the purchase of the machines, so we will significantly reduce our costs and expect a significant increase in revenue through toll production. As a result of the development, manufacturing activity is shortened to 1 day, thus shortening the production process, which takes up to 1 week with the involvement of external companies and foreign companies. With the help of the manufacturer line, we can produce a large number of surgical templates in sufficient quantity and quality, so we can manufacture tolls for dentists in the country and use the templates in our own surgical interventions. Based on the needs of the market, we can expect significant orders after the installation of the machines. (English) / rank
 
Normal rank
Property / summary: With the help of the production line to be procured, we can provide new feet, manufacturing activities and services to dentists and surgeons in the country, and we can produce 3D printed drilling templates that are essential for the perfect implantation of dental implants. The design in the so-called Guided Surgery software (coDiagnostiX) requires the production of 2 types of digital files (made of a patient). 1. With the CT device to be acquired, a DICOM-format recording of the patient’s facial and jaw conditions and anatomical formulas is made. 2. After traditional imprinting, the patient’s rectile oral formulas are visible to the shoulder, which is shown on a model by the dental technician. It digitises this model with a special dental scanner and forms an STL file format, which is sent to the dentist as 2, the design file. The third — definitely recommended file — also in STL file format and is also produced by the dental technician, prepares a prosthetic (replacement) plan. The coDiagnostiX software also displays this file. By collecting these data, we did the best we could to ensure that the implants to be implanted into the patient’s jawbones — in order to anchor the dentures — are in perfect place and position according to the patient’s oral conditions, and serve the future dental prosthesis. This process is called backward planning. In the software, the implants are placed in a virtual position, followed by the design of the template. This plan is verified by a validated centre operated by the software distributor and partner and sends back the correct plan. The resulting computer data is then transferred to the 3D printer, and then the finished surgical template can be manufactured with the help of the 3D printer. The 3D printer you want to buy for this purpose prints the template, then the printed template puts so-called titanium bushings into the printed template. These bushings fixed in the surgical template guide the instrument(s) of the physician performing the implantation. Without error, they put the implants in the pre-planned position in terms of depth and axis. Through development, our market position will be significantly strengthened. We will be able to carry out the previously outsourced template manufacturing process after the purchase of the machines, so we will significantly reduce our costs and expect a significant increase in revenue through toll production. As a result of the development, manufacturing activity is shortened to 1 day, thus shortening the production process, which takes up to 1 week with the involvement of external companies and foreign companies. With the help of the manufacturer line, we can produce a large number of surgical templates in sufficient quantity and quality, so we can manufacture tolls for dentists in the country and use the templates in our own surgical interventions. Based on the needs of the market, we can expect significant orders after the installation of the machines. (English) / qualifier
 
point in time: 8 February 2022
Timestamp+2022-02-08T00:00:00Z
Timezone+00:00
CalendarGregorian
Precision1 day
Before0
After0

Revision as of 17:28, 8 February 2022

Project Q3921177 in Hungary
Language Label Description Also known as
English
Start of manufacturing activity at Gyneco-DENT-2000 LTD.
Project Q3921177 in Hungary

    Statements

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    24,203,830 forint
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    66,928.67 Euro
    0.00276521 Euro
    3 December 2021
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    132,328.419 Euro
    0.0027336256 Euro
    15 December 2021
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    48,407,660.0 forint
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    50.0 percent
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    18 December 2017
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    27 March 2018
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    GYNECO-DENT-2000 EGÉSZSÉGÜGYI SZOLGÁLTATÓ KORLÁTOLT FELELŐSSÉGŰ TÁRSASÁG
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    46°20'54.56"N, 18°42'5.98"E
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    A beszerezni kívánt gyártósor segítségével új lábon tudunk állni, gyártási tevékenységet, szolgáltatást tudunk nyújtani az ország fogorvosai, sebészei számára, le tudjuk gyártani a fogászati implantátumok tökéletes beültetéséhez elengedhetetlenül szükséges 3D nyomtatott fúrási sablonokat. Az ún. Guided Surgery (irányított sebészeti) szoftverben (coDiagnostiX) való tervezéshez 2 féle (páciensről alkotott) digitális állomány előállítása szükséges. 1. A beszerezni kívánt CT készülékkel DICOM formátumú felvétel készül a páciens arc-állcsont viszonyairól, anatómiai képleteiről. 2. Hagyományos lenyomatvételt követően a páciens recens szájképletei vállnak láthatóvá, amit modellen jelenít meg a fogtechnikus. Ezt a modellt speciális fogtechnikai szkennerrel digitalizálja és STL fájl formátumot képez, amit megküld a fogorvos számára, mint 2., a tervezéshez szükséges állományt. A harmadik - mindenképpen ajánlott állomány - szintén STL fájl formátumú és szintén a fogtechnikus állítja elő - protetikai (pótlás) tervet készít. A coDiagnostiX szoftver ezt a fájlt is megjeleníti. Ezen adatok begyűjtésével a létező legtöbbet megtettük azért, hogy a páciens állcsontjaiba - fogpótlás elhorgonyzása érdekében - beültetendő implantátumok a páciens szájkondícióinak megfelelően tökéletes helyre, pozícióba kerüljenek, szolgálják a jövőben elkészítendő fogpótlást. Ezt a folyamatot backward planning-nek (visszafelé tervezésnek) hívjuk. A szoftverben ezek alapján az implantátumok virtuális pozícióba kerülnek, amit a sablon megtervezése követ. E tervet a szoftver forgalmazója és partnere által működtetett validált központ ellenőrzi, és visszaküldi a korrekt tervet. Az így létrejövő számítógépes adatok kerülnek aztán a 3D-nyomtatóba, majd a 3D nyomtató segítségével legyártatható a kész sebészi sablon. Az erre a célra vásárolni kívánt 3D nyomtatója a sablont kinyomtatja, majd a nyomtatott sablonba ún. titán perselyek kerülnek. Ezek a sebészi sablonba rögzített perselyek az implantációt végrehajtó orvos műszereit (fúróit) vezetik meg. Hiba nélkül, az előre tervezett pozícióba juttatják az implantátumokat, mélység és tengely tekintetében. A fejlesztés révén piaci pozíciónk jelentősen megerősödik. A korábban kiszervezett sablon legyártási folyamatot a gépek beszerzése után mi fogjuk tudni elvégezni, így jelentősen csökkentjük költségeinket, valamint a bérgyártás révén jelentős bevétel növekedésre számítunk. A fejlesztés hatására gyártási tevékenység 1 napra lerövidül, lerövidítve így a gyártási folyamatot, mely külső cég, külföldi cégek bevonásával akár 1 hetet is igénybe vesz. A gyártó sor segítségével nagy darabszámú sebészi sablonokat megfelelő mennyiségben és minőségben tudjuk előállítani, így az ország fogorvosai számára bérgyártást tudunk vállalni, valamint saját sebészi beavatkozásaink során is alkalmazni tudjuk a sablonokat. A piaci igények alapján jelentős megrendelésekre számíthatunk a gépek üzembe helyezését követően. (Hungarian)
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    With the help of the production line to be procured, we can provide new feet, manufacturing activities and services to dentists and surgeons in the country, and we can produce 3D printed drilling templates that are essential for the perfect implantation of dental implants. The design in the so-called Guided Surgery software (coDiagnostiX) requires the production of 2 types of digital files (made of a patient). 1. With the CT device to be acquired, a DICOM-format recording of the patient’s facial and jaw conditions and anatomical formulas is made. 2. After traditional imprinting, the patient’s rectile oral formulas are visible to the shoulder, which is shown on a model by the dental technician. It digitises this model with a special dental scanner and forms an STL file format, which is sent to the dentist as 2, the design file. The third — definitely recommended file — also in STL file format and is also produced by the dental technician, prepares a prosthetic (replacement) plan. The coDiagnostiX software also displays this file. By collecting these data, we did the best we could to ensure that the implants to be implanted into the patient’s jawbones — in order to anchor the dentures — are in perfect place and position according to the patient’s oral conditions, and serve the future dental prosthesis. This process is called backward planning. In the software, the implants are placed in a virtual position, followed by the design of the template. This plan is verified by a validated centre operated by the software distributor and partner and sends back the correct plan. The resulting computer data is then transferred to the 3D printer, and then the finished surgical template can be manufactured with the help of the 3D printer. The 3D printer you want to buy for this purpose prints the template, then the printed template puts so-called titanium bushings into the printed template. These bushings fixed in the surgical template guide the instrument(s) of the physician performing the implantation. Without error, they put the implants in the pre-planned position in terms of depth and axis. Through development, our market position will be significantly strengthened. We will be able to carry out the previously outsourced template manufacturing process after the purchase of the machines, so we will significantly reduce our costs and expect a significant increase in revenue through toll production. As a result of the development, manufacturing activity is shortened to 1 day, thus shortening the production process, which takes up to 1 week with the involvement of external companies and foreign companies. With the help of the manufacturer line, we can produce a large number of surgical templates in sufficient quantity and quality, so we can manufacture tolls for dentists in the country and use the templates in our own surgical interventions. Based on the needs of the market, we can expect significant orders after the installation of the machines. (English)
    8 February 2022
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    Szekszárd, Tolna
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    Identifiers

    GINOP-1.2.2-16-2017-01204
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