Design of a new intraoral splint with 3D-printed inserts for dental biofilm collection

Sebastian Schlafer; Andreas Møllebjerg; Karina Kambourakis Johnsen; Signe Maria Nielsen; Rikke Louise Meyer

Design of a new intraoral splint with 3D-printed inserts for dental biofilm collection

Sebastian Schlafer, Andreas Møllebjerg, Karina Kambourakis Johnsen, Signe Maria Nielsen, Rikke Louise Meyer

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Conference abstract in journal › Research › peer-review

Abstract

Biofilm models are important tools to study the impact of bacterial metabolism and the effect of therapeutic measures on the caries process. Laboratory models consisting of few bacterial species are useful for high-throughput testing, but in-situ models reflect the complexity of the oral environment much better. The increased complexity typically results in a large variation in the amount of biofilm produced, not only between individuals but also between biofilms collected from the same person. Here, we designed a lower-jaw-splint with 3D-printed silicon inserts that protect the biofilm samples during growth and provide a standardized recession for each individual biofilm sample. We hypothesized that a standardized splint geometry reduces variation between replicate biofilm samples from the same individual and increases the amount of biofilm produced, compared to an in-situ-model without standardized geometry. The splints consisted of a 3D-printed metallic arch and two acrylic vestibular extensions. The extensions contained 3D-printed silicon inserts for biofilm carriers (4x4x1.5 mm). Each individual carrier was surrounded by silicon walls, recessed by 1.5 mm and kept in place by an undercut. 48-h biofilms were collected in 6-tuplicate (2 technical, 3 biological replicates) from five healthy participants, both with standardized splints and with ‘traditional’ splints where the carriers were fixed with sticky wax. The biovolume was determined by confocal microscopy. The coefficient of intra-individual variation was high for both systems, but slightly lower for the standardized splints (69 vs. 80). The average amount of biofilm was slightly lower on the standardized splints (124599 µm3±70284 SD vs. 163616 µm3±135033 SD), with no statistically significant difference (p=0.33, 2-sample t-test). The use of silicon inserts eased the handling of the biofilm samples.

Original language	English
Journal	Caries Research
ISSN	0008-6568
Publication status	Published - Jul 2020
Event	ORCA: 67th Congress of the European Organization for Caries Research - Online Duration: 9 Jul 2020 → 11 Jul 2020 https://www.orca-caries-research.org/events/67th-orca-congress

Conference

Conference	ORCA: 67th Congress of the European Organization for Caries Research
Location	Online
Period	09/07/2020 → 11/07/2020
Internet address	https://www.orca-caries-research.org/events/67th-orca-congress

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title = "Design of a new intraoral splint with 3D-printed inserts for dental biofilm collection",

abstract = "Biofilm models are important tools to study the impact of bacterial metabolism and the effect of therapeutic measures on the caries process. Laboratory models consisting of few bacterial species are useful for high-throughput testing, but in-situ models reflect the complexity of the oral environment much better. The increased complexity typically results in a large variation in the amount of biofilm produced, not only between individuals but also between biofilms collected from the same person. Here, we designed a lower-jaw-splint with 3D-printed silicon inserts that protect the biofilm samples during growth and provide a standardized recession for each individual biofilm sample. We hypothesized that a standardized splint geometry reduces variation between replicate biofilm samples from the same individual and increases the amount of biofilm produced, compared to an in-situ-model without standardized geometry. The splints consisted of a 3D-printed metallic arch and two acrylic vestibular extensions. The extensions contained 3D-printed silicon inserts for biofilm carriers (4x4x1.5 mm). Each individual carrier was surrounded by silicon walls, recessed by 1.5 mm and kept in place by an undercut. 48-h biofilms were collected in 6-tuplicate (2 technical, 3 biological replicates) from five healthy participants, both with standardized splints and with {\textquoteleft}traditional{\textquoteright} splints where the carriers were fixed with sticky wax. The biovolume was determined by confocal microscopy. The coefficient of intra-individual variation was high for both systems, but slightly lower for the standardized splints (69 vs. 80). The average amount of biofilm was slightly lower on the standardized splints (124599 µm3±70284 SD vs. 163616 µm3±135033 SD), with no statistically significant difference (p=0.33, 2-sample t-test). The use of silicon inserts eased the handling of the biofilm samples.",

author = "Sebastian Schlafer and Andreas M{\o}llebjerg and {Kambourakis Johnsen}, Karina and Nielsen, {Signe Maria} and Meyer, {Rikke Louise}",

year = "2020",

month = jul,

language = "English",

journal = "Caries Research",

issn = "0008-6568",

publisher = "S. Karger AG",

note = "ORCA: 67th Congress of the European Organization for Caries Research ; Conference date: 09-07-2020 Through 11-07-2020",

url = "https://www.orca-caries-research.org/events/67th-orca-congress",

}

TY - ABST

T1 - Design of a new intraoral splint with 3D-printed inserts for dental biofilm collection

AU - Schlafer, Sebastian

AU - Møllebjerg, Andreas

AU - Kambourakis Johnsen, Karina

AU - Nielsen, Signe Maria

AU - Meyer, Rikke Louise

PY - 2020/7

Y1 - 2020/7

N2 - Biofilm models are important tools to study the impact of bacterial metabolism and the effect of therapeutic measures on the caries process. Laboratory models consisting of few bacterial species are useful for high-throughput testing, but in-situ models reflect the complexity of the oral environment much better. The increased complexity typically results in a large variation in the amount of biofilm produced, not only between individuals but also between biofilms collected from the same person. Here, we designed a lower-jaw-splint with 3D-printed silicon inserts that protect the biofilm samples during growth and provide a standardized recession for each individual biofilm sample. We hypothesized that a standardized splint geometry reduces variation between replicate biofilm samples from the same individual and increases the amount of biofilm produced, compared to an in-situ-model without standardized geometry. The splints consisted of a 3D-printed metallic arch and two acrylic vestibular extensions. The extensions contained 3D-printed silicon inserts for biofilm carriers (4x4x1.5 mm). Each individual carrier was surrounded by silicon walls, recessed by 1.5 mm and kept in place by an undercut. 48-h biofilms were collected in 6-tuplicate (2 technical, 3 biological replicates) from five healthy participants, both with standardized splints and with ‘traditional’ splints where the carriers were fixed with sticky wax. The biovolume was determined by confocal microscopy. The coefficient of intra-individual variation was high for both systems, but slightly lower for the standardized splints (69 vs. 80). The average amount of biofilm was slightly lower on the standardized splints (124599 µm3±70284 SD vs. 163616 µm3±135033 SD), with no statistically significant difference (p=0.33, 2-sample t-test). The use of silicon inserts eased the handling of the biofilm samples.

AB - Biofilm models are important tools to study the impact of bacterial metabolism and the effect of therapeutic measures on the caries process. Laboratory models consisting of few bacterial species are useful for high-throughput testing, but in-situ models reflect the complexity of the oral environment much better. The increased complexity typically results in a large variation in the amount of biofilm produced, not only between individuals but also between biofilms collected from the same person. Here, we designed a lower-jaw-splint with 3D-printed silicon inserts that protect the biofilm samples during growth and provide a standardized recession for each individual biofilm sample. We hypothesized that a standardized splint geometry reduces variation between replicate biofilm samples from the same individual and increases the amount of biofilm produced, compared to an in-situ-model without standardized geometry. The splints consisted of a 3D-printed metallic arch and two acrylic vestibular extensions. The extensions contained 3D-printed silicon inserts for biofilm carriers (4x4x1.5 mm). Each individual carrier was surrounded by silicon walls, recessed by 1.5 mm and kept in place by an undercut. 48-h biofilms were collected in 6-tuplicate (2 technical, 3 biological replicates) from five healthy participants, both with standardized splints and with ‘traditional’ splints where the carriers were fixed with sticky wax. The biovolume was determined by confocal microscopy. The coefficient of intra-individual variation was high for both systems, but slightly lower for the standardized splints (69 vs. 80). The average amount of biofilm was slightly lower on the standardized splints (124599 µm3±70284 SD vs. 163616 µm3±135033 SD), with no statistically significant difference (p=0.33, 2-sample t-test). The use of silicon inserts eased the handling of the biofilm samples.

M3 - Conference abstract in journal

SN - 0008-6568

JO - Caries Research

JF - Caries Research

T2 - ORCA: 67th Congress of the European Organization for Caries Research

Y2 - 9 July 2020 through 11 July 2020

ER -

Design of a new intraoral splint with 3D-printed inserts for dental biofilm collection

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