Team:Purdue/Human Practices/iGEM Characterization Standard

From 2013.igem.org

(Difference between revisions)
Line 4: Line 4:
The genetic parts in the “Registry of Standardized Parts” are standardized; however, there is currently no standard method to present the information for each part.  This year the Purdue iGEM team has set out to create standardized data sheets for the Registry.  Standardized data sheets will enable synthetic biologists to gain maximum benefits of and fully understand each genetic part to facilitate future usage.  This web-based template system to submit and present genetic part characterization data will promote consistent presentation of information, enabling ease of use.   
The genetic parts in the “Registry of Standardized Parts” are standardized; however, there is currently no standard method to present the information for each part.  This year the Purdue iGEM team has set out to create standardized data sheets for the Registry.  Standardized data sheets will enable synthetic biologists to gain maximum benefits of and fully understand each genetic part to facilitate future usage.  This web-based template system to submit and present genetic part characterization data will promote consistent presentation of information, enabling ease of use.   
 +
 +
<break></break>
Although the Purdue iGEM Team is the face behind the standardized datasheet creation, this endeavor could not have been completed without the help of the 79 other iGEM teams that we collaborated with.  This large-scale collaboration is unprecedented in the history of the iGEM competition.  With a global collaboration of teams in 15 countries, we combined the knowledge and perspectives of numerous synthetic biologists with broad ranges of experience to create the most universal and appropriate datasheet.
Although the Purdue iGEM Team is the face behind the standardized datasheet creation, this endeavor could not have been completed without the help of the 79 other iGEM teams that we collaborated with.  This large-scale collaboration is unprecedented in the history of the iGEM competition.  With a global collaboration of teams in 15 countries, we combined the knowledge and perspectives of numerous synthetic biologists with broad ranges of experience to create the most universal and appropriate datasheet.
 +
 +
<break></break>
There were many phases to this collaboration process, and teams participated in the collaboration to different extents.  We initiated the collaboration process by gathering contact information of as many iGEM teams as possible.  With that information, an initial survey was sent to individuals of each team to assess levels of interest and outline our general plan.  This survey asked teams to address problems with the current Registry system and to establish which teams were interested in officially collaborating with the Purdue team.
There were many phases to this collaboration process, and teams participated in the collaboration to different extents.  We initiated the collaboration process by gathering contact information of as many iGEM teams as possible.  With that information, an initial survey was sent to individuals of each team to assess levels of interest and outline our general plan.  This survey asked teams to address problems with the current Registry system and to establish which teams were interested in officially collaborating with the Purdue team.
-
 
+
<break></break>
A second survey was then sent out to those teams interested in collaborating, asking which assays each team is capable of performing to characterize genetic parts, along with teams’ analysis of the importance of each assay.  The survey also gathered assurance from each team that a datasheet is an effective way to standardize characterization data in the registry.  
A second survey was then sent out to those teams interested in collaborating, asking which assays each team is capable of performing to characterize genetic parts, along with teams’ analysis of the importance of each assay.  The survey also gathered assurance from each team that a datasheet is an effective way to standardize characterization data in the registry.  
-
 
+
<break></break>
To extend our collaboration efforts beyond emails, we video-conferenced with as many teams as possible, which turned out to be 28 teams.  During the videoconferences, each team reviewed our initial draft of the datasheet.  Some iGEM teams have a more extensive background in performing certain experimental assays than others.  Collectively, we were able to gather the necessary information that pertains to many common assays used to characterize genetic parts.  These videoconferences provided us with invaluable information so that we could construct a versatile datasheet template that is applicable to a broad range of genetic parts.  
To extend our collaboration efforts beyond emails, we video-conferenced with as many teams as possible, which turned out to be 28 teams.  During the videoconferences, each team reviewed our initial draft of the datasheet.  Some iGEM teams have a more extensive background in performing certain experimental assays than others.  Collectively, we were able to gather the necessary information that pertains to many common assays used to characterize genetic parts.  These videoconferences provided us with invaluable information so that we could construct a versatile datasheet template that is applicable to a broad range of genetic parts.  
-
 
+
<break></break>
After videoconferencing with each team, we sent out a final survey to each of the collaborating teams, asking for a follow-up evaluation of our draft of the datasheet template as well as any more information on experimental assays.  We then created a proof-of-concept software to asses the feasibility of implementing this and the capabilities of different programming languages to create this template datasheet submission system.  With limited knowledge in computer programming, the Purdue Team collaborated with the Boston University iGEM Team, who focused more on the technical development of the application and the implementation aspects of the project.
After videoconferencing with each team, we sent out a final survey to each of the collaborating teams, asking for a follow-up evaluation of our draft of the datasheet template as well as any more information on experimental assays.  We then created a proof-of-concept software to asses the feasibility of implementing this and the capabilities of different programming languages to create this template datasheet submission system.  With limited knowledge in computer programming, the Purdue Team collaborated with the Boston University iGEM Team, who focused more on the technical development of the application and the implementation aspects of the project.
-
 
+
<break></break>
Each phase in our collaboration process brought us one step closer to achieving the versatile datasheet that we aimed for.  With the broad experience ranges and knowledge of those that we collaborated with, the overall goal was to create datasheet that is simple to use and adaptable to all different types of genetic parts.  After collaborating with 79 iGEM Teams, the Purdue team feels as though they have successfully created a standardized datasheet system thus constructed a feasible method to standardize the presentation of genetic part information in the Registry.
Each phase in our collaboration process brought us one step closer to achieving the versatile datasheet that we aimed for.  With the broad experience ranges and knowledge of those that we collaborated with, the overall goal was to create datasheet that is simple to use and adaptable to all different types of genetic parts.  After collaborating with 79 iGEM Teams, the Purdue team feels as though they have successfully created a standardized datasheet system thus constructed a feasible method to standardize the presentation of genetic part information in the Registry.

Revision as of 00:44, 23 September 2013


PurdueLogo2013.png

Characterization Collaboration

The genetic parts in the “Registry of Standardized Parts” are standardized; however, there is currently no standard method to present the information for each part. This year the Purdue iGEM team has set out to create standardized data sheets for the Registry. Standardized data sheets will enable synthetic biologists to gain maximum benefits of and fully understand each genetic part to facilitate future usage. This web-based template system to submit and present genetic part characterization data will promote consistent presentation of information, enabling ease of use. Although the Purdue iGEM Team is the face behind the standardized datasheet creation, this endeavor could not have been completed without the help of the 79 other iGEM teams that we collaborated with. This large-scale collaboration is unprecedented in the history of the iGEM competition. With a global collaboration of teams in 15 countries, we combined the knowledge and perspectives of numerous synthetic biologists with broad ranges of experience to create the most universal and appropriate datasheet. There were many phases to this collaboration process, and teams participated in the collaboration to different extents. We initiated the collaboration process by gathering contact information of as many iGEM teams as possible. With that information, an initial survey was sent to individuals of each team to assess levels of interest and outline our general plan. This survey asked teams to address problems with the current Registry system and to establish which teams were interested in officially collaborating with the Purdue team. A second survey was then sent out to those teams interested in collaborating, asking which assays each team is capable of performing to characterize genetic parts, along with teams’ analysis of the importance of each assay. The survey also gathered assurance from each team that a datasheet is an effective way to standardize characterization data in the registry. To extend our collaboration efforts beyond emails, we video-conferenced with as many teams as possible, which turned out to be 28 teams. During the videoconferences, each team reviewed our initial draft of the datasheet. Some iGEM teams have a more extensive background in performing certain experimental assays than others. Collectively, we were able to gather the necessary information that pertains to many common assays used to characterize genetic parts. These videoconferences provided us with invaluable information so that we could construct a versatile datasheet template that is applicable to a broad range of genetic parts. After videoconferencing with each team, we sent out a final survey to each of the collaborating teams, asking for a follow-up evaluation of our draft of the datasheet template as well as any more information on experimental assays. We then created a proof-of-concept software to asses the feasibility of implementing this and the capabilities of different programming languages to create this template datasheet submission system. With limited knowledge in computer programming, the Purdue Team collaborated with the Boston University iGEM Team, who focused more on the technical development of the application and the implementation aspects of the project. Each phase in our collaboration process brought us one step closer to achieving the versatile datasheet that we aimed for. With the broad experience ranges and knowledge of those that we collaborated with, the overall goal was to create datasheet that is simple to use and adaptable to all different types of genetic parts. After collaborating with 79 iGEM Teams, the Purdue team feels as though they have successfully created a standardized datasheet system thus constructed a feasible method to standardize the presentation of genetic part information in the Registry.