In the coming decades, urbanisation is expected to increase considerably. Today, 54 per cent of the world population lives in urban areas. By 2050, this share is forecast to increase to 66 per cent. That equates to an additional 2.4 billion people living in urban centres.[1]

The need to feed these increasing urban populations is placing unprecedented pressure on the agriculture industry. To secure higher productivity, the sector relies upon synthetic fertilisers derived from energy intensive manufacturing methods; the run-off from these fertilisers coupled with the food mileage required for crops to reach our cities is having a devastating environmental impact. In addition, for every 1° increase in atmospheric temperature, 10% of farmland used for crop production will be lost. [2] This destructive cycle impacts consumers, farmers, and the environment.

One way of protecting our crops and the land we use for agriculture is by growing within controlled, contained environments. Growing indoors is already a well-established practice; greenhouses are widely used and guarantee a safer, and more predictable method of growing. By carefully controlling the parameters within these environments, we can artificially create the optimum growth conditions for a specific crop, maximising yield.

The need for sustainable agricultural solutions has never been greater. It is our contention that by combining these artificial and contained growth systems with the efficient use of space in our cities, we may relieve some of the pressure being placed upon the agriculture industry by increasing urban populations – leading the paradigm shift towards an urban future where sustainable agricultural solutions are commonplace.

Newcaslte iGEM 2018 proposes an alternative root.

Governments and local authorities are responsible for providing and upholding essential services for its citizens, this is especially poignant for the provision of food and protection of farmland.

Newcastle City council has recently declared their bold plans to convert Newcastle into a ‘Smart City’. This is an initiative to make the city more connected, becoming a pioneering figure in the digital revolution. They are looking to pursue areas such as ‘smart energy,’ ‘smart mobility,’ and ‘smart screens’ - see the Newcastle smart city diagram below. However, we felt the ambitious plans neglected a ‘smart agriculture’ approach.

As a result, we decided to take on the challenge of designing a ‘smart agriculture’ solution for Newcastle, demonstrating how the city can shift towards a sustainable agricultural model – setting an example for other cities across the globe – in turn, beginning to tackle some of the global issues our iGEM project set out to solve.

To begin, we researched into areas of the city where we feel space is being underutilised, and in which a sustainable food source would have the most impact. After studying the urban agriculture industry and communicating with stakeholders (see timeline below) we found a space that gives access to locations across the city. Newcastle’s Victoria Tunnel; a disused tunnel that was once used to transport coal from the mines down to the river for shipment - as well serving as a bunker during WWII. It runs beneath a variety of urban hubs that would benefit from fresh produce including: Newcastle University, Northumbria University, Royal Victoria Hospital, Student villages, and Business centres (see map below).

As part of our human practices we have conceptualised an architectural design project within the Victoria Tunnel that transforms it into a hydroponic urban farm. This design exercise integrates / was informed by all elements of our project – stakeholder engagement, wetware, hardware, and safety.

Below is the journey we took to design the Victoria Tunnel urban farm:

Step 1: Initial Project Considerations

(LEGISLATION/SAFETY)

Once we had decided upon the initial project idea we knew that we would be working with pants; leading us to look for applications for our product within the agriculture industry. As a result, our project - if successful - would potentially involve releasing our genetically modified bacteria into soil microbial communities – but we were aware this may have undesirable and unforeseen impacts on the rhizosphere too.

To further our understanding of this topic, we began to look at existing legislation surrounding the release of GMO’s and the environment. We read official documentation relating to the use of GMO's in contained environments (GMO LEGISLATION)

Therefore, we highlighted early on the necessity to explore the use of our bacteria in contained environments – this way we have comply with safe project design / responsible innovation standards.

(WETWARE/HARDWARE)

When planning the wetware side of the project and figuring out what experiments we needed to do, it became immediately obvious that there would be a need to develop a device than enables high-throughput experimental outcomes as we are working with plants over a relatively short period of time – this led to the idea of making our own hydroponic system (see hardware)

Once we knew we were searching for applications for our bacteria within the agriculture industry, and that we would be doing so in the context of contained growth environments – we began to line up meetings with relevant stakeholders.

In Summary, we asked our stakeholders about their values and the overwhelming response was a commitment to sustainable agriculture: reducing the carbon footprint of the agriculture industry, reducing the cost of fresh produce to consumers (whilst increasing accessibility), and reducing costs for farmers. Inevitably we felt our bacteria solved the issue of reducing carbon footprint by reducing the demand for fertilisers – but we still needed to find a way in which it could be used to solve some of the other issues raised by stakeholders - such as feeding the increasing urban population.

More detailed information about how the conversations with stakeholders influenced our project can be seen in step 3

Step 1: Initial Project Considerations

(LEGISLATION/SAFETY)

Once we had decided upon the initial project idea we knew that we would be working with pants; leading us to look for applications for our product within the agriculture industry. As a result, our project - if successful - would potentially involve releasing our genetically modified bacteria into soil microbial communities – but we were aware this may have undesirable and unforeseen impacts on the rhizosphere too.

To further our understanding of this topic, we began to look at existing legislation surrounding the release of GMO’s and the environment. We read official documentation relating to the use of GMO's in contained environments (GMO LEGISLATION)

Therefore, we highlighted early on the necessity to explore the use of our bacteria in contained environments – this way we have comply with safe project design / responsible innovation standards.

(WETWARE/HARDWARE)

When planning the wetware side of the project and figuring out what experiments we needed to do, it became immediately obvious that there would be a need to develop a device than enables high-throughput experimental outcomes as we are working with plants over a relatively short period of time – this led to the idea of making our own hydroponic system (see hardware)

Governments and local authorities are responsible for providing and upholding essential services for its citizens, this is especially poignant for the provision of food and protection of farmland.

Newcastle City council has recently declared their bold plans to convert Newcastle into a ‘Smart City’. This is an initiative to make the city more connected, becoming a pioneering figure in the digital revolution. They are looking to pursue areas such as ‘smart energy,’ ‘smart mobility,’ and ‘smart screens’ - see the Newcastle smart city diagram below. However, we felt the ambitious plans neglected a ‘smart agriculture’ approach.

As a result, we decided to take on the challenge of designing a ‘smart agriculture’ solution for Newcastle, demonstrating how the city can shift towards a sustainable agricultural model – setting an example for other cities across the globe – in turn, beginning to tackle some of the global issues our iGEM project set out to solve.

To begin, we researched into areas of the city where we feel space is being underutilised, and in which a sustainable food source would have the most impact. After studying the urban agriculture industry and communicating with stakeholders (see timeline below) we found a space that gives access to locations across the city. Newcastle’s Victoria Tunnel; a disused tunnel that was once used to transport coal from the mines down to the river for shipment - as well serving as a bunker during WWII. It runs beneath a variety of urban hubs that would benefit from fresh produce including: Newcastle University, Northumbria University, Royal Victoria Hospital, Student villages, and Business centres (see map below).

As part of our human practices we have conceptualised an architectural design project within the Victoria Tunnel that transforms it into a hydroponic urban farm. This design exercise integrates / was informed by all elements of our project – stakeholder engagement, wetware, hardware, and safety.

Below is the journey we took to design the Victoria Tunnel urban farm: