How to grow a human lung

Public Release: 24-Mar-2015

Embryonic stem cells

Proteins involved in lung development

Growth factors

Inhibitors of intestine development

Growing media

Petri dish

Protein mixture

Scientists from the University of Michigan have grown the first 3D mini lungs from stem cells. The study, published in eLife, compliments other developments in the field such as growing mainly 2D structures and building lung tissue from the scaffold of donated organs.

The advantage of growing 3D structures is that their organisation bears greater similarity to the human lung. The scientists succeeded in growing structures resembling both the large proximal airways and the small distal airways

Lead author Dr Jason Spence says:

“We expected different cells types to form, but their organisation into structures resembling human airways surprised us and is a very exciting result.”

Ingredients

    Embryonic stem cells

    Proteins involved in lung development

    Growth factors

    Inhibitors of intestine development

    Growing media

    Petri dish

    Protein mixture

Method for “morphogenesis in a dish”

First, add protein ActivinA to stem cells and leave for four days. A type of tissue called endoderm will form. Endoderm is found in early embryos and gives rise to the lung, liver and several other internal organs.

Add Noggin, another protein, and a transforming growth factor. Leave for another four days. You will find the endoderm is induced to form 3D spherical structures called the foregut spheroids.

The next challenge is to make these structures expand and develop into lung tissue by exposing the cells to proteins involved in lung development.

Transfer spheroids to protein mixture and incubate at room temperature for 10 minutes until the mixture solidifies. Treat with additional proteins every four days and transfer into a new protein mixture every 10-15 days.

The resulting lung organoids should survive in culture for over 100 days and develop into well-organised structures containing cell types found in the lung. You will find the lung organoids are self-organizing, and do not require further manipulation to generate 3-dimensional tissues.

Previous studies have focused on forming the outer tissue of the lung (the epithelium). With this new method, you will be able to go one step further by also creating connective tissue (mesenchyme). In a more recent study, distal airway tissue was formed, which gives rise to the small airways less than 2mm in diameter. With the new method, cells of the large proximal airways also form, enabling more complete study of lung development and lung diseases.

Additional options:

Add the foregut spheroids to a lung scaffold from a human lung – use one deemed unsuitable for transplantation. On this scaffold, uou will find the organoids mature faster.

To study genetic disorders that affect lung development, produce stem cell lines from affected patients or introduce mutations to healthy cells. This will allow you to observe how a mutation affects cell differentiation, tissue organization, and tissue growth.

Future developments:

Since these structures were developed in a dish, they are lacking several components of the native lung, including blood vessels, which are a critical component of gas exchange.

We hope to build on our initial findings to build increasingly complex mini-lungs by adding these components, eventually forming tiny organs able to perform functions related to breathing.

###

Reference

The paper ‘In vitro generation of human pluripotent stem cell derived lung organoids’ can be freely accessed online at http://dx.doi.org/10.7554/eLife.05098. Contents, including text, figures, and data, are free to re-use under a CC BY 4.0 license.

Media contact

Jennifer Mitchell, eLife
j.mitchell@elifesciences.org
+44 (0) 1223 855 373

About eLife Sciences Publications Ltd

eLife is a unique collaboration between the funders and practitioners of research to improve the way important research is selected, presented, and shared. eLife publishes outstanding works across the life sciences and biomedicine — from basic biological research to applied, translational, and clinical studies. eLife is supported by the Howard Hughes Medical Institute, the Max Planck Society, and the Wellcome Trust. Learn more at elifesciences.org.

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Categories: . Defensive Medicine

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