Original Post: 12/2022 | Revision 2 06/20/24

The use of聽mass timber聽in commercial building projects continues to double in growth each year as a low-carbon, sustainable and light-weight structural material compared to traditional construction materials. Mass timber was already popular in Europe, which accounts for over 60% of the global market for this innovative construction material, but its adoption is now becoming increasingly widespread across North America. According to the Wood Products Council, as of March 2024, 2,115 multi-family, commercial building, and institutional projects featuring mass timber are underway or completed in the United States, reflecting a steady growth trend.

Mass timber is prized by architects, builders and environmentalists alike. When exposed in building designs, the material鈥檚 beauty is immediately apparent. As a structural element, mass timber can meet or even exceed concrete and steel construction performance standards. Its most important benefit, however, is its potential contribution as a climate change solution.

While steel and cement manufacturing are among the world鈥檚 largest sources of carbon emissions, a mass timber-framed building can serve as a carbon sink throughout its lifetime, sequestering carbon absorbed from the atmosphere while the wood was growing in the forest. As long as the building stands, the carbon contained in the wood remains locked in the structure and will not be released into the air.

鈥淐onversations around sustainability in the building industry used to be focused on operational energy, the carbon emissions associated with a building鈥檚 use from heating and cooling, for example,鈥 said Tanya Luthi, director of engineering at Timberlab. 鈥淭hat understanding has evolved to include the full life cycle of a building, including the embodied carbon of the materials used to construct the project. Fortunately, advancements in engineered wood products, such as the development of cross-laminated timber, have coincided with a strong and deepening commitment to sustainable forestry practices, allowing us to use mass timber responsibly at scale from an engineering and a sustainability perspective. Wood is the only major structural material that we can regrow.鈥

Because of these climate benefits, governments and municipalities across the U.S. and worldwide are establishing policies that promote the use of mass timber in new construction. A recent example is New York City鈥檚 Mass Timber Accelerator program, which is piloting the use of mass timber in a series of large-scale construction projects across the city to align with its decarbonization efforts.

At the same time, many jurisdictions are revising building codes to permit the use of mass timber in ways that previously wouldn鈥檛 have been considered. These changes have enabled the construction of revolutionary new buildings like the Ascent in Wisconsin. At 25 stories and 284 feet tall, this residential tower in the heart of Milwaukee鈥檚 downtown is the world鈥檚 tallest hybrid mass timber building.

Despite the rapid growth in enthusiasm for mass timber construction across multiple industries, the healthcare sector has been slower to adopt this climate-friendly material. Concerns about medical space planning, infection control, acoustics and vibration suppression 鈥 among other issues 鈥 have inhibited the healthcare industry鈥檚 transition to mass timber structures.

However, this reluctance is fading as new projects 鈥 including an ambulatory care unit in Sechelt, British Columbia and Northlake Commons, a life sciences laboratory and workspace building in Seattle 鈥 demonstrate mass timber鈥檚 enormous potential to revitalize the construction of healthcare facilities. Besides mass timber鈥檚 obvious environmental benefits, its use is also proven to contribute to patient and employee well-being and bolster the brand reputation of its earliest adopters.

In the months and years to come, it will be increasingly important for leading organizations in the healthcare industry to demonstrate their commitment to the health of the planet and their communities by choosing the building material that best aligns with their mission 鈥 to improve human health.


Among stakeholders in healthcare, as well as a broad array of other industries, there is growing awareness of the climate impact of constructing new buildings and facilities. World Green Building Council estimates that the built environment is responsible for 39% of global carbon emissions. Cement and steel manufacturing industries account for nearly 10% of the world鈥檚 ongoing carbon emissions, a source of carbon dioxide that鈥檚 difficult for societies to eliminate. On average, approximately 2 tons of carbon dioxide are emitted in manufacturing every ton of steel, though this can be reduced somewhat by incorporating scrap into recycled steel production.

In contrast, trees capture and store carbon as they grow 鈥 approximately 1 ton for every cubic meter of growth. By weight, trees are approximately 50% carbon. When trees are harvested, all the carbon that has been sequestered in the wood while they were growing remains there. Once that harvested wood is used in a building that carbon will stay within that structure for as long as the building stands. In essence, mass timber construction projects transfer sequestered carbon from forests to the built environment. Then, new trees are replanted in place of those harvested, capturing and storing yet more carbon.

This fact accounts for the environmental promise of mass timber construction. Mass timber is a renewable resource. Plus, it鈥檚 possible to store embodied carbon within a building for the whole of the structure鈥檚 lifecycle. Research indicates that mass timber construction is approximately 50% more carbon-efficient than steel.

But this is a rule-of-thumb estimate. The actual climate impact of any individual mass timber construction project will be influenced by the forestry, transportation and milling practices employed for the wood used in the project, as well as how the building is disassembled and its materials disposed of at the end of its life cycle.

For a truly sustainable building project, using locally sourced wood from sustainably managed forests is necessary. Not only do intact forest ecosystems sequester more carbon, but they also help protect biodiversity and wild animal habitats. It鈥檚 key to cultivate transparency and accurate tracking in the mass timber supply chain to ensure that building materials are sourced from responsibly managed forests.

For instance, sourcing wood for building projects in the Pacific Northwest from forests in the same region makes sense because it reduces the distance construction materials need to be transported, thereby reducing emissions. This practice also supports the region鈥檚 historically important timber economy and rural communities, which are integral to the timber supply chain.

In addition, it鈥檚 crucial to select timber harvested from timberlands that grow trees to a size large enough to ensure that the maximum rate of carbon sequestration has occurred on those forested lands. Timber producers that exceed state Forest Practices Act guidelines for sustainable forestry practices and watershed health adhere to climate-smarter practices.


To date, mass timber has not been widely used for structural systems in healthcare industry construction projects. This means there are few examples to validate that mass timber can meet healthcare facilities鈥 unique structural requirements. However, research and innovation are underway, and ongoing studies demonstrate that mass timber can meet the strength and performance requirements necessary for its adoption in healthcare.

Buildings in the healthcare sector must meet strict vibration requirements to support the performance of critical operations and sensitive medical equipment. Typically, this means that structures are designed to be stiffer and more robust, adding material and expense to the project. Vibration performance in mass timber buildings can be challenging due to the structure鈥檚 lightweight, so healthcare operators are wondering if mass timber structures can meet the requirements. New vibration analysis tools, coupled with field testing of occupied buildings, have shown that mass timber-framed structures, just like steel structures, can be designed to meet or exceed the vibration criteria for operating and treatment rooms, patient rooms, administrative and public areas, medical offices and lab areas.

Sounds in healthcare environments can range from the beeping of alarms and equipment to the hum of machines and HVAC systems to other people鈥檚 conversations. These can irritate or even harm patients, and transferring these sounds can violate patient privacy required by HIPAA (Health Insurance Portability and Accountability Act). Healthcare facilities require conscious design for strategic sound control, and mass timber elements have lower sound ratings because of their lower mass relative to concrete. For this reason, timber panels are complemented by other materials in a floor assembly that can add mass and ensure noise control. Laboratory tests have shown that mass timber floor assemblies can achieve acoustic performance that meets industry guidelines.

Healthcare facilities have strict surface-cleaning and sanitization requirements, particularly in high-risk areas such as operating rooms and intensive care units. In these areas, surfaces must be resistant to microbial growth and spread, smooth, nonporous and durable enough to withstand repeated cleaning and disinfection. In critical facilities such as surgical suites in mass timber buildings, wood can be encapsulated with materials and finishes that create a sterile and durable surface, like what is done in concrete and steel buildings. In less critical facilities, the wood can be coated with a washable finish.

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There鈥檚 a common misconception that wood is inherently dangerous in fires. However, mass timber is not a lightweight wood frame construction, and like a log in a campfire, mass timber buildings have inherent fire resistance due to their size. Though still a combustible material, mass timber structures are designed and built to achieve the same fire and life safety requirements as non-combustible construction.

In fact, cross-laminated timber and glulam members have demonstrated compliance with local and international building codes. Unlike steel, which will lose strength if it becomes too hot, mass timber building components will incur surface charring but retain strength to sustain design loads. In addition, mass timber beams and columns designed to inhibit floor-to-floor and room-to-room smoke transfer have earned smoke ratings comparable to those of steel structural elements. Fire risks in mass timber buildings can be additionally mitigated with encapsulation or through other compensating measures, such as improved egress design, more reliable and robust suppression systems and early fire detection measures.

In the past, some stakeholders have avoided mass timber because they perceive it as inherently more expensive. While it can be true that there are higher material costs associated with building and framing in mass timber, these costs are generally offset by shorter material lead times, faster structure installation, and a shortened construction schedule overall.

鈥淭imber structures can be built faster, but that is only advantageous when projects are planned and managed correctly. The biggest financial risk in any construction project will always be the labor cost, which is highly dependent on how much time the project takes. Delays are generally more expensive than changing materials, resolving conflicts or altering designs. Mass timber project timelines are more predictable, which makes the capital investment more predictable,鈥 states Erik Benedetti, project manager and healthcare lead at 番茄影视.

Some stakeholders have also avoided using mass timber because of concerns about the cost or availability of insurance. Because this is an emerging technology, not all insurers may understand mass timber鈥檚 performance and benefits. It may be necessary to engage and communicate with your underwriter to help them understand and accurately assess the risks. This issue will almost certainly become rarer as mass timber adoption accelerates.


Healthcare stakeholders increasingly recognize that providing high-quality patient care goes beyond supplying the right medications, technologies and evidence-based therapeutic protocols. Optimizing patient outcomes also requires providing care that respects individuals鈥 preferences, emotional needs and values. It means treating patients in spaces purposefully designed to make occupants feel healthy and safe. In this arena, mass timber construction truly shines.

The aesthetic and design benefits of exposed wood in architecture are already well understood. As award-winning architect Michael Green, who builds mass timber structures in British Columbia, said, wood is 鈥渘ature鈥檚 fingerprint in buildings,鈥 so mass timber has a deeply soothing effect on the buildings鈥 occupants.

Biophilic design is among the latest trends in hospital and healthcare facility design. A growing body of research shows that incorporating natural elements or views of nature in healthcare facilities can improve staff productivity and efficiency while enhancing patients鈥 feelings of well-being, decreasing stress levels and reducing pain levels. Studies have shown that hospital patients whose rooms have views of forested land or water recover more quickly than those with views of a blank wall. They require less pain medication and leave the hospital earlier. Mass timber construction with exposed structural elements can bring that impression of nature into the healthcare facility. Plus, if patients are told the building鈥檚 story, they鈥檒l understand the positive impact its construction has had.

鈥淎wareness of the impact of climate change is growing among patients today,鈥 said Chris Morris, director of national healthcare at 番茄影视. 鈥淜nowing that the building where you鈥檙e receiving care was built from materials that were sourced locally, that are more sustainable and that are contributing to sequestering carbon from the atmosphere is significant for many people. The beauty of mass timber is just one more reason they鈥檇 prefer to receive care in those buildings.鈥

While leading healthcare organizations are designing healthcare spaces to feel welcoming, artful and beautiful rather than sterile or clinical, they鈥檙e also thinking about ways to extend the benefits of design aesthetics to their employees. In a field where record shortages of nurses and other skilled professionals are an acute problem, it鈥檚 particularly important to design employee break rooms and common spaces in ways that are restful and calming to help counter burnout.

Furthermore, patients and employees alike appreciate when a healthcare organization鈥檚 commitment to sustainability and ethical building practices allows it to operate harmoniously with its mission of promoting human health and healing.


Today鈥檚 healthcare organizations face numerous challenges. They must recruit and retain top-notch care providers, deliver high-quality patient care and streamline operations to manage costs. To build thriving practices that will attract patient populations now and continue to do so in the future, they must demonstrate that they care for the minds, bodies and spirits of patients, caregivers, administrators and visitors. This requires more than medical expertise; it also demands vision and the courage to make sustainable and ethical choices.

鈥淭he stakes are high in an industry like healthcare 鈥 we are talking about people鈥檚 lives,鈥 said Luthi. 鈥淲hen the stakes are high, people are often cautious about change, which could be one reason we haven鈥檛 seen mass timber adopted as widely in healthcare as in other sectors. But if you look at it another way, incorporating mass timber into healthcare projects is actually the perfect opportunity to make a positive impact both on the planet and on its people.鈥