Georgia Tech’s SimTigrate Design Lab and Dräger, an international supplier of medical and safety technology, have released a white paper that sets out to demonstrate the advantages for Intensive Care Units in hospitals of ceiling-mounted beam systems over traditional headwall systems or those operated with articulated arms or overhead booms.
One of this paper’s stated purposes is to understand how medical teams evaluate architectural solutions to medical gas delivery, and to compare user experiences with different overhead utilities in the ICU. Its opinions are based primarily on field observations of the use of booms in three hospitals, interviews with staff in other ICUs who have used the beam system, and a simulation conducted in a low-fidelity mockup with nurses, physicians and respiratory therapists from a hospital undergoing a renovation of its ICU patient rooms.
The paper is also a full-throated endorsement of Dräger’s beam system for ICUs, although it does not delve into cost comparisons among different delivery systems.
The paper observes that operating rooms in most hospitals already favor ceiling-mounted systems to deliver medical gases and supply power. As more patient care is provided at the bedside within ICUs, hospitals have replicated overhead service delivery solutions in those units to realize the same advantages of improved access to the head of the bed.
“Yet it is important to keep in mind that ICU rooms do not function exactly like operating rooms, and therefore may have different needs,” the paper states.
The white paper spells out the disadvantages of headwalls in ICUs (space, patient and equipment access, mobility). It also provides a number of reasons why overhead booms aren’t optimal, either.
For example, while overhead booms free up floor space, “they are quite large and take up a lot of real estate in the patient room.” Due to limited space in most inpatient rooms, nurses routinely have to move both boom arms out of the way to move patients into or out of the room.
The flexibility of articulated boom arms has a downside, too, in that the arms can block critical views of such things as monitors.
Perhaps the biggest disadvantage of booms operating overhead is that they impede the use of patient lifts, because the range of a cross bar is limited by the boom and requires that the boom arms are pushed all the way forward, and the bed be moved further away from the wall, to gain access to the patient’s center of gravity.
These illustrations compare patient access when an ICU room is equipped with a Ponta beam system (top) versus an articulated arm system. The Georgia Tech white paper says the biggest disadvantage of booms operating overhead or to the side of the bed is that they impede the use of patient lifts, because the range of a cross bar is limited by the boom and requires that the boom arms are pushed all the way forward, and the bed be moved further away from the wall, to gain access to the patient’s center of gravity. Image: “Comparison of Overhead Utility Systems for Intensive Care Rooms.”
The bulk of this white paper is devoted to demonstrating the advantages of Dräger’s Ponta overhead beam system within an ICU environment.
It states that the Ponta beam takes up less space than an overhead boom, which is important for smaller inpatient rooms. The beam system allows nurses to move the shuttles (columns that suspend from the beam) laterally to come closer together to support infants in incubators or patients in chairs; or farther apart to support bariatric patients.
The columns are customizable for the specific needs of the ICU clinic and standardized across all rooms, such that the ventilator is always on the same side of the patient bed. The beam system allows staff to move the bed in and out of the room easier.
To back up its claims, Georgia Tech, with support from Dräger, the architectural firm HKS, and Grady Health System, conducted three simulation sessions on the Grady’s campus in downtown Atlanta to give the nurses, providers, and facility leadership an opportunity to try out the Ponta beam under real-life care situations.
A critical care doctor with Grady scripted a complex patient scenario that required bulky equipment, access to the head of the bed, and placed many people in the room.
The participants included nurses, doctors, and leadership from Grady’s medical ICU, as well as nurses from the Marcus Stroke and Neurosciences Center who were familiar with using a boom and could compare the performance of different delivery systems.
The 15 simulation participants who completed surveys rated the Ponta system positively in all categories. A dozen agreed or strongly agreed that the beam reduced clutter around the bed; 13 agreed or strongly agreed that the beam better organizes equipment, and 11 agreed or strongly agreed that the beam system is better for managing cables.
Clear majorities of participants also judged the beam system superior to overhead boom systems for providing better access to the patient and to gases and equipment, and better visibility to monitors.
“It is clear that ceiling-mounted solutions for delivery of utilities are far superior than the traditional headwall,” the report states. But unlike overhead boom systems, which were designed originally for operating rooms, Dräger’s Ponta beam system is specifically desgined for smaller inpatient room. The beam system also minimizes bulky infrastructure directly over the patient.
Perhaps the biggest advantage of the Ponta beam is that because it is not mounted directly over the center of the bed, that space is available for overhead patient lift tracks, making the patient lift more effective and easier to operate, which results in more frequent use.
Related Stories
| May 20, 2013
Jones Lang LaSalle: All U.S. real estate sectors to post gains in 2013—even retail
With healthier job growth numbers and construction volumes at near-historic lows, real estate experts at Jones Lang LaSalle see a rosy year for U.S. commercial construction.
| May 9, 2013
Post-tornado Greensburg, Kan., leads world in LEED-certified buildings per capita
Six years after a tornado virtually wiped out the town, Greensburg, Kan., is the world's leading community in LEED-certified buildings per capita.
| May 1, 2013
Groups urge Congress: Keep energy conservation requirements for government buildings
More than 350 companies urge rejection of special interest efforts to gut key parts of Energy Independence and Security Act
| May 1, 2013
World’s tallest children’s hospital pushes BIM to the extreme
The Building Team for the 23-story Lurie Children’s Hospital in Chicago implements an integrated BIM/VDC workflow to execute a complex vertical program.
| Apr 30, 2013
Tips for designing with fire rated glass - AIA/CES course
Kate Steel of Steel Consulting Services offers tips and advice for choosing the correct code-compliant glazing product for every fire-rated application. This BD+C University class is worth 1.0 AIA LU/HSW.
| Apr 30, 2013
Healthcare lighting innovation: Overhead fixture uses UV to kill airborne pathogens
Designed specifically for hospitals, nursing homes, child care centers, and other healthcare facilities where infection control is a concern, the Arcalux Health Risk Management System (HRMS) is an energy-efficient lighting fixture that doubles as a germ-killing machine.
| Apr 24, 2013
North Carolina bill would ban green rating systems that put state lumber industry at disadvantage
North Carolina lawmakers have introduced state legislation that would restrict the use of national green building rating programs, including LEED, on public projects.
| Apr 24, 2013
Los Angeles may add cool roofs to its building code
Los Angeles Mayor Antonio Villaraigosa wants cool roofs added to the city’s building code. He is also asking the Department of Water and Power (LADWP) to create incentives that make it financially attractive for homeowners to install cool roofs.
| Apr 10, 2013
ASHRAE publishes second edition to HVAC manual for healthcare facilities
The American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) has published a second edition of its “HVAC Design Manual for Hospitals and Clinics.”