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Researchers have developed a scaffold using 3-D bioprinting that slowly releases antibiotics, offering the hope of revolutionizing treatment of diabetic foot ulcers.
Diabetes is among the top 10 causes of deaths worldwide, and in the United Kingdom more than 4.9 million people have diabetes, according to Diabetes UK, who said that “if nothing changes, we predict that 5.5 million people will have diabetes in the UK by 2030.”
Diabetic foot ulcers affect approximately one in four diabetic patients. Standard therapies, such as pressure offloading and infection management, are often unsuccessful alone and require the introduction of advanced therapies, such as hydrogel wound dressings, which further increases treatment costs and requires hospitalization, highlighted the authors of the study, 3D bioprinted scaffolds for diabetic wound-healing applications.
they said.
Drug-loaded scaffold
In their study, published in the journal Drug Delivery and Translational Research, and being presented at the Controlled Release Society Workshop, Italy, this week, researchers from Queen’s University Belfast explained that the treatment strategy required for the effective healing of diabetic foot ulcers is a “complex process” requiring several combined therapeutic approaches. As a result, there is a “significant clinical and economic burden” associated with treating diabetic foot ulcers, they said, and these treatments are often unsuccessful, commonly resulting in lower-limb amputation.
Diabetes UK pointed out that diabetes leads to almost 9,600 leg, toe, or foot amputations every year – “That’s 185 a week,” the charity emphasized.
Recent research has focused on drug-loaded scaffolds to treat diabetic foot ulcers. The scaffold structure is a novel carrier for cell and drug delivery that enhances wound healing, explained the authors.
Dimitrios Lamprou, PhD, professor of biofabrication and advanced manufacturing, Queen’s School of Pharmacy, and corresponding author, explained: “These scaffolds are like windows that enable doctors to monitor the healing constantly. This avoids needing to remove them constantly, which can provoke infection and delay the healing process.”
Low-cost treatment alternative
For their proof-of-concept investigation, the researchers made 3-D–bioprinted scaffolds with different designs – honeycomb, square, parallel, triangular, double-parallel – to be used for the sustained release of levofloxacin to the diabetic foot ulcer.
“The ‘frame’ has an antibiotic that helps to ‘kill’ the bacteria infection, and the ‘glass’ that can be prepared by collagen/sodium alginate can contain a growth factor to encourage cell growth. The scaffold has two molecular layers that both play an important role in healing the wound,” explained Dr. Lamprou.
The authors highlighted that square and parallel designs were created to improve flexibility, and that the repeating unit nature of this scaffold would also allow the scaffold to be easily cut to the required size in order to reduce clinical wastage. The triangular and double-parallel designs were created to decrease the available surface area, and the double-parallel design was composed by repeating units to also meet the same clinical benefits.
“This proof of concept study demonstrates the innovative potential of bioprinting technologies in fabrication of antibiotic scaffolds for the treatment of diabetic foot ulcers,” said the authors. The chosen scaffold design provided sustained release of antibiotic over 4 weeks to infected diabetic foot ulcers, demonstrated suitable mechanical properties for tissue engineering purposes, and can be easily modified to the size of the wound, they said.
Katie Glover, PhD, Queen’s School of Pharmacy, lead author, said: “Using bioprinting technology, we have developed a scaffold with suitable mechanical properties to treat the wound, which can be easily modified to the size of the wound.”
She added that this provides a “low-cost alternative” to current treatments for diabetic foot ulcers, which could “revolutionize” their treatment. Moreover, it could improve patient outcomes while reducing the economic burden on health services, she said.
A version of this article first appeared on Medscape UK.
Researchers have developed a scaffold using 3-D bioprinting that slowly releases antibiotics, offering the hope of revolutionizing treatment of diabetic foot ulcers.
Diabetes is among the top 10 causes of deaths worldwide, and in the United Kingdom more than 4.9 million people have diabetes, according to Diabetes UK, who said that “if nothing changes, we predict that 5.5 million people will have diabetes in the UK by 2030.”
Diabetic foot ulcers affect approximately one in four diabetic patients. Standard therapies, such as pressure offloading and infection management, are often unsuccessful alone and require the introduction of advanced therapies, such as hydrogel wound dressings, which further increases treatment costs and requires hospitalization, highlighted the authors of the study, 3D bioprinted scaffolds for diabetic wound-healing applications.
they said.
Drug-loaded scaffold
In their study, published in the journal Drug Delivery and Translational Research, and being presented at the Controlled Release Society Workshop, Italy, this week, researchers from Queen’s University Belfast explained that the treatment strategy required for the effective healing of diabetic foot ulcers is a “complex process” requiring several combined therapeutic approaches. As a result, there is a “significant clinical and economic burden” associated with treating diabetic foot ulcers, they said, and these treatments are often unsuccessful, commonly resulting in lower-limb amputation.
Diabetes UK pointed out that diabetes leads to almost 9,600 leg, toe, or foot amputations every year – “That’s 185 a week,” the charity emphasized.
Recent research has focused on drug-loaded scaffolds to treat diabetic foot ulcers. The scaffold structure is a novel carrier for cell and drug delivery that enhances wound healing, explained the authors.
Dimitrios Lamprou, PhD, professor of biofabrication and advanced manufacturing, Queen’s School of Pharmacy, and corresponding author, explained: “These scaffolds are like windows that enable doctors to monitor the healing constantly. This avoids needing to remove them constantly, which can provoke infection and delay the healing process.”
Low-cost treatment alternative
For their proof-of-concept investigation, the researchers made 3-D–bioprinted scaffolds with different designs – honeycomb, square, parallel, triangular, double-parallel – to be used for the sustained release of levofloxacin to the diabetic foot ulcer.
“The ‘frame’ has an antibiotic that helps to ‘kill’ the bacteria infection, and the ‘glass’ that can be prepared by collagen/sodium alginate can contain a growth factor to encourage cell growth. The scaffold has two molecular layers that both play an important role in healing the wound,” explained Dr. Lamprou.
The authors highlighted that square and parallel designs were created to improve flexibility, and that the repeating unit nature of this scaffold would also allow the scaffold to be easily cut to the required size in order to reduce clinical wastage. The triangular and double-parallel designs were created to decrease the available surface area, and the double-parallel design was composed by repeating units to also meet the same clinical benefits.
“This proof of concept study demonstrates the innovative potential of bioprinting technologies in fabrication of antibiotic scaffolds for the treatment of diabetic foot ulcers,” said the authors. The chosen scaffold design provided sustained release of antibiotic over 4 weeks to infected diabetic foot ulcers, demonstrated suitable mechanical properties for tissue engineering purposes, and can be easily modified to the size of the wound, they said.
Katie Glover, PhD, Queen’s School of Pharmacy, lead author, said: “Using bioprinting technology, we have developed a scaffold with suitable mechanical properties to treat the wound, which can be easily modified to the size of the wound.”
She added that this provides a “low-cost alternative” to current treatments for diabetic foot ulcers, which could “revolutionize” their treatment. Moreover, it could improve patient outcomes while reducing the economic burden on health services, she said.
A version of this article first appeared on Medscape UK.
Researchers have developed a scaffold using 3-D bioprinting that slowly releases antibiotics, offering the hope of revolutionizing treatment of diabetic foot ulcers.
Diabetes is among the top 10 causes of deaths worldwide, and in the United Kingdom more than 4.9 million people have diabetes, according to Diabetes UK, who said that “if nothing changes, we predict that 5.5 million people will have diabetes in the UK by 2030.”
Diabetic foot ulcers affect approximately one in four diabetic patients. Standard therapies, such as pressure offloading and infection management, are often unsuccessful alone and require the introduction of advanced therapies, such as hydrogel wound dressings, which further increases treatment costs and requires hospitalization, highlighted the authors of the study, 3D bioprinted scaffolds for diabetic wound-healing applications.
they said.
Drug-loaded scaffold
In their study, published in the journal Drug Delivery and Translational Research, and being presented at the Controlled Release Society Workshop, Italy, this week, researchers from Queen’s University Belfast explained that the treatment strategy required for the effective healing of diabetic foot ulcers is a “complex process” requiring several combined therapeutic approaches. As a result, there is a “significant clinical and economic burden” associated with treating diabetic foot ulcers, they said, and these treatments are often unsuccessful, commonly resulting in lower-limb amputation.
Diabetes UK pointed out that diabetes leads to almost 9,600 leg, toe, or foot amputations every year – “That’s 185 a week,” the charity emphasized.
Recent research has focused on drug-loaded scaffolds to treat diabetic foot ulcers. The scaffold structure is a novel carrier for cell and drug delivery that enhances wound healing, explained the authors.
Dimitrios Lamprou, PhD, professor of biofabrication and advanced manufacturing, Queen’s School of Pharmacy, and corresponding author, explained: “These scaffolds are like windows that enable doctors to monitor the healing constantly. This avoids needing to remove them constantly, which can provoke infection and delay the healing process.”
Low-cost treatment alternative
For their proof-of-concept investigation, the researchers made 3-D–bioprinted scaffolds with different designs – honeycomb, square, parallel, triangular, double-parallel – to be used for the sustained release of levofloxacin to the diabetic foot ulcer.
“The ‘frame’ has an antibiotic that helps to ‘kill’ the bacteria infection, and the ‘glass’ that can be prepared by collagen/sodium alginate can contain a growth factor to encourage cell growth. The scaffold has two molecular layers that both play an important role in healing the wound,” explained Dr. Lamprou.
The authors highlighted that square and parallel designs were created to improve flexibility, and that the repeating unit nature of this scaffold would also allow the scaffold to be easily cut to the required size in order to reduce clinical wastage. The triangular and double-parallel designs were created to decrease the available surface area, and the double-parallel design was composed by repeating units to also meet the same clinical benefits.
“This proof of concept study demonstrates the innovative potential of bioprinting technologies in fabrication of antibiotic scaffolds for the treatment of diabetic foot ulcers,” said the authors. The chosen scaffold design provided sustained release of antibiotic over 4 weeks to infected diabetic foot ulcers, demonstrated suitable mechanical properties for tissue engineering purposes, and can be easily modified to the size of the wound, they said.
Katie Glover, PhD, Queen’s School of Pharmacy, lead author, said: “Using bioprinting technology, we have developed a scaffold with suitable mechanical properties to treat the wound, which can be easily modified to the size of the wound.”
She added that this provides a “low-cost alternative” to current treatments for diabetic foot ulcers, which could “revolutionize” their treatment. Moreover, it could improve patient outcomes while reducing the economic burden on health services, she said.
A version of this article first appeared on Medscape UK.
FROM DRUG DELIVERY AND TRANSLATIONAL RESEARCH