Home
Our Company
About
Why Bridge PTS?
Getting Started
Collaborators
Licenses
BRIDGE PTS Cited Publications
Services
Wound Healing
Infection Control & Biofilms
Customized Surgical Work
Our Facility
Posters
Events
Blog
Contact Us
Search

Bridge PTS

Home
Our Company
About
Why Bridge PTS?
Getting Started
Collaborators
Licenses
BRIDGE PTS Cited Publications
Services
Wound Healing
Infection Control & Biofilms
Customized Surgical Work
Our Facility
Posters
Events
Blog
Contact Us
Search
  • Wound Healing Testing
  • Pig Acute Wound Healing
  • Pig Delayed Wound Healing
  • Pig Infected Wound Healing
  • Pig Debridement Effectiveness
  • Pig Acute Thermal Injury Healing
  • Pig Infected Thermal Injury Healing
  • Pig Scarring and Scarring Reduction
  • Goat Infected Bone Healing
  • Rat Infected Bone Healing
  • Rabbit Bone Allograft
  • Tensile Testing (WH)
  • Rabbit Femur Defect
  • Rabbit Sidewall (cecal) Adhesion
  • Walker-Mason Burn and Infection Model
  • Rat Ischemic Wound Healing
  • Rat Franz-Robson Laparotomy Model
  • Pig Anastomosis Model

Pig Debridement Effectiveness

  • Duration of study – 21 days

  • Lead time – 30 days

  • Standard results – Wound size measurements, Microbiology, Histology

Model Utility:

This thermal injury model is used to screen thermal injury debridement products and medical devices for effectiveness and safety. 

How the Model Works:

In this model, 2nd or 3rd degree burns are made on the dorsal thorax of the animal.  The size and number of wounds created can vary based on the needs of the experiment; however, the standard number and size of wounds are 20, 2.0 cm diameter wounds per animal. 

The wounds may then be treated with the experimental agent or medical device. These can be in the form of a liquid, gel, powder, or solid (typically cut to wound size).  The wounds will then be bandaged with an appropriate bandage for the type of material used and allowed to heal for typically 14 to 28 days.  The wounds will be measured and assessed twice per week. Treatments may be applied as often as once per day.

At the end of the protocol, the animal is euthanized and the burned area is collected for histological or other analysis.

Example Data:

Figure 1.  A comparison of median visual assessments of eschar formation of acute thermal injuries.  Three concentrations of the same material were compared to a non-treated control.

Figure 1.  A comparison of median visual assessments of eschar formation of acute thermal injuries.  Three concentrations of the same material were compared to a non-treated control.

Advantages:

This model is considered to very closely approximate human thermal injury healing.  BRIDGE PTS has considerable experience and familiarity with this model.   Due to the spacing of the wound on the animal, multiple test materials can be tested on a single animal.  This could allow for higher throughput screening.

This model can be used to assess wound healing.  See Pig Acute Thermal Injury Healing.

This model can also be performed with infection! See Pig Infected Thermal Injury Healing.

Disadvantages:

If multiple test materials are placed on a single animal, it is difficult or impossible to assess systemic effects that the materials may have.   

Although 2nd degree burns are included in this model, the severity of burn can be difficult to control.

References:

  1. Telgenhoff D, Lam K, Ramsay S, Vasquez V, Villareal K, Slusarewicz P, Attar P, Shroot B. Influence of papain urea copper chlorophyllin on wound matrix remodeling. Wound Repair Regen. 2007 Sep-Oct;15(5):727-35

Back to Top

BRIDGE PTS, Inc., Brooks City-Base, San Antonio, TX 78235, P: 210-532-7344