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Cory Berkland

Cory Berkland
Professor

4141B Learned Hall 1530 W 15th St
Lawrence, KS 66045
Phone: (785) 864-1455
Fax: (785) 864-4967
E-mail: berkland@ku.edu

 

Education

  • Post Doc Chemical and Biomolecular Engineering - University of Illinois, Urbana 2004
  • PhD Chemical and Biomolecular Engineering - University of Illinois, Urbana May 2003
  • MS Chemical Engineering - University of Illinois, Urbana May 2001
  • BS Chemical Engineering Iowa State University, Ames Dec 1998

Research Interests

 

In recent history, through the merger of engineering and biological sciences, biotechnology has pressed toward improving methods for regenerating tissues, developing biosensors, and effectively delivering therapeutic agents. Accomplishing such tasks requires specifically designing biomedical or drug delivery devices that possess the required physicochemical properties. Our lab focuses on developing precision engineering technologies at the macro- to molecular scale for novel or improved biomedical and drug delivery devices.

Precision Particles

Precisely sized micro- or nanoparticles offer several advantages over conventional particulate drug formulations. Our previous work has established uniform biodegradable particles as a means to control and define the release profile of drugs over time. In addition, specifically modulating microsphere size offers an attractive means to improve drug administration while controlling release. For example, the deep lung can be effectively reached by 1-3 micron particles while 10-20 micron particles can embolize a tumor bed for localized delivery of chemotherapeutics. Finally, the design of microcapsules utilizing a degradable polymeric shell of controlled thickness may provide a novel platform for the development of pulsatile drug release profiles as desired for vaccine formulations

Precision Tissue Scaffolds

The properties of tissue scaffolds, such as overall size/shape, degradability, compression strength, porosity, and surface structure are difficult to control using conventional techniques and need to be specifically tuned depending on the medical application. By combining various device fabrication techniques such as soft lithography, precision particle fabrication, and electrostatic spraying, polymeric devices exhibiting precision macro-, micro-, and nano-structure can be produced. Utilizing these techniques in combination provides biomedical devices exhibiting controlled properties including biodegradable tissue scaffolds with periodic structure.