BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 Lecture 6: Programmed/Pulsed Drug Delivery and Drug Delivery in Tissue Engineering Last time principles of controlled release from solid polymers Today Pulsatile/regulated/ multifactor controlled release 3 case studies of controlled release Reading Polymeric system for dual growth factor delivery, T.P. Richardson et al., Nat. Biotech 9,1029-1034(2001) Microchips as controlled drug-delivery devices, J.T. Santini et aL., Andegwandte Chemie lnt.Ed.39,23962047(2000) Requlated controlled release Applications of regulated and pulsatile release Many applications would be best-served by non-monotonic and multi-cargo release profiles oral pattern Definition: release of cargo in bursts followed by periods of little/no release in a defined ten o Motivation Single injection delivery of booster for vaccination Mimic natural secretion patterns of hormones Provide optimal therapy for tolerance-inducing drugs Constant drug levels cause receptor down-regulation accine boosting hormone release patterns in vivo mples of acted from a review article by Brabant et al. (Reference 7) references cited in the review artie Hormone w Pulses/Dav Growth hormo 4-9.7-2 Thyroid stimulating hormone 15.90-121 stimulating hormone 18-24,12-20.0 C 08-144.120 100 03,144 Progesterone 020406080100120140 Testosterone 13.8-12 Aldosterone Time in trial. weeks optisol Lecture 5- Programmed Drug Delivery 1 of 12
BEH.462/3.962J Molecular Principles of Biomaterials Spring 2003 Lecture 6: Programmed/Pulsed Drug Delivery and Drug Delivery in Tissue Engineering Last time: principles of controlled release from solid polymers Today: Pulsatile/regulated/multifactor controlled release: 3 case studies of controlled release Reading: ‘Polymeric system for dual growth factor delivery,’ T.P. Richardson et al., Nat. Biotech. 19, 1029-1034 (2001) ‘Microchips as controlled drug-delivery devices,’ J.T. Santini et al., Andegwandte Chemie Intl. Ed. 39, 2396-2047 (2000) Regulated controlled release Applications of regulated and pulsatile release • Definition: release of cargo in bursts followed by periods of little/no release in a defined temporal pattern1 • Many applications would be best-served by non-monotonic and multi-cargo release profiles o Motivation: Single injection delivery of ‘booster’ for vaccination Mimic natural secretion patterns of hormones Provide optimal therapy for tolerance-inducing drugs • Constant drug levels cause receptor down-regulation Vaccine boosting hormone release patterns in vivo Lecture 5 – Programmed Drug Delivery 1 of 12
BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 Example: HIV-1 DNA vaccine delivered with boosters to elevate Ab titers2 o Mechanical and electrical devices that can provide digitized release typically require larger devices and surgical implantation(e.g Pharm. Res. 1, 237(1984); also have high cost Show an example o Degradable polymers allow submicron, injectable devices · Two types Release profile is encoded in structure and composition of device o Triggered External signal drives release Multilayer surface-eroding delivery devices >drug-loaded PEBP laver NHCHICONHOCOC&Hs )y fN-P o- poly phosphazene (NHCH2COOCH:CHJ PLCA coating p polyanhydride(PSP or PSTP) polylactide block m2.[o是mC ∞xwox,[o CH3 CHa Fast-degrading Polyanhydride block (xy-30: 70 by molar) Hydrophilic PEG block · Polyphosphazene Base-catalyzed degradation, acid-inhibited degradation ·PEG-b- Polyanhydride o Rapid bulk erosion-use hydrophilic block to make hrs-long degradation time for mm-thick caps(very fast o .. becomes porous during erosion, so need a means to prevent next layer from starting to degrade as ater reaches drug-containing layer o creates acidic byproducts as it degrades o First polyphosphazene layer degrades quickly( first burst release) o Polyanhydride layer: degrades quickly, acidifies internal environment Even though water penetrates the polyanhydride. A ne polyanhydride has completely adation of polyphosphazene begins and no drug is released from the polyphosphazene layer until eroded and acidic products are removed from microenvironment Lecture 5- Programmed Drug Delivery 2 of 12
BEH.462/3.962J Molecular Principles of Biomaterials Spring 2003 Example: HIV-1 DNA vaccine delivered with boosters to elevate Ab titers2 : o Mechanical and electrical devices that can provide digitized release typically require larger devices and surgical implantation (e.g. Pharm. Res. 1, 237 (1984)); also have high cost Show an example o Degradable polymers allow submicron, injectable devices • Two types o Pre-programmed Release profile is encoded in structure and composition of device o Triggered External signal drives release Multilayer surface-eroding delivery devices Case study: multilayered delivery devices3 Fast-degrading Polyanhydride block Hydrophilic PEG block polyphosphazene slow-degrading polylactide block • Polyphosphazene: o Base-catalyzed degradation, acid-inhibited degradation • PEG-b-Polyanhydride: o Rapid bulk erosion- use hydrophilic block to make hrs-long degradation time for mm-thick caps (very fast) o …becomes porous during erosion, so need a means to prevent next layer from starting to degrade as water reaches drug-containing layer o creates acidic byproducts as it degrades • Function of complete device: o First polyphosphazene layer: degrades quickly (first burst release) o Polyanhydride layer: degrades quickly, acidifies internal environment Even though water penetrates the polyanhydride, no degradation of polyphosphazene begins and no drug is released from the polyphosphazene layer until the polyanhydride has completely eroded and acidic products are removed from microenvironment Lecture 5 – Programmed Drug Delivery 2 of 12
BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 er acid ifies Water penetrates into device degrades sHow pht Fig. 2. Theoretical pulsatile release of a drug from a surface- oding polymeric system. The time between initial release and booster release is determined by the erosion of the drug free layer refs for theory: J Contr Rel 20, 201(1992); J Cont Rel 18, 159(1992 Regulated release devices: case example-drug delivery microchips work from M. Cima and R. Langer labs Lecture 5- Programmed Drug Delivery 3 of 12
