. 2020 Mar 2;41(7):911–927. doi: 10.1038/s41401-020-0372-z

Table 1.

Characteristics of selected delivery strategies for cancer immunotherapies

Delivery technology	Classes of immunotherapy	Advantages	Limitations
In vivo nanoparticle delivery to immune cells	• Cytokines • Checkpoint inhibitors • Agonistic antibodies • Engineered T cells	• Surface functionalization with targeting agents • Localized delivery • Cargo protection	• Premature drug release • Nanoparticle stability • Delivery to off-target clearance organs • Systemic toxicity
Ex vivo T-cell functionalization with nanoparticles	• Cytokines • Vaccines • Engineered T cells	• Innate tumor infiltration • Improved drug delivery • Can be engineered ex vivo or in vivo	• Long production time • Short drug release profiles • Cell death after administration • Complex manufacturing
Controlled release systems	• Cytokines • Checkpoint inhibitors • Agonistic antibodies	• Extended therapy timeline • Cargo protection • Low required doses • Localized delivery following intravenous injection	• Difficult to control release profiles • Toxicities from off-target release • Potentially require surgical implantation • Acidification can degrade cargo
Biomaterial implant scaffolds	• Cytokines • Vaccines • Engineered T cells	• In situ dendritic cell activation • Delivery of dendritic cell attractants • Implant functionalization with antigen • Controlled release profiles • Provides physical structure for cells	• Potential toxicity from the implant material • Need to define specific antigens • Potential rejection of loaded adjuvant • Requires surgery
Injectable biomaterial scaffolds	• Cytokines • Checkpoint inhibitors • Neoantigens	• Minimally invasive • No surgery required • Controlled release of loaded cargo • Delivery directly to the tumor	• Early stages of development • Requires extensive characterization for biodegradation profile • May require large gauge needle
Transdermal delivery systems	• Checkpoint inhibitors • Neoantigens	• Sustained release • Low required doses • Local delivery directly to the tumor • Minimally invasive • Bio-responsive	• Small treatment area • Bioavailability and biocompatibility are unknown • Can be used only for tumors close to the skin • Complex manufacturing

Delivery technology

Classes of immunotherapy

Advantages

Limitations

In vivo nanoparticle delivery to immune cells

• Cytokines

• Checkpoint inhibitors

• Agonistic antibodies

• Engineered T cells

• Surface functionalization with targeting agents

• Localized delivery

• Cargo protection

• Premature drug release

• Nanoparticle stability

• Delivery to off-target clearance organs

• Systemic toxicity

Ex vivo T-cell functionalization with nanoparticles

• Cytokines

• Vaccines

• Engineered T cells

• Innate tumor infiltration

• Improved drug delivery

• Can be engineered ex vivo or in vivo

• Long production time

• Short drug release profiles

• Cell death after administration

• Complex manufacturing

Controlled release systems

• Cytokines

• Checkpoint inhibitors

• Agonistic antibodies

• Extended therapy timeline

• Cargo protection

• Low required doses

• Localized delivery following intravenous injection

• Difficult to control release profiles

• Toxicities from off-target release

• Potentially require surgical implantation

• Acidification can degrade cargo

Biomaterial implant scaffolds

• Cytokines

• Vaccines

• Engineered T cells

• In situ dendritic cell activation

• Delivery of dendritic cell attractants

• Implant functionalization with antigen

• Controlled release profiles

• Provides physical structure for cells

• Potential toxicity from the implant material

• Need to define specific antigens

• Potential rejection of loaded adjuvant

• Requires surgery

Injectable biomaterial scaffolds

• Cytokines

• Checkpoint inhibitors

• Neoantigens

• Minimally invasive

• No surgery required

• Controlled release of loaded cargo

• Delivery directly to the tumor

• Early stages of development

• Requires extensive characterization for biodegradation profile

• May require large gauge needle

Transdermal delivery systems

• Checkpoint inhibitors

• Neoantigens

• Sustained release

• Low required doses

• Local delivery directly to the tumor

• Minimally invasive

• Bio-responsive

• Small treatment area

• Bioavailability and biocompatibility are unknown

• Can be used only for tumors close to the skin

• Complex manufacturing

Reprinted with permission from [2]