Your browser doesn't support javascript.
loading
Show: 20 | 50 | 100
Results 1 - 4 de 4
Filter
Add more filters

Therapeutic Methods and Therapies TCIM
Database
Type of study
Language
Affiliation country
Publication year range
1.
Cell Host Microbe ; 31(10): 1574-1592, 2023 10 11.
Article in English | MEDLINE | ID: mdl-37827116

ABSTRACT

Many systemically administered cancer therapies exhibit dose-limiting toxicities that reduce their effectiveness. To increase efficacy, bacterial delivery platforms have been developed that improve safety and prolong treatment. Bacteria are a unique class of therapy that selectively colonizes most solid tumors. As delivery vehicles, bacteria have been genetically modified to express a range of therapies that match multiple cancer indications. In this review, we describe a modular "build-a-bug" method that focuses on five design characteristics: bacterial strain (chassis), therapeutic compound, delivery method, immune-modulating features, and genetic control circuits. We emphasize how fundamental research into gut microbe pathogenesis has created safe bacterial therapies, some of which have entered clinical trials. The genomes of gut microbes are fertile grounds for discovery of components to improve delivery and modulate host immune responses. Future work coupling these delivery vehicles with insights from gut microbes could lead to the next generation of microbial cancer therapy.


Subject(s)
Host Microbial Interactions , Neoplasms , Humans , Synthetic Biology/methods , Neoplasms/therapy
2.
J Immunother Cancer ; 6(1): 78, 2018 08 06.
Article in English | MEDLINE | ID: mdl-30081947

ABSTRACT

In this White Paper, we discuss the current state of microbial cancer therapy. This paper resulted from a meeting ('Microbial Based Cancer Therapy') at the US National Cancer Institute in the summer of 2017. Here, we define 'Microbial Therapy' to include both oncolytic viral therapy and bacterial anticancer therapy. Both of these fields exploit tumor-specific infectious microbes to treat cancer, have similar mechanisms of action, and are facing similar challenges to commercialization. We designed this paper to nucleate this growing field of microbial therapeutics and increase interactions between researchers in it and related fields. The authors of this paper include many primary researchers in this field. In this paper, we discuss the potential, status and opportunities for microbial therapy as well as strategies attempted to date and important questions that need to be addressed. The main areas that we think will have the greatest impact are immune stimulation, control of efficacy, control of delivery, and safety. There is much excitement about the potential of this field to treat currently intractable cancer. Much of the potential exists because these therapies utilize unique mechanisms of action, difficult to achieve with other biological or small molecule drugs. By better understanding and controlling these mechanisms, we will create new therapies that will become integral components of cancer care.


Subject(s)
Bacteria , Biological Therapy/methods , Genetic Vectors , Neoplasms/prevention & control , Neoplasms/therapy , Viruses , Animals , Bacteria/genetics , Biological Therapy/standards , Biological Therapy/trends , Cancer Vaccines/genetics , Cancer Vaccines/immunology , Clinical Studies as Topic , Combined Modality Therapy , Drug Evaluation, Preclinical , Genetic Engineering , Genetic Vectors/genetics , Humans , Neoplasms/etiology , Oncolytic Virotherapy , Treatment Outcome , Viruses/genetics
3.
Biotechnol Bioeng ; 112(11): 2397-405, 2015 Nov.
Article in English | MEDLINE | ID: mdl-25976712

ABSTRACT

Motile bacteria can overcome the transport limitations that hinder many cancer therapies. Active bacteria can penetrate through tissue to deliver treatment to resistant tumor regions. Bacterial therapy has had limited success, however, because this motility is heterogeneous, and within a population many individuals are non-motile. In human trials, heterogeneity led to poor dispersion and incomplete tumor colonization. To address these problems, a swarm-plate selection method was developed to increase swimming velocity. Video microscopy was used to measure the velocity distribution of selected bacteria and a microfluidic tumor-on-a-chip device was used to measure penetration through tumor cell masses. Selection on swarm plates increased average velocity fourfold, from 4.9 to 18.7 µm/s (P < 0.05) and decreased the number of non-motile individuals from 51% to 3% (P < 0.05). The selected phenotype was both robust and stable. Repeating the selection process consistently increased velocity and eliminated non-motile individuals. When selected strains were cryopreserved and subcultured for 30.1 doublings, the high-motility phenotype was preserved. In the microfluidic device, selected Salmonella penetrated deeper into cell masses than unselected controls. By 10 h after inoculation, control bacteria accumulated in the front 30% of cell masses, closest to the flow channel. In contrast, selected Salmonella accumulated in the back 30% of cell masses, farthest from the channel. Selection increased the average penetration distance from 150 to 400 µm (P < 0.05). This technique provides a simple and rapid method to generate high-motility Salmonella that has increased penetration and potential for greater tumor dispersion and clinical efficacy.


Subject(s)
Locomotion , Neoplasms/microbiology , Salmonella/physiology , Bacteriological Techniques , Biological Therapy/methods , Humans , Lab-On-A-Chip Devices , Microscopy, Video , Models, Biological , Neoplasms/therapy , Salmonella/isolation & purification , Selection, Genetic
4.
Ther Deliv ; 6(3): 385-99, 2015 Mar.
Article in English | MEDLINE | ID: mdl-25853312

ABSTRACT

Bacteria are perfect vessels for targeted cancer therapy. Conventional chemotherapy is limited by passive diffusion, and systemic administration causes severe side effects. Bacteria can overcome these obstacles by delivering therapeutic proteins specifically to tumors. Bacteria have been modified to produce proteins that directly kill cells, induce apoptosis via signaling pathways, and stimulate the immune system. These three modes of bacterial treatment have all been shown to reduce tumor growth in animal models. Bacteria have also been designed to convert nontoxic prodrugs to active therapeutic compounds. The ease of genetic manipulation enables creation of arrays of bacteria that release many new protein drugs. This versatility will allow targeting of multiple cancer pathways and will establish a platform for individualized cancer medicine.


Subject(s)
Bacteria/metabolism , Bacterial Proteins/therapeutic use , Biological Therapy/methods , Neoplasms/therapy , Bacterial Proteins/metabolism , Bacterial Toxins/metabolism , Bacterial Toxins/therapeutic use , Humans , Prodrugs/metabolism , Prodrugs/therapeutic use
SELECTION OF CITATIONS
SEARCH DETAIL