Sage Journals: Discover world-class research

Abstract

While the duration and size of human clinical trials may be difficult to reduce, there are several parameters in pre-clinical vaccine development that may be possible to further optimise. By increasing the accuracy of the models used for pre-clinical vaccine testing, it should be possible to increase the probability that any particular vaccine candidate will be successful in human trials. In addition, an improved model will allow the collection of increasingly more-informative data in pre-clinical tests, thus aiding the rational design and formulation of candidates entered into clinical evaluation. An acceleration and increase in sophistication of pre-clinical vaccine development will thus require the advent of more physiologically-accurate models of the human immune system, coupled with substantial advances in the mechanistic understanding of vaccine efficacy, achieved by using this model. We believe the best viable option available is to use human cells and/or tissues in a functional in vitro model of human physiology. Not only will this more accurately model human diseases, it will also eliminate any ethical, moral and scientific issues involved with use of live humans and animals. An in vitro model, termed “MIMIC” (Modular IMmune In vitro Construct), was designed and developed to reflect the human immune system in a well-based format. The MIMIC® System is a laboratory-based methodology that replicates the human immune system response. It is highly automated, and can be used to simulate a clinical trial for a diverse population, without putting human subjects at risk. The MIMIC System uses the circulating immune cells of individual donors to recapitulate each individual human immune response by maintaining the autonomy of the donor. Thus, an in vitro test system has been created that is functionally equivalent to the donor's own immune system and is designed to respond in a similar manner to the in vivo response.

Keywords

clinical trial drug testing functional assays high-throughput immune response infectious disease in vitro vaccine

Get full access to this article

View all access options for this article.

References

Randolph

G.J.

, Beaulieu

, Lebecque

, Steinman

R.M.

& Muller

W.A.

(1998). Differentiation of monocytes into dendritic cells in a model of transendothelial trafficking. Science, New York 282, 480–483.

Randolph

G.J.

, Sanchez-Schmitz

, Liebman

R.M.

& Schäkel

(2002). The CD16⁺ (FcgRIII⁺) subset of human monocytes preferentially becomes migratory dendritic cells in a model tissue setting. Journal of Experimental Medicine 196, 517–527.

Shortman

& Liu

Y-J.

(2002). Mouse and human dendritic cell subtypes. Nature Reviews. Immunology 2, 151–161.

Zelivyanskaya

M.L.

, Nelson

J.A.

, Poluektova

, Uberti

, Mellon

, Gendelman

H.E.

& Boska

M.D.

(2003). Tracking superparamagnetic iron oxide labeled monocytes in brain by high-field magnetic resonance imaging. Journal of Neuroscience Research 73, 284–295.

Pugh

C.W.

, MacPherson

G.G.

& Steer

H.W.

(1983). Characterization of nonlymphoid cells derived from rat peripheral lymph. Journal of Experimental Medicine 157, 1758–1779.

Smith

J.B.

, McIntosh

G.H.

& Morris

(1970). The traffic of cells through tissues: a study of peripheral lymph in sheep. Journal of Anatomy 107, 87–100.

Fossum

, Rolstad

& Ford

W.L.

(1984). Thymus independence, kinetics and phagocytic ability of interdigitating cells. Immunobiology 168, 403–413.

Holt

P.G.

, Haining

, Nelson

D.J.

& Sedgwick

J.D.

(1994). Origin and steady-state turnover of class II MHC-bearing dendritic cells in the epithelium of the conducting airways. Journal of Immunology 153, 256–261.

Larregina

A.T.

, Morelli

A.E.

, Spencer

L.A.

, Logar

A.J.

, Watkins

S.C.

, Thomson

A.W.

& Falo

L.D.

Jr. (2001). Dermal-resident CD14⁺ cells differentiate into Langerhans cells. Nature Immunology 2, 1151–1158.

10.

Randolph

G.J.

, Inaba

, Robbiani

D.F.

, Steinman

R.M.

& Muller

W.A.

(1999). Differentiation of phagocytic monocytes into lymph node dendritic cells in vivo. Immunity 11, 753–761.

11.

Ginhoux

, Tacke

, Angeli

, Bogunovic

, Loubeau

, Dai

X.M.

, Stanley

E.R.

, Randolph

G.J.

& Merad

(2006). Langerhans cells arise from monocytes in vivo. Nature Immunology 7, 265–273.

12.

Helintö

, Renkonen

, Tervo

, Vesaluoma

, Saaren-Seppälä

, Haahtela

& Kirveskari

(2004). Direct in vivo monitoring of acute allergic reactions in human conjunctiva. Journal of Immunology 172, 3235–3242.

13.

Robbiani

D.F.

, Finch

R.A.

, Jäger

, Muller

W.A.

, Sartorelli

A.C.

& Randolph

G.J.

(2000). The leukotriene C₄ transporter MRP1 regulates CCL19 (MIP-3b, ELC)-dependent mobilization of dendritic cells to lymph nodes. Cell 103, 757–768.

14.

Morelli

A.E.

, Rubin

J.P.

, Erdos

, Tkacheva

O.A.

, Mathers

A.R.

, Zahorchak

A.F.

, Thomson

A.W.

, Falo

L.D.

Jr & Larregina

A.T.

(2005). CD4⁺ T cell responses elicited by different subsets of human skin migratory dendritic cells. Journal of Immunology 175, 7905–7915.

15.

Assenmacher

, Lohning

& Radbruch

(2001). Detection and isolation of cytokine secreting cells using the cytometric cytokine secretion assay. Current Protocols in Immunology Unit 6.27, 1–10.

16.

Young

A.J.

(1999). The physiology of lymphocyte migration through the single lymph node in vivo. Seminars in Immunology 11, 73–83.

17.

Byers

A.M.

, Tapia

T.M.

, Sassano

E.R.

& Wittman

(2009). In vitro antibody response to tetanus in the MIMIC™ system is a representative measure of vaccine immunogenicity. Biologicals 137, 148–151.

18.

Toossi

& Ellner

J.J.

(2001). Pathogenesis of tuberculosis. In Tuberculosis (ed. Friedman

L.N.

), pp. 19–47. New York, NY, USA: CRC Press.

An Immunologic Model for Rapid Vaccine Assessment — A Clinical Trial in a Test Tube

Abstract

Keywords

Get full access to this article

References