Confocal Raman microscopy for investigating synthesis and characterization of individual optically trapped vinyl-polymerized surfactant particles.

Small polymeric particles are increasingly employed as adsorbent materials, as molecular carriers, as delivery vehicles, and in preconcentration applications. The rational development of these materials requires in situ methods of analysis to characterize their synthesis, structure, and applications. Optical-trapping confocal Raman microscopy is a spectroscopic method capable of acquiring information at several stages of the development of such dispersed particulate materials. In the present study, an example material is developed and tested using confocal Raman microscopy for characterization at each stage of the process. Specifically, the method is used to investigate the synthesis, structure, and applications of individual polymeric surfactant particles produced by the vinyl polymerization of sodium 11-acrylamidoundecanoate (SAAU). The kinetics of polymerization can be monitored over time by measuring the loss of the acrylamide C=C functional groups using confocal Raman microscopy of particles optically trapped by the excitation laser, where, within the limits of detecting the vinyl functional group, the complete polymerization of the SAAU monomer was achieved. The polymerized SAAU particles are spherical, and they exhibit uniform access to water throughout their structure, as tested by the penetration of heavy water (D2O) and collection of spatially resolved Raman spectra from the interior of the particle. These porous particles contain hydrophobic domains that can be used to accumulate molecules for adsorption or carrier applications. This property was tested by using confocal Raman microscopy to measure the accumulation equilibria and kinetics of a model compound, dioxybenzone. The partitioning of this compound into the polymer surfactant could be determined on a quantitative basis using relative scattering cross sections of the SAAU monomer and the adsorbate. The study points out the utility of optical-trapping confocal Raman microscopy for investigating the synthesis, structure, and potential carrier applications of polymeric particle materials.

Confocal Raman microscopy probing of temperature-controlled release from individual, optically-trapped phospholipid vesicles.

Control of permeability of phospholipid vesicle (liposome) membranes is critical to their applications in analytical sensing, in fundamental studies of chemistry in small volumes, and in encapsulation and release of payloads for site-directed drug delivery. Applications of liposome formulations in drug delivery often take advantage of the enhanced permeability of phospholipid membranes at their gel-to-fluid phase transition, where the release of encapsulated molecules can be initiated by an increase in temperature. Despite numerous successful liposome formulations for encapsulation and release methods to study the kinetics, this process has been limited to investigations of bulk vesicle dispersions, which provide little or no information about the vesicle membrane structure and its relationship to the kinetics of trans-membrane transport. In this work, confocal Raman microscopy is adapted to study temperature-dependent release of a model compound, 3-nitrobenzene sulfonate (3-NBS), from individual optically trapped phospholipid vesicles, while simultaneously monitoring structural changes in the vesicle membrane reported by vibrational modes of phospholipid acyl chains and the local environment of the encapsulated compound. The confocal geometry allows efficient excitation and collection of Raman scattering from a single vesicle, while optical trapping allows more than hour-long observations of the same vesicle. With window factor analysis to resolve component spectra, temperature-controlled release of 3-NBS through vesicle membranes composed of pure 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) was measured and compared to transport through a lysolipid-containing membrane specifically formulated for efficient drug delivery.

Molecular profiling: gene expression reveals discrete phases of lens induction and development in Xenopus laevis.

PURPOSE: Experimental tissue transplant studies reveal that lens development is directed by a series of early and late inductive interactions. These interactions impart a growing lens-forming bias within competent presumptive lens ectoderm that leads to specification and the commitment to lens fate. Relatively few genes are known which control these events. Identification of additional genes expressed during lens development may reveal key players in these processes and help to characterize these tissue properties. METHODS: A large suite of genes has been isolated that are expressed during the process of cornea-lens transdifferentiation (lens regeneration) in Xenopus laevis. Many of these genes are also expressed during embryonic lens development. Genes were selected for expression analysis via in situ hybridization. This group consisted of clones with possible roles in cell determination and differentiation as well as novel clones without previous identities. The spatiotemporal expression of these genes in conjunction with previously described genes were correlated with key events during embryonic lens formation. RESULTS: Eighteen of the thirty clones analyzed via in situ hybridization demonstrated observable expression in the developing lens. These genes were initially expressed in the presumptive lens ectoderm at a variety of timepoints throughout development. Expression is restricted to discrete time intervals during lens development. However, in most cases, expression was maintained throughout lens development after being initially upregulated. CONCLUSIONS: The expression of these genes suggests that a genetic hierarchy exists in which an increasing number of genes are upregulated and their expression is maintained throughout lens development. Suites of genes appear to be upregulated at specific timepoints during development, correlating with stages of lens induction, specification, commitment, lens placode formation, and lens differentiation, while suites at additional timepoints suggest that other, previously unreported stages exist as well. This analysis provides a genetic framework for characterizing these processes of lens development.

Characterizing gene expression during lens formation in Xenopus laevis: evaluating the model for embryonic lens induction.

Few directed searches have been undertaken to identify the genes involved in vertebrate lens formation. In the frog Xenopus, the larval cornea can undergo a process of transdifferentiation to form a new lens once the original lens is removed. Based on preliminary evidence, we have shown that this process shares many elements of a common molecular/genetic pathway to that involved in embryonic lens development. A subtracted cDNA library, enriched for genes expressed during cornea-lens transdifferentiation, was prepared. The similarities/identities of specific clones isolated from the subtracted cDNA library define an expression profile of cells undergoing cornea-lens transdifferentiation ("lens regeneration") and corneal wound healing (the latter representing a consequence of the surgery required to trigger transdifferentiation). Screens were undertaken to search for genes expressed during both transdifferentiation and embryonic lens development. Significantly, new genes were recovered that are also expressed during embryonic lens development. The expression of these genes, as well as others known to be expressed during embryonic development in Xenopus, can be correlated with different periods of embryonic lens induction and development, in an attempt to define these events in a molecular context. This information is considered in light of our current working model of embryonic lens induction, in which specific tissue properties and phases of induction have been previously defined in an experimental context. Expression data reveal the existence of further levels of complexity in this process and suggests that individual phases of lens induction and specific tissue properties are not strictly characterized or defined by expression of individual genes.