matt_papers/MWTCC03/poster.tex

%% this is my poster for the Midwest Theoretical Conference


\documentclass[10pt]{scrartcl}
%%
%
% This is a poster template with latex macros and using
% the University of Florida Logo.  For further information
% on making postscript, resizeing, and printing the poster file
% please see web site 
% http://www.phys.ufl.edu/~pjh/posters/poster_howto_UF.html
% 
% N.B. This format is cribbed from one obtained from the University
% of Karlsruhe, so some macro names and parameters are in German
% Here is a short glosary:
% Breite: width
% Hoehe: height
% Spalte: column
% Kasten: box
%
% All style files necessary are part of standard TeTeX distribution
% On the UF unix cluster you should not need to import these files
% specially, as they will be automatically located.  If you
% run on a local PC however, you will need to locate these files.
% At UF try /usr/local/TeTeX...
% 
% P. Hirschfeld 2/11/00
%
% The recommended procedure is to first generate a ``Special Format" size poster
% file, which is relatively easy to manipulate and view.  It can be
% resized later to A0 (900 x 1100 mm) full poster size, or A4 or Letter size
% as desired (see web site).  Note the large format printers currently
% in use at UF's OIR have max width of about 90cm or 3 ft., but the paper
% comes in rolls so the length is variable.  See below the specifications
% for width and height of various formats.  Default in the template is
% ``Special Format",  with 4 columns.
%%
%% 
%% Choose your poster size:
%% For printing you will later RESIZE your poster by a factor
%%        2*sqrt(2) = 2.828    (for A0)
%%        2         = 2.00     (for A1) 
%%  
%% 
\def\breite{390mm}     % Special Format. 
\def\hoehe{319.2mm}      % Scaled by 2.82 this gives 110cm x 90cm 
\def\anzspalten{4}
%%
%%\def\breite{420mm}     % A3 LANDSCAPE
%%\def\hoehe{297mm}
%%\def\anzspalten{4}
%%
%% \def\breite{297mm}     % A3 PORTRAIT
%% \def\hoehe{420mm}
%% \def\anzspalten{3}
%%
%% \def\breite{210mm}     % A4 PORTRAIT
%% \def\hoehe{297mm}
%% \def\anzspalten{2}
%%
%%
%% Procedure:
%%   Generate poster.dvi with latex
%%   Check with Ghostview
%%   Make a .ps-file with ``dvips -o poster.ps poster''
%%   Scale it with poster_resize poster.ps S
%%   where S is scale factor
%%     for Special Format->A0 S= 2.828 (= 2^(3/2)))
%%     for Special Format->A1 S= 2 (= 2^(2/2)))
%% 
%% Sizes (European:)
%%   A3: 29.73 X 42.04 cm
%%   A1: 59.5 X 84.1 cm
%%   A0: 84.1 X 118.9 cm
%%   N.B. The recommended procedure is ``Special Format x 2.82"
%%   which gives 90cm x 110cm (not quite A0 dimensions).
%%
%% --------------------------------------------------------------------------
%%
%% Load the necessary packages
%% 
\usepackage{palatino}
\usepackage[latin1]{inputenc}
\usepackage{epsf}
\usepackage{graphicx,psfrag,color,pstcol,pst-grad}
\usepackage{amsmath,amssymb}
\usepackage{latexsym}
\usepackage{calc}
\usepackage{multicol}
\usepackage{wrapfig}
%%
%% Define the required numbers, lengths and boxes 
%%
\newsavebox{\dummybox}
\newsavebox{\spalten}
%\input psfig.sty

%%
%%
\newlength{\bgwidth}\newlength{\bgheight}
\setlength\bgheight{\hoehe} \addtolength\bgheight{-1mm}
\setlength\bgwidth{\breite} \addtolength\bgwidth{-1mm}

\newlength{\kastenwidth}

%% Set paper format
\setlength\paperheight{\hoehe}                                             
\setlength\paperwidth{\breite}
\special{papersize=\breite,\hoehe}

\topmargin -1in
\marginparsep0mm
\marginparwidth0mm
\headheight0mm
\headsep0mm


%% Minimal Margins to Make Correct Bounding Box
\setlength{\oddsidemargin}{-2.44cm}
\addtolength{\topmargin}{-3mm}
\textwidth\paperwidth
\textheight\paperheight

%%
%%
\parindent0cm
\parskip1.5ex plus0.5ex minus 0.5ex
\pagestyle{empty}


\definecolor{ndgold}{rgb}{0.87,0.82,0.59}
\definecolor{ndgold2}{rgb}{0.96,0.91,0.63}
\definecolor{ndblue}{rgb}{0,0.1875, 0.6992}
\definecolor{recoilcolor}{rgb}{1,0,0}
\definecolor{occolor}{rgb}{0,1,0}
\definecolor{pink}{rgb}{0,1,1}


\def\UberStil{\normalfont\sffamily\bfseries\large}
\def\UnterStil{\normalfont\sffamily\small}
\def\LabelStil{\normalfont\sffamily\tiny}
\def\LegStil{\normalfont\sffamily\tiny}

%%
%% Define some commands
%%
\definecolor{JG}{rgb}{0.1,0.9,0.3}

\newenvironment{kasten}{%
  \begin{lrbox}{\dummybox}%
    \begin{minipage}{0.96\linewidth}}%
    {\end{minipage}%
  \end{lrbox}%
  \raisebox{-\depth}{\psshadowbox[framearc=0.05,framesep=1em]{\usebox{\dummybox}}}\\[0.5em]}
\newenvironment{spalte}{%
  \setlength\kastenwidth{1.2\textwidth}
  \divide\kastenwidth by \anzspalten
  \begin{minipage}[t]{\kastenwidth}}{\end{minipage}\hfill}


\def\op#1{\hat{#1}}
\begin{document}
\bibliographystyle{plain}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%               Background                     %%%             
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
{\newrgbcolor{gradbegin}{0.0 0.01875 0.6992}%
  \newrgbcolor{gradend}{1 1 1}%{1 1 0.5}%
  \psframe[fillstyle=gradient,gradend=gradend,%
  gradbegin=gradbegin,gradmidpoint=0.1](\bgwidth,-\bgheight)}
\vfill
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%                     Header                   %%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\hfill
\psshadowbox[fillstyle=solid,fillcolor=ndgold2]{\makebox[0.95\textwidth]{%
    \hfill
    \parbox[c]{2cm}{\includegraphics[width=8cm]{ndLogoScience1a.eps}}
    \hfill
    \parbox[c]{0.8\linewidth}{%
      \begin{center}
        \color{ndblue}
        \textbf{\Huge {A Mesoscale Model for Phospholipid Simulations}}\\[0.5em]
        \textsc{\LARGE \underline{Matthew~A.~Meineke}, and J.~Daniel~Gezelter}\\[0.3em]
        {\large Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN 46556, USA\\
{\tt\ mmeineke@nd.edu}
}
      \end{center}}
\hfill}}\hfill\mbox{}\\[1.cm]
%\vspace*{1.3cm}
\begin{lrbox}{\spalten}
  \parbox[t][\textheight]{1.3\textwidth}{%
    \vspace*{0.2cm}
    \hfill
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%                 first column                 %%%             
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    \begin{spalte}
     \begin{kasten}
% 
%
%   This begins the first "kasten" or box
%
%
     \begin{center}
{\large{\color{red}    \underline{ABSTRACT}  } }
     \end{center}

{\color{ndblue}

A mesoscale model for phospholipids has been developed for molecular
dynamics simulations of lipid bilayers. The model makes several
simplifications to both the water and the phospholipids to reduce the
computational cost of each force evaluation. The water was represented
by the soft sticky dipole model of Ichiye \emph{et
al}.\cite{liu96:new_model,liu96:monte_carlo,chandra99:ssd_md} The
simplifications to the phospholipids included the reduction of atoms
in the tail groups to beads representing $\mbox{CH}_{2}$ and
$\mbox{CH}_{3}$ unified atoms, and the replacement of the head groups
with a single point mass containing a centrally located dipole. The
model was then used to simulate micelle and bilayer formation from a
configuration of randomly placed phospholipids which was simulated for
times in excess of 30 nanoseconds.

 }
      \end{kasten}

        
  \begin{kasten}
  \section{{\color{red}\underline{Introduction \& Background}}}
  \label{sec:intro}

%%  \subsection{{\color{ndblue}Motivation}}
  \label{sec:motivation}


Simulations of phospholipid bilayers are, by necessity, quite
complex. The lipid molecules are large, and contain many
atoms. Additionally, the head groups of the lipids are often
zwitterions, and the large separation between charges results in a
large dipole moment. Adding to the complexity are the number of water
molecules needed to properly solvate the lipid bilayer, typically 25
water molecules for every lipid molecule. These factors make it
difficult to study certain biologically interesting phenomena that
have large inherent length or time scale.

  \end{kasten}

  \begin{kasten}
  \subsection{{\color{ndblue}Ripple Phase}}

\begin{wrapfigure}{o}{60mm}
\centering
\includegraphics[width=40mm]{ripple.epsi}
\end{wrapfigure}

\mbox{}
\begin{itemize}
\item The ripple (~$P_{\beta'}$~) phase lies in the transition from the gel to fluid phase.
\item Periodicity of 100 - 200 $\mbox{\AA}$\cite{Cevc87}
\item Current simulations have box sizes ranging from 50 - 100 $\mbox{\AA}$ on a side.\cite{saiz02,lindahl00,venable00}
\end{itemize}

  \label{sec:ripplePhase}

   \end{kasten}


  \begin{kasten}
\subsection{{\color{ndblue}Diffusion \& Formation Dynamics}}
\begin{itemize}

\item
Drug Diffusion
        \begin{itemize}
        \item 
        Some drug molecules may spend appreciable amounts of time in the
        membrane

        \item
        Long time scale dynamics are need to observe and characterize their
        actions
        \end{itemize}

\item
Bilayer Formation Dynamics
        \begin{itemize}
        \item
        Current lipid simulations indicate\cite{Marrink01}:
                \begin{itemize} 
                \item Aggregation can happen as quickly as 200 ps

                \item Bilayers can take up to 20 ns to form completely
                \end{itemize}

        \end{itemize}
\end{itemize}
  \end{kasten}

  \begin{kasten}
\subsection{{\color{ndblue}System Simplfications}}
\begin{itemize}
\item Unified atoms with fixed bond lengths replace groups of atoms.
\item Replace charge distributions with dipoles.(Eq. \ref{eq:dipole} 
        vs. Eq. \ref{eq:coloumb})
\begin{itemize}
        \item Relatively short range, $\frac{1}{r^3}$, interactions allow
        the application of computational simplification algorithms,
        ie. neighbor lists.
\end{itemize}
\end{itemize}
\begin{equation}
V^{\text{dp}}_{ij}(\mathbf{r}_{ij},\boldsymbol{\Omega}_{i},
        \boldsymbol{\Omega}_{j}) = \frac{1}{4\pi\epsilon_{0}} \biggl[
        \frac{\boldsymbol{\mu}_{i} \cdot \boldsymbol{\mu}_{j}}{r^{3}_{ij}}
        -
        \frac{3(\boldsymbol{\mu}_i \cdot \mathbf{r}_{ij}) %
                (\boldsymbol{\mu}_j \cdot \mathbf{r}_{ij}) }
                {r^{5}_{ij}} \biggr]
\label{eq:dipole}
\end{equation}
\begin{equation}
V^{\text{ch}}_{ij}(\mathbf{r}_{ij}) = \frac{q_{i}q_{j}}%
        {4\pi\epsilon_{0} r_{ij}}
\label{eq:coloumb}
\end{equation} 
  \end{kasten}


     \end{spalte}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%               second column                  %%%             
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    \begin{spalte}


  \begin{kasten}
\subsection{{\color{ndblue}Reduction in calculations}}
Unified water and lipid models and decrease the number of interactions
needed between two molecules.

\begin{center}
\includegraphics[width=50mm,angle=-90]{reduction.epsi}
\end{center}
     \end{kasten}
        

  \begin{kasten}
\section{{\color{red}\underline{Models}}}
\label{sec:model}
\subsection{{\color{ndblue}Water Model}}
\label{sec:waterModel}

The waters in the simulation were modeled after the Soft Sticky Dipole
(SSD) model of Ichiye.\cite{liu96:new_model} Where:

\begin{wrapfigure}[10]{o}{60mm}
\begin{center}
\includegraphics[width=40mm]{ssd.epsi}
\end{center}
\end{wrapfigure}
\mbox{}
\begin{itemize}
\item $\sigma$ is the Lennard-Jones length parameter.
\item $\boldsymbol{\mu}_i$ is the dipole vector of molecule $i$,
\item $\mathbf{r}_{ij}$ is the vector between molecules $i$ and $j$
\item $\boldsymbol{\Omega}_i$ and $\boldsymbol{\Omega}_j$ are the Euler angles of molecule $i$ or $j$ respectively.
\end{itemize}

It's potential is as follows:

\begin{equation}
V_{s\!s\!d} = V_{L\!J}(r_{i\!j}) + V_{d\!p}(r_{i\!j},\Omega_{i},\Omega_{j})
        + V_{s\!p}(r_{i\!j},\Omega_{i},\Omega_{j})
\end{equation}


  \end{kasten}


    \end{spalte}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%               third column                   %%%             
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    \begin{spalte}

     \begin{kasten}
     
     \section{{\color{ndblue}Ima third column holder}}
     
        hello

     \end{kasten}


    \end{spalte}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%               fourth column                  %%%             
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    \begin{spalte}


     \begin{kasten}
        \begin{center}  
        {\large{\color{red} \underline{Acknowledgments}}}
     \end{center}

The authors would like to acknowledge Charles Vardeman, Christopher
Fennell, and Teng lin for their contributions to the simulation
engine. MAM would also like to extend a special thank you to Charles
Vardeman for his help with the TeX formatting of this
poster. Computaion time was provided on the Bunch-of-Boxes (B.o.B.)
cluster under NSF grant DMR 00 79647. The authors acknowledge support
under NSF grant CHE-0134881.

     \end{kasten}

\vspace{0.5cm}
      \begin{kasten}
           {\small
                \bibliography{poster}
           }
   \end{kasten}
    \end{spalte}
    }
    \end{lrbox}
\resizebox*{0.98\textwidth}{!}{%
  \usebox{\spalten}}\hfill\mbox{}\vfill
\end{document}
Revision:	551
Committed:	Mon Jun 9 15:22:52 2003 UTC (22 years, 4 months ago) by mmeineke
Content type:	application/x-tex
File size:	12726 byte(s)
Log Message:	fixed the left alignment bug. Bugger if I know what was causing it.
#	User	Rev	Content
1	mmeineke	546	%% this is my poster for the Midwest Theoretical Conference
2
3
4			\documentclass[10pt]{scrartcl}
5			%%
6			%
7			% This is a poster template with latex macros and using
8			% the University of Florida Logo. For further information
9			% on making postscript, resizeing, and printing the poster file
10			% please see web site
11			% http://www.phys.ufl.edu/~pjh/posters/poster_howto_UF.html
12			%
13			% N.B. This format is cribbed from one obtained from the University
14			% of Karlsruhe, so some macro names and parameters are in German
15			% Here is a short glosary:
16			% Breite: width
17			% Hoehe: height
18			% Spalte: column
19			% Kasten: box
20			%
21			% All style files necessary are part of standard TeTeX distribution
22			% On the UF unix cluster you should not need to import these files
23			% specially, as they will be automatically located. If you
24			% run on a local PC however, you will need to locate these files.
25			% At UF try /usr/local/TeTeX...
26			%
27			% P. Hirschfeld 2/11/00
28			%
29			% The recommended procedure is to first generate a ``Special Format" size poster
30			% file, which is relatively easy to manipulate and view. It can be
31			% resized later to A0 (900 x 1100 mm) full poster size, or A4 or Letter size
32			% as desired (see web site). Note the large format printers currently
33			% in use at UF's OIR have max width of about 90cm or 3 ft., but the paper
34			% comes in rolls so the length is variable. See below the specifications
35			% for width and height of various formats. Default in the template is
36			% ``Special Format", with 4 columns.
37			%%
38			%%
39			%% Choose your poster size:
40			%% For printing you will later RESIZE your poster by a factor
41			%% 2*sqrt(2) = 2.828 (for A0)
42			%% 2 = 2.00 (for A1)
43			%%
44			%%
45	mmeineke	551	\def\breite{390mm} % Special Format.
46	mmeineke	546	\def\hoehe{319.2mm} % Scaled by 2.82 this gives 110cm x 90cm
47			\def\anzspalten{4}
48			%%
49			%%\def\breite{420mm} % A3 LANDSCAPE
50			%%\def\hoehe{297mm}
51			%%\def\anzspalten{4}
52			%%
53			%% \def\breite{297mm} % A3 PORTRAIT
54			%% \def\hoehe{420mm}
55			%% \def\anzspalten{3}
56			%%
57			%% \def\breite{210mm} % A4 PORTRAIT
58			%% \def\hoehe{297mm}
59			%% \def\anzspalten{2}
60			%%
61			%%
62			%% Procedure:
63			%% Generate poster.dvi with latex
64			%% Check with Ghostview
65			%% Make a .ps-file with ``dvips -o poster.ps poster''
66			%% Scale it with poster_resize poster.ps S
67			%% where S is scale factor
68			%% for Special Format->A0 S= 2.828 (= 2^(3/2)))
69			%% for Special Format->A1 S= 2 (= 2^(2/2)))
70			%%
71			%% Sizes (European:)
72			%% A3: 29.73 X 42.04 cm
73			%% A1: 59.5 X 84.1 cm
74			%% A0: 84.1 X 118.9 cm
75			%% N.B. The recommended procedure is ``Special Format x 2.82"
76			%% which gives 90cm x 110cm (not quite A0 dimensions).
77			%%
78			%% --------------------------------------------------------------------------
79			%%
80			%% Load the necessary packages
81			%%
82	mmeineke	549	\usepackage{palatino}
83	mmeineke	546	\usepackage[latin1]{inputenc}
84			\usepackage{epsf}
85			\usepackage{graphicx,psfrag,color,pstcol,pst-grad}
86			\usepackage{amsmath,amssymb}
87			\usepackage{latexsym}
88			\usepackage{calc}
89			\usepackage{multicol}
90	mmeineke	550	\usepackage{wrapfig}
91	mmeineke	546	%%
92			%% Define the required numbers, lengths and boxes
93			%%
94			\newsavebox{\dummybox}
95			\newsavebox{\spalten}
96			%\input psfig.sty
97
98			%%
99			%%
100			\newlength{\bgwidth}\newlength{\bgheight}
101			\setlength\bgheight{\hoehe} \addtolength\bgheight{-1mm}
102			\setlength\bgwidth{\breite} \addtolength\bgwidth{-1mm}
103
104			\newlength{\kastenwidth}
105
106			%% Set paper format
107			\setlength\paperheight{\hoehe}
108			\setlength\paperwidth{\breite}
109			\special{papersize=\breite,\hoehe}
110
111			\topmargin -1in
112			\marginparsep0mm
113			\marginparwidth0mm
114			\headheight0mm
115			\headsep0mm
116
117
118			%% Minimal Margins to Make Correct Bounding Box
119			\setlength{\oddsidemargin}{-2.44cm}
120			\addtolength{\topmargin}{-3mm}
121			\textwidth\paperwidth
122			\textheight\paperheight
123
124			%%
125			%%
126			\parindent0cm
127			\parskip1.5ex plus0.5ex minus 0.5ex
128			\pagestyle{empty}
129
130
131
132			\definecolor{ndgold}{rgb}{0.87,0.82,0.59}
133			\definecolor{ndgold2}{rgb}{0.96,0.91,0.63}
134	mmeineke	547	\definecolor{ndblue}{rgb}{0,0.1875, 0.6992}
135	mmeineke	546	\definecolor{recoilcolor}{rgb}{1,0,0}
136			\definecolor{occolor}{rgb}{0,1,0}
137			\definecolor{pink}{rgb}{0,1,1}
138
139
140
141
142
143			\def\UberStil{\normalfont\sffamily\bfseries\large}
144			\def\UnterStil{\normalfont\sffamily\small}
145			\def\LabelStil{\normalfont\sffamily\tiny}
146			\def\LegStil{\normalfont\sffamily\tiny}
147
148			%%
149			%% Define some commands
150			%%
151			\definecolor{JG}{rgb}{0.1,0.9,0.3}
152
153			\newenvironment{kasten}{%
154			\begin{lrbox}{\dummybox}%
155			\begin{minipage}{0.96\linewidth}}%
156			{\end{minipage}%
157			\end{lrbox}%
158			\raisebox{-\depth}{\psshadowbox[framearc=0.05,framesep=1em]{\usebox{\dummybox}}}\\[0.5em]}
159			\newenvironment{spalte}{%
160			\setlength\kastenwidth{1.2\textwidth}
161			\divide\kastenwidth by \anzspalten
162			\begin{minipage}[t]{\kastenwidth}}{\end{minipage}\hfill}
163
164
165
166	mmeineke	551
167	mmeineke	546	\def\op#1{\hat{#1}}
168			\begin{document}
169			\bibliographystyle{plain}
170			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
171			%%% Background %%%
172			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
173	mmeineke	551	{\newrgbcolor{gradbegin}{0.0 0.01875 0.6992}%
174	mmeineke	546	\newrgbcolor{gradend}{1 1 1}%{1 1 0.5}%
175			\psframe[fillstyle=gradient,gradend=gradend,%
176			gradbegin=gradbegin,gradmidpoint=0.1](\bgwidth,-\bgheight)}
177			\vfill
178			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
179			%%% Header %%%
180			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
181			\hfill
182			\psshadowbox[fillstyle=solid,fillcolor=ndgold2]{\makebox[0.95\textwidth]{%
183			\hfill
184	mmeineke	547	\parbox[c]{2cm}{\includegraphics[width=8cm]{ndLogoScience1a.eps}}
185	mmeineke	546	\hfill
186			\parbox[c]{0.8\linewidth}{%
187			\begin{center}
188	mmeineke	547	\color{ndblue}
189	mmeineke	546	\textbf{\Huge {A Mesoscale Model for Phospholipid Simulations}}\\[0.5em]
190			\textsc{\LARGE \underline{Matthew~A.~Meineke}, and J.~Daniel~Gezelter}\\[0.3em]
191			{\large Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN 46556, USA\\
192			{\tt\ mmeineke@nd.edu}
193			}
194			\end{center}}
195			\hfill}}\hfill\mbox{}\\[1.cm]
196			%\vspace*{1.3cm}
197			\begin{lrbox}{\spalten}
198			\parbox[t][\textheight]{1.3\textwidth}{%
199			\vspace*{0.2cm}
200			\hfill
201			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
202			%%% first column %%%
203			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
204			\begin{spalte}
205			\begin{kasten}
206			%
207			%
208			% This begins the first "kasten" or box
209			%
210			%
211			\begin{center}
212			{\large{\color{red} \underline{ABSTRACT} } }
213			\end{center}
214
215			{\color{ndblue}
216
217			A mesoscale model for phospholipids has been developed for molecular
218			dynamics simulations of lipid bilayers. The model makes several
219			simplifications to both the water and the phospholipids to reduce the
220			computational cost of each force evaluation. The water was represented
221			by the soft sticky dipole model of Ichiye \emph{et
222			al}.\cite{liu96:new_model,liu96:monte_carlo,chandra99:ssd_md} The
223			simplifications to the phospholipids included the reduction of atoms
224			in the tail groups to beads representing $\mbox{CH}_{2}$ and
225			$\mbox{CH}_{3}$ unified atoms, and the replacement of the head groups
226			with a single point mass containing a centrally located dipole. The
227			model was then used to simulate micelle and bilayer formation from a
228			configuration of randomly placed phospholipids which was simulated for
229			times in excess of 30 nanoseconds.
230
231			}
232			\end{kasten}
233
234	mmeineke	550
235			\begin{kasten}
236			\section{{\color{red}\underline{Introduction \& Background}}}
237			\label{sec:intro}
238	mmeineke	546
239	mmeineke	551	%% \subsection{{\color{ndblue}Motivation}}
240	mmeineke	550	\label{sec:motivation}
241	mmeineke	546
242	mmeineke	550
243			Simulations of phospholipid bilayers are, by necessity, quite
244			complex. The lipid molecules are large, and contain many
245			atoms. Additionally, the head groups of the lipids are often
246			zwitterions, and the large separation between charges results in a
247			large dipole moment. Adding to the complexity are the number of water
248			molecules needed to properly solvate the lipid bilayer, typically 25
249			water molecules for every lipid molecule. These factors make it
250			difficult to study certain biologically interesting phenomena that
251			have large inherent length or time scale.
252
253			\end{kasten}
254
255			\begin{kasten}
256			\subsection{{\color{ndblue}Ripple Phase}}
257
258			\begin{wrapfigure}{o}{60mm}
259			\centering
260			\includegraphics[width=40mm]{ripple.epsi}
261			\end{wrapfigure}
262
263			\mbox{}
264			\begin{itemize}
265			\item The ripple (~$P_{\beta'}$~) phase lies in the transition from the gel to fluid phase.
266			\item Periodicity of 100 - 200 $\mbox{\AA}$\cite{Cevc87}
267			\item Current simulations have box sizes ranging from 50 - 100 $\mbox{\AA}$ on a side.\cite{saiz02,lindahl00,venable00}
268			\end{itemize}
269
270			\label{sec:ripplePhase}
271
272			\end{kasten}
273
274
275			\begin{kasten}
276			\subsection{{\color{ndblue}Diffusion \& Formation Dynamics}}
277			\begin{itemize}
278
279			\item
280			Drug Diffusion
281			\begin{itemize}
282			\item
283			Some drug molecules may spend appreciable amounts of time in the
284			membrane
285
286			\item
287			Long time scale dynamics are need to observe and characterize their
288			actions
289			\end{itemize}
290
291			\item
292			Bilayer Formation Dynamics
293			\begin{itemize}
294			\item
295			Current lipid simulations indicate\cite{Marrink01}:
296			\begin{itemize}
297			\item Aggregation can happen as quickly as 200 ps
298
299			\item Bilayers can take up to 20 ns to form completely
300			\end{itemize}
301
302			\end{itemize}
303			\end{itemize}
304			\end{kasten}
305
306			\begin{kasten}
307			\subsection{{\color{ndblue}System Simplfications}}
308			\begin{itemize}
309			\item Unified atoms with fixed bond lengths replace groups of atoms.
310			\item Replace charge distributions with dipoles.(Eq. \ref{eq:dipole}
311			vs. Eq. \ref{eq:coloumb})
312			\begin{itemize}
313			\item Relatively short range, $\frac{1}{r^3}$, interactions allow
314			the application of computational simplification algorithms,
315			ie. neighbor lists.
316			\end{itemize}
317			\end{itemize}
318			\begin{equation}
319			V^{\text{dp}}_{ij}(\mathbf{r}_{ij},\boldsymbol{\Omega}_{i},
320			\boldsymbol{\Omega}_{j}) = \frac{1}{4\pi\epsilon_{0}} \biggl[
321			\frac{\boldsymbol{\mu}_{i} \cdot \boldsymbol{\mu}_{j}}{r^{3}_{ij}}
322			-
323			\frac{3(\boldsymbol{\mu}_i \cdot \mathbf{r}_{ij}) %
324			(\boldsymbol{\mu}_j \cdot \mathbf{r}_{ij}) }
325			{r^{5}_{ij}} \biggr]
326			\label{eq:dipole}
327			\end{equation}
328			\begin{equation}
329			V^{\text{ch}}_{ij}(\mathbf{r}_{ij}) = \frac{q_{i}q_{j}}%
330			{4\pi\epsilon_{0} r_{ij}}
331			\label{eq:coloumb}
332			\end{equation}
333			\end{kasten}
334
335
336
337	mmeineke	546	\end{spalte}
338			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
339			%%% second column %%%
340			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
341			\begin{spalte}
342
343
344	mmeineke	550	\begin{kasten}
345			\subsection{{\color{ndblue}Reduction in calculations}}
346			Unified water and lipid models and decrease the number of interactions
347			needed between two molecules.
348
349			\begin{center}
350			\includegraphics[width=50mm,angle=-90]{reduction.epsi}
351			\end{center}
352	mmeineke	546	\end{kasten}
353
354
355	mmeineke	550	\begin{kasten}
356			\section{{\color{red}\underline{Models}}}
357			\label{sec:model}
358			\subsection{{\color{ndblue}Water Model}}
359			\label{sec:waterModel}
360	mmeineke	546
361	mmeineke	550	The waters in the simulation were modeled after the Soft Sticky Dipole
362			(SSD) model of Ichiye.\cite{liu96:new_model} Where:
363	mmeineke	546
364	mmeineke	550	\begin{wrapfigure}[10]{o}{60mm}
365			\begin{center}
366			\includegraphics[width=40mm]{ssd.epsi}
367			\end{center}
368			\end{wrapfigure}
369			\mbox{}
370			\begin{itemize}
371			\item $\sigma$ is the Lennard-Jones length parameter.
372			\item $\boldsymbol{\mu}_i$ is the dipole vector of molecule $i$,
373			\item $\mathbf{r}_{ij}$ is the vector between molecules $i$ and $j$
374			\item $\boldsymbol{\Omega}_i$ and $\boldsymbol{\Omega}_j$ are the Euler angles of molecule $i$ or $j$ respectively.
375			\end{itemize}
376
377			It's potential is as follows:
378
379			\begin{equation}
380			V_{s\!s\!d} = V_{L\!J}(r_{i\!j}) + V_{d\!p}(r_{i\!j},\Omega_{i},\Omega_{j})
381			+ V_{s\!p}(r_{i\!j},\Omega_{i},\Omega_{j})
382			\end{equation}
383
384
385			\end{kasten}
386
387
388
389
390	mmeineke	546	\end{spalte}
391			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
392			%%% third column %%%
393			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
394			\begin{spalte}
395
396			\begin{kasten}
397	mmeineke	549
398			\section{{\color{ndblue}Ima third column holder}}
399
400	mmeineke	546	hello
401
402			\end{kasten}
403
404
405			\end{spalte}
406			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
407			%%% fourth column %%%
408			%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
409			\begin{spalte}
410
411
412
413
414
415			\begin{kasten}
416			\begin{center}
417			{\large{\color{red} \underline{Acknowledgments}}}
418			\end{center}
419
420			The authors would like to acknowledge Charles Vardeman, Christopher
421			Fennell, and Teng lin for their contributions to the simulation
422			engine. MAM would also like to extend a special thank you to Charles
423			Vardeman for his help with the TeX formatting of this
424			poster. Computaion time was provided on the Bunch-of-Boxes (B.o.B.)
425			cluster under NSF grant DMR 00 79647. The authors acknowledge support
426			under NSF grant CHE-0134881.
427
428			\end{kasten}
429
430			\vspace{0.5cm}
431			\begin{kasten}
432			{\small
433			\bibliography{poster}
434			}
435			\end{kasten}
436			\end{spalte}
437			}
438			\end{lrbox}
439			\resizebox*{0.98\textwidth}{!}{%
440			\usebox{\spalten}}\hfill\mbox{}\vfill
441			\end{document}