Pig eyes were obtained from the University of Arizona Meat Sciences Laboratory. The eyes were enucleated immediately after euthanatization, stored on ice, and transferred to the laboratory for tissue isolation. The adherent muscles were excised, the lens and vitreous were discarded, and the retina was detached using forceps. The eye cup was filled with PBS (137 mM NaCl, 2.70 mM KCl, 10.1 mM Na₂HPO₄, 1.80 mM KH₂PO₄; pH 7.4) and the RPE cells were carefully removed using a fine camel's hair brush to avoid damaging BM. The BM/Ch was detached from the sclera with the aid of forceps and mounted between two corresponding 1.5-mm-diameter holes drilled in pieces of exposed and developed x-ray film (BioMax-MS; Kodak, Rochester, NY) coated with a thin film of silicon grease (Fig. 1). 

Human serum albumin (EMD Chemicals Inc, Gibbstown, NJ), horse spleen ferritin (EMD Chemicals), RNase A (Teknova Inc, Hollister, CA), and cytosine (Sigma-Aldrich, St. Louis, MO) were of the highest purity available. These tracers were selected for their ability to separate cleanly by gel exclusion chromatography. Diffusion properties of tracers through BM/Ch were studied using a dual Ussing chamber (model U2500; Warner Instruments). The BM/Ch x-ray film “sandwich” was mounted in the chamber using a 12-mm round tissue insert with an O-ring (Fig. 1), such that the two sides of the Ussing chamber were separated by the BM/Ch. A mixture of cytosine (molecular weight [MW] = 110.1, R _S < 1.0 nm) and the following proteins: RNase A (MW = 13,700, R _S = 1.72 nm), albumin (MW = 66,382, R _S = 3.55 nm), and ferritin (MW = 450,000, R _S = 6.15 nm), dissolved in 4.5 mL of PBS containing 1 mM MgCl and 0.1 mM CaCl₂ (PBS-CM), was added to the reservoir on one side of the tissue with the opposite side containing 4.5 mL of PBS-CM only. The initial concentration of each solute (albumin: 24,931 μg/mL; ferritin: 2592 μg/mL; RNase A: 1203 μg/mL; and cytosine: 381 μg/mL) was varied so that peak heights in the initial chromatograms were comparable. Magnetic bars were placed in each chamber to permit continuous agitation of the solutions for the duration of the experiment. Sample aliquots of 0.7 mL were withdrawn at time intervals of 4, 8, 16, 24, and 36 hours from each chamber for quantification of proteins. 

Flux (J) was calculated using Eq. (1), where C is the accumulated molar concentration at a given time point, A is the area (cm²) of the exposed tissue (0.01766 cm²), and t is elapsed time    

Permeability coefficients (P) were calculated using Fick's first law as indicated in Eq. (2), where L is the thickness of the BM/Ch preparation determined by SEM of cross-sections of mounted explants and ΔC describes the difference in moles of tracer between the two compartments of the Ussing chamber    

Tracers were quantified using gel exclusion chromatography with a 1.6 × 60 cm column (Hi-Prep Sephacryl S-300HR; Amersham, Pittsburgh, PA) equilibrated with PBS-CM. The column was developed at a linear flow rate of 15 mL cm⁻¹ h⁻² using an automated liquid chromatography system (AKTAprime; GE Healthcare Life Sciences) controlled by open source software (PrimeView, Version 1.0; GE Healthcare Life Sciences). Peaks were detected by their absorbance at 280 nm and peak areas determined by integration using the open source software (PrimeView). Solute concentration was determined by linear regression analysis using peak areas derived from known quantities of each test solute. Standard curves were derived individually for each solute as a function of concentration (see Fig. 4). 

Nonlinear regressions were obtained by using curve-fitting software (GraphPad Prism; GraphPad Software Inc, La Jolla, CA). An unpaired Student's t-test was used to compare calculated flux means, with two-tailed probability values, and α = 0.05 was used as the criterion to reject the null hypothesis of equality of means. All values are reported as mean ± SD. 

The integrity of the BM or Ch surface of tissue samples was evaluated at the end of each experiment by a scanning electron microscope (SEM) and transmission electron microscopy (TEM). For SEM, at the end of each experiment, x-ray film/tissue “sandwiches” were immersed in 3% gluteraldehyde in 25 mM phosphate buffer (pH 7) overnight at 4°C. The samples were rinsed in PBS, postfixed in 2% osmium tetroxide for 60 minutes, and dehydrated through a graded series of ethanol. Then the samples were critical point dried, mounted on a specimen stub with silver paste, and sputter coated with Au/Pd. Samples were imaged and photographed with a fully automated variable pressure SEM (Hitachi S-3400N Type II). Because orientation of the tissue on the specimen stub dictated the viewing angle of the image, measurements of BM/Ch thickness, images of the Ch side of tissue, and images of tissue with intact RPE were not made from samples used in diffusion experiments, but were performed on other tissue isolates. BM/Ch thickness was determined from SEM cross-sectional images (n = 3) obtained at a magnification of ×1000 using ImageJ software (developed by Wayne Rasband, National Institutes of Health, Bethesda, MD; available at http://rsb.info.nih.gov/ij/index.html). For TEM, tissue samples were fixed in 1% paraformaldehyde, 2% glutaraldehyde in 0.1 M Sorenson's phosphate buffer (pH 7.4) overnight at 4°C. After rinsing in 0.1 M Sorenson's phosphate buffer, samples were dehydrated and prepared for embedding (Araldite Epoxy Embedding Kit SPI-Pon 812; SPI Supplies, West Chester, PA). Samples were imaged at 80 kV with uranyl acetate staining (CM12 Phillips Transmission EM). 

The goal of our study was to measure differences in flux and permeability of macromolecules across BM/Ch as related to R _S, and to do so using the smallest piece of tissue possible. The latter will facilitate future studies using small animals such as mice and to evaluate regional variations in diffusion across BM/Ch in human eyes. To accomplish this we applied a simple and inexpensive modification to a commercially available Ussing chamber to permit the use of small pieces of BM/Ch. As shown in Figure 1, this modification involves the use of an insert produced from two pieces of exposed x-ray film. A hole of any size can be drilled in the film and the tissue held in place between the two pieces by a thin film of silicon grease. 

In our modified Ussing setup the ability to follow diffusion across BM/Ch requires that BM be intact for the duration of the experiment. To determine whether all five layers of BM are intact, we compared BM from eyes fixed immediately after enucleation and with the RPE intact (Fig. 2A) with BM/Ch preparations (Fig. 2B) by TEM. Figure 2 demonstrates that all five layers of BM remain intact after the procedure, with the only noticeable difference being the washout of plasma protein. Elastic and collagen fibers as well as the endothelial and RPE basement membranes remained intact. It should be noted that in all experiments it is the RPE basement membrane that is directly exposed to the fluid in the chamber. 

Since the integrity of BM could be compromised by poor dissection of the tissue, failure to remove RPE cells from BM, or the disintegration of the tissue during mounting, or during the time course of the experiment, the integrity of each BM/Ch preparation was evaluated at the end of each experiment using SEM. Figure 3 shows that RPE cells were successfully and completely removed from the surface of BM (compare Figs. 3A1 and 3A2 with 3C) without collateral damage to BM (Figs. 3A1, 3A2). BM appeared intact because there was no evidence of exposed collagen fibers, as would be predicted due to tearing of the basal lamina. Examination of the opposing surface revealed a web of connective tissue fibers resembling the suprachoiodal tissue that connects the Ch and sclera (Fig. 3B). We observed no evidence that the tissue had deteriorated during our experiments. Thickness (L) of BM/Ch explants was measured by SEM of explants in cross-section and was 58.1 ± 1.51 μm (mean ± SD, n = 3). 

To determine how flux across BM/Ch is influenced by R _S, we established a concentration gradient of all four tracer molecules across BM/Ch and applied Fick's first law to calculate the flux and permeability coefficient of each molecule (see the Materials and Methods section). Although others have used fluorescent tracers to measure flux across BM/Ch preparations, we found that this did not suit the design of our experiments. The reason for this was that we could not achieve a high enough specific activity of labeling of the reporter molecules to perform experiments with 1.8-mm² tissue samples in a 24- to 48-hour experiment, and we wanted to be able to compare multiple tracers in the same experiment without introducing the need for each reporter to be differentially labeled. Furthermore, labeling of proteins with fluorescent tracers is typically accomplished by modification of the Ε amino acid of a lysine residue, which significantly alters charge characteristics and potentially affects R _S. To circumvent these limitations we chose to use gel exclusion chromatography to quantify all four tracers, without structural modification, at each time point simultaneously. Examples of chromatograms and standard curves indicating the limits of detection for each standard are shown in Figure 4. 

Experiments were performed to examine the diffusion of all four tracers in both the BM to Ch (Fig. 5) and Ch to BM (Fig. 6) directions. We were able to detect cytosine at the first time point of 4 hours regardless of the direction of diffusion (Figs. 5, 6). RNase A was quantifiable at 4 hours in the BM to Ch direction (Fig. 5) but was not quantifiable until 8 hours in the Ch to BM direction (Fig. 6). Similarly, albumin was first observed in the BM to Ch direction at 4 hours (Fig. 5) but the peak was too small to quantify; however, by 8 hours a significant amount of albumin was observed to have diffused. In the Ch to BM direction albumin was first detected at 16 hours (Fig. 6). Ferritin was first detected at 24 hours in the BM to Ch experiments (Fig. 6), but was reliably observed in the Ch to BM experiments only at the 36-hour time point (Fig. 5). Importantly, even at 36 hours, ferritin was not detected in every experiment in either direction. To ensure that our data were not skewed by absorption of the tracers to the explants, we quantified the amount of each tracer in both compartments at each time point. Essentially 100% of each tracer was recovered at each time point. 

The flux of each tracer remained relatively constant throughout the time course of each experiment (Fig. 7A), although the diffusion of tracers did not have a significant impact on the concentration gradient through the time course of the experiment (Fig. 8). Flux was greatest for the smallest tracer, cytosine, and diminished with increasing R _S (Fig. 7B). Ferritin had the slowest average flux (0.1 ± 0.08 nmol cm⁻² h⁻¹ from Ch to BM and 0.09 ± 0.14 nmol cm⁻² h⁻¹ from BM to Ch) and was detected only at the 36-hour time point in the Ch to BM direction and at the 24- and 36-hour time points in the BM to Ch direction. For all four tracers flux appeared greater in the BM to Ch direction compared with that in the Ch to BM direction (Fig. 6A). For cytosine and RNase A this difference was statistically significant (P < 0.05). 

The permeability coefficient (P) for each tracer was calculated using Eq. (2) (see the Materials and Methods section) at each time point at which the tracer was detected. Like flux, P remained constant with time (Fig. 9A) and decreased with increasing R _S for cytosine, RNase A, and albumin (Figs. 9A, 9B). In contrast to the difference in flux, however, P was similar for albumin and ferritin. Thus, we conclude that the size exclusion limit of BM exceeds the R _S of ferritin, but that the permeability of BM to molecules with R _S similar to or greater than that of albumin is limited, suggesting that albumin and ferritin are near the physical size exclusion limit of BM. 

Studies of molecular diffusion through BM have been a valuable aid in understanding the effects of aging on BM function and suggest that the pathologic progression of AMD includes a diminished flux of nutrients and waste across BM. ^{17 –20} Prior studies examining the diffusion properties of BM have been performed on human tissues and age-matched controls but have always examined a single tracer or, when multiple tracers were used, they were examined serially rather than simultaneously. By using gel exclusion chromatography we have been able to determine flux and permeability coefficients for four tracers differing in mass and R _S without altering the endogenous properties of these tracers by chemical modification of charged amino acids. Gel exclusion chromatography allows us to rule out any interaction between the individual tested molecules. Molar concentrations were calculated on both sides of the tissues and, by performing mole balance calculation, we can determine exactly how much of each protein diffused through. Any differences could be attributed to interaction of the molecule with the tissue. Also, differences in peak retention volumes or peak shapes can give us information on interaction of the molecules among themselves. 

Furthermore, we have miniaturized the system to permit measurements to be made on pieces of tissue as small as (and potentially smaller than) 1.8 mm². This miniaturization has the potential to allow comparative studies of diffusion using tissue from genetically altered mice or human tissue from a single donor dissected from the macula versus the periphery. In this work we used pig BM/Ch tissue as a tool to develop the method under study. Although the pig BM used was not subject to age-related alterations in composition and structure, such as lipid deposits and thickening, it has a structure and composition similar to those of human BM ^21,22 and is a popular model for the study of AMD. ^23,24  

The flux values we obtained were compared with values obtained by other groups for molecules of similar mass. Hussain et al. ¹¹ examined the flux of amino acids ranging from 75.07 to 175.13 Da. Their values ranged from approximately 1400 nmol cm⁻² h⁻¹ (for phenylanine) to 3600 nmol cm⁻² h⁻¹ (for lysine). In our experiments, cytosine, whose molecular mass lies within the range studied for these amino acids, had fluxes of 2426 ± 1148 nmol cm⁻² h⁻¹ in the BM to Ch direction and 1462 ± 727 nmol cm⁻² h⁻¹ in the Ch to BM direction. Hussain et al. ¹⁷ examined the flux of various fluorescent dextrans with mass ranging from 4.4 to 500 kDa. The larger dextrans exhibited flux of approximately 0.357 nmol cm⁻² h⁻¹. This value is higher than the flux we obtained for ferritin (<0.1 nmol cm⁻² h⁻¹ in either direction). This difference is likely due to the structure of dextrans. ²⁵ Dextran flux values are expected to be higher since they are randomly coiled linear polymers, whereas the tracers we used are globular proteins (except for cytosine). ¹⁷ Dextrans and proteins of comparable mass react differently with water (dextrans are more hydrophilic) and studies on dextran diffusion have shown that they are less hindered than would be predicted on the basis of R _S. ²⁵ However, diffusional flux alone may not be the best value for comparison between molecules. Flux is influenced by many factors, including the structural properties of the tissue, the tracer, the concentration gradient, and the time course of the experiment. 

The relationship between P and R _S was found to follow an exponential decline for molecules with R _S equivalent to albumin (3.55 nm) and smaller. As explained elsewhere, ^26,27 porous diffusion through a fiber matrix, such as BM, roughly follows an exponential decline with molecular radius. Similar trends have been observed in diffusion of proteins through the sclera. ^28,29 When studied individually, small molecules (amino acids with mass similar to that of cytosine) were found to have an almost linear trend ¹¹ of flux relative to mass, whereas dextran macromolecules of differing size followed a power law relationship ^17,25,30 of flux relative to mass. Interestingly, the P of BM/Ch for ferritin was very similar to albumin despite the difference in their R _S values (3.55 nm for albumin vs. 6.15 nm for ferritin). The change in relationship between permeability and R _S for molecules of this size suggests that the functional size exclusion limit of BM in the pig is greater than 6.15 nm but that 6.15 nm is approaching that limit. 

In this study we successfully established a method to evaluate the diffusion of both small and macromolecules through BM. The relationship between diffusivity and R _S was found to be consistent with porous diffusion through a fiber matrix. As with all past studies on diffusion through BM/Ch, one limitation is the presence of the Ch and the longer path through the Ch than through BM itself. Although others have shown differences in the flux of tracers through BM in an AMD versus age-matched control eyes, there is still the need to investigate the underlying mechanisms causing these differences and the relative changes that occur in the macula versus the periphery. Also there is still the need to evaluate the diffusion of tracers with known importance to RPE function, such as serum retinol binding protein, ³¹ secreted cytokines, ^32,33 and lipoproteins. ^9,34 The method presented herein will be a valuable tool in future studies seeking to understand differences in BM permeability in genetically altered animal models exhibiting sub-RPE deposits ³⁵ and in understanding differences in the regional permeability of BM in human donor tissue associated with AMD.