Characterization of polymer and colloid solutions

The invention claimed is: 1. A simultaneous multiple sample light scattering (SMSLS) detection device comprising: a plurality of light scattering batch cells, each of the light scattering batch cells configured to contain a solution; a plurality of stressor modules each respectively coupled to at least one of the plurality of light scattering batch cells and each respectively configured to introduce a stressor to the solutions contained in at least one of the plurality of light scattering batch cells, the plurality of stressor modules further configured to generate stressor information output data; a photodetector coupled to at least one of the plurality of light scattering batch cells configured to detect scattered light and generate light scattering data; and a computing device coupled to the plurality of stressor modules and the photodetector, the computing device configured to receive light scattering data from the photodetector and stressor information output data from the plurality of stressor modules, the computing device further configured to determine a time dependent response of a solution initiated by the introduction of a stressor from the light scattering data and the stressor information output data. 2. The SMSLS device of claim 1 , wherein each of the plurality of light scattering batch cells comprises an agitation device capable of generating mechanical agitation of a solution contained therein, each agitation device coupled to at least one of the plurality of stressor modules, and wherein at least one of the plurality of stressor modules is configured to cause the agitation device to generate mechanical agitation of a solution. 3. The SMSLS device of claim 1 , further comprising: an incident light source configured to supply incident light to the plurality of light scattering batch cells; a rastering device coupled to at least one of the plurality of light scattering batch cells that is configured to move the at least one light scattering batch cell in a controlled pattern through the incident light; and wherein the photodetector is further configured to detect the scattered light emitted through the rastered light scattering batch cell. 4. The SMSLS device of claim 1 , wherein the plurality of stressor modules are configured to introduce a first stressor to at least one of the plurality of light scattering batch cells, and to introduce a second stressor to at least one other light scattering batch cell of the plurality of light scattering batch cells. 5. The SMSLS device of claim 4 , wherein the second stressor is different than the first stressor, and wherein the plurality of stressor modules are configured to introduce the first stressor and second stressor simultaneously. 6. The SMSLS device of claim 1 , wherein each of the plurality of stressor modules are configured to independently control the introduction of a stressor to a respective one of the light scattering batch cells. 7. The SMSLS device of claim 1 , wherein the time dependent response is protein aggregation or protein degradation. 8. The SMSLS device of claim 1 , wherein the light scattering data comprises light scattering spikes (LSS). 9. The SMSLS device of claim 1 , wherein the solution comprises a protein and the plurality of stressor modules are configured to introduce a stressor to the solutions contained in the plurality of light scattering batch cells in order to initiate a protein aggregation or degradation response. 10. The SMSLS device of claim 1 , wherein the light scattering data comprises a time dependent light scattering signature and the computing device is configured to determine a mechanistic or kinetic parameter associated with protein aggregation or protein degradation. 11. The SMSLS device of claim 1 , further comprising one or more individual cell control modules respectively coupled to at least one of the plurality of light scattering batch cells and configured to introduce a solution to a respective one of the plurality of light scattering batch cells. 12. A method of determining a time dependent aggregation or degradation response of a biological solution to one or more stressors, the method comprising: introducing a biological solution to each of a plurality of light scattering cells; introducing, using a stressor module, one or more stressors to at least one biological solution contained in the plurality of light scattering cells; generating, at the stressor module, stressor information output data corresponding to the one or more stressors; introducing a source of incident light to the plurality of light scattering cells; detecting, at a photodetector, scattered light corresponding to a time dependent response in the at least one biological solution; generating, at the photodetector, light scattering data corresponding to the time dependent response; determining, at a computing device, a time dependent aggregation or degradation response of the at least one biological solution to the one or more stressors, using the light scattering data and the stressor information output data. 13. The method of claim 12 , wherein the stressor is selected from the group consisting of mechanical agitation, ultrasound, a freeze-thaw cycle, increased exposure to an air/liquid interface, and exposure to a surface or a gas. 14. The method of claim 12 , further comprising introducing, using a stressor module, a first stressor and a second stressor to the same biological solution. 15. The method of claim 14 , wherein the first stressor is mechanical shear and the second stressor is increased exposure to an air/liquid interface. 16. The method of claim 12 , further comprising introducing, using a stressor module, a first stressor to a first biological solution contained in the plurality of light scattering cells, and a second stressor to a second biological solution contained in the plurality of light scattering cells. 17. The method of claim 16 , wherein the second stressor is different than the first stressor, and wherein the first and second stressors are introduced contemporaneously. 18. The method of claim 12 , wherein introducing a biological solution comprises introducing a biological solution using an individual cell control module. 19. The method of claim 12 , wherein the plurality of light scattering cells are batch cells. 20. The method of claim 12 , wherein the biological solution is a protein solution. 21. A simultaneous multiple sample light scattering (SMSLS) detection device comprising: a plurality of light scattering batch cells, each of the light scattering batch cells configured to contain a solution; one or more individual cell control modules respectively coupled to at least one of the plurality of light scattering batch cells and configured to introduce a solution to a respective one of the plurality of light scattering batch cells; a plurality of stressor modules each respectively coupled to at least one of the plurality of light scattering batch cells and each respectively configured to introduce a stressor to the solutions contained in at least one of the plurality of light scattering batch cells, the plurality of stressor modules further configured to generate stressor information output data; a photodetector coupled to at least one of the plurality of light scattering batch cells configured to detect scattered light and generate light scattering data; and a computing device coupled to the plurality of stressor modules and the photodetector, the computing device configured