Fast, single injection well plate micro-calorimeter using photonic sensors

What is claimed is: 1 . A system for calorimetry, the system comprising: a) a well having a volume for receiving a sample; b) an input feature configured to facilitate reception of the sample in the well; c) a light source configurable to irradiate the well and the sample with incident light; d) a photonic sensor chip disposed at the bottom of the well, the photonic sensor chip comprising plural nanohole array (NHA) sensors integrated upon a substrate; e) a light detector configured to measure transmission of light through the NHA sensors to obtain a series of extraordinary optical transmission (EOT) measurements; f) frame elements configured to secure and mutually couple the light source, the photonic sensor chip, the light detector, and the input feature to form a calorimetry unit, wherein the frame elements include a chip holder and a light detector holder, the chip holder and the light detector holder each configured to couple with one or more other frame elements of the calorimetry unit, the chip holder adapted to hold the photonic sensor chip at the bottom of the well, and the light detector holder adapted to hold the light detector to receive light transmitted as an EOT transmission through the NHA sensors of the photonic sensor chip; and g) a processor configured to calculate a calorimetry measurement as a function of the series of EOT measurements, the calorimetry measurement being indicative of energy released as a result of the sample in the well undergoing a change. 2 . The system of claim 1 , wherein the input feature includes an injection device configured to access the volume of the well and deposit the sample therein. 3 . The system of claim 2 , wherein the well is one of a plurality of wells disposed upon a well plate. 4 . The system of claim 1 , wherein the input feature includes a plurality of diffusion features disposed through a frame element forming a wall of the well, the plurality of diffusion features configured, while the calorimetry unit is immersed in a fluid, to permit a volume of the fluid including the sample to flow into the well. 5 . The system of claim 4 , further comprising at least one filter element configured to control the flow of the sample into the well. 6 . The system of claim 1 , further comprising a power supply configured to control an intensity of the light source within a range of intensities between 0 and 500 lux, according to a voltage setting of the power supply. 7 . The system of claim 6 , wherein the power supply is spatially separated from the calorimetry unit and includes at least one battery, or a switchable DC power supply device. 8 . The system of claim 1 , wherein the light source includes a light-emitting diode (LED) and a collimator operatively coupled with the LED to control a direction of rays of light emitted by the LED. 9 . The system of claim 1 , further including a heater in thermal contact with the well, and a heater controller coupled to the heater, the heater controller programmed to control the heater to apply heat to the well with the sample provided therein. 10 . The system of claim 1 , wherein the light detector includes at least one of (i) a charge-coupled device (CCD) chip or a photo-multiplier tube (PMT) positioned to receive light transmitted as an EOT transmission through the NHA sensors of the photonic sensor chip disposed at the bottom of the well, and (ii) a camera positioned to receive light transmitted as an EOT transmission at least through the NHA sensors of the photonic sensor chip disposed at the bottom of the well. 11 . The system of claim 10 , wherein the light detector includes the camera, and the camera is positioned to receive light transmitted as an EOT transmission through NHA sensors of a plurality of photonic sensor chips, each photonic sensor chip of the plurality of photonic sensor chips being respectively disposed at the bottom each well in a well plate. 12 . The system of claim 1 , further comprising a lens configurable to focus, upon the light detector, light transmitted as an EOT transmission through the NHA sensors of the photonic sensor chip disposed at the bottom of the well, the system further comprising a lens frame element configured to secure the lens and to be mutually physically coupled with one or more other frame elements of the calorimetry unit. 13 . The system of claim 1 , further comprising an optics controller configured to control aspects of at least one of the light source and the light detector, the system further comprising memory configured to store data acquired from the light detector. 14 . The system of claim 13 , wherein the processor, the optics controller, and the memory are integrated within an electronic microcontroller device operatively coupled with, and spatially separate from, the calorimetry unit. 15 . The system of claim 3 , wherein each well of the plurality of wells is arranged to receive a respective sample by a respective input feature. 16 . The system of claim 3 , wherein each well of the plurality of wells comprises a respective light detector configured to measure transmission of light through the NHA sensors to obtain a series of EOT measurements. 17 . The system of claim 3 , wherein each well of the plurality of wells comprises a respective photonic sensor chip disposed at the bottom of the well. 18 . The system of claim 4 , wherein the calorimetry unit is a floating calorimetry unit configured to be suspended in the fluid. 19 . The system of claim 18 , further comprising a floating material connected to an upper end cap of the frame elements and at least one anchor connected to a lower end cap of the frame elements, to control a vertical displacement of the floating calorimeter unit. 20 . The system of claim 2 , wherein the injection device comprises at least one of a microfluidic injector, a dip pen, and a micro pipette. 21 . A system for calorimetry, the system comprising: a well having a volume for receiving a sample; an input feature configured to facilitate reception of the sample in the well; a light source configurable to irradiate the well and the sample with incident light; a photonic sensor chip disposed at the bottom of the well, the photonic sensor chip comprising plural nanohole array (NHA) sensors integrated upon a substrate; a light detector configured to measure transmission of light through the NHA sensors to obtain a series of extraordinary optical transmission (EOT) measurements; frame elements configured to secure and mutually couple the light source, the photonic sensor chip, the light detector, and the input feature to form a floating calorimetry unit; wherein the input feature includes a plurality of diffusion features disposed through a frame element forming a wall of the well, the plurality of diffusion features configured, while the floating calorimetry unit is immersed in and suspended in a fluid, to permit a volume of the fluid including the sample to flow into the well; and a processor configured to calculate a calorimetry measurement as a function of the series of EOT measurements, the calorimetry measurement being indicative of energy released as a result of the sample in the well undergoing a change. 22 . The system of claim 21 , further comprising a floating material connected to an upper end cap of the frame elements and at least one anchor connected to a lower end cap of the frame elements, to control a vertical displacement of the floating calorimete