A system for electronically and optically monitoring biological samples, the system including: a multi-well plate having a plurality of wells configured to receive a plurality of biological samples, each of the wells having a set of electrodes and a transparent window on a bottom surface of the well that is free of electrodes; an illumination module configured to illuminate the wells; a cradle configured to receive the multi-well plate, the cradle having an opening on the bottom that exposes the transparent windows of the wells; and an optical imaging module movable across different wells of a same multi-well plate to capture images through the windows.

A bioreactor for culturing cells in a liquid environment is provided that is designed to reduce the chance of contamination, contain the contamination should it occur, and readily clean and sterilize all or part of the bioreactor in response to contamination, or on a schedule. A processor-controlled method of promoting sterility in a bioreactor is also provided.

A cell permeabilizing microfluidic system for permeabilizing one or more cells in a fluid flow. The system has a microfluidic channel for channeling at least one cell in a fluid flow and an optical source for generating a beam of light for permeabilizing the at least one cell, wherein the channel and the source are arranged so that the light beam and fluid flow are collinear in a permeabilization part of the channel and cells are permeabilized within the permeabilization part.

Disclosed herein are bioreactors that include a container for holding fluid aligned on a vertical axis, wherein at least a portion of the container is oriented at an angle relative to the vertical axis, wherein the angle is from about 0 to 90. In some embodiments, the container is placed on a support structure with portions of the container oriented at alternating angles. The system is essentially closed except for at least one opening (for example an opening at the bottom edge) that allows for the introduction of gases and/or nutrients. The gas and/or nutrients are introduced in such a way as to provide mixing and aeration of a cell culture in the bioreactor. Also disclosed are methods of culturing cells (such as microalgae, macroalgae, bacteria, fungi, insect cells, plant cells, animal cells, or plant or animal tissue or organs) using a bioreactor described herein.

A bioreactor (30) for production and harvesting of microalgae is described, comprising a reactor basin (32) in the form of a tank arranged to receive CO2 and water as well as algae, and which is equipped with at least one outlet for harvesting of algal biomass, where the reactor basin (32) comprises a rotating beam (54) equipped with one or more tillable mixing grates (60) and harvesting grates (62).

The invention relates to a solar lens panel (2) comprising a number of light collecting elements (2) placed next to one another and a number of light guides (4) corresponding to the number of light collecting elements (3); one light guide (4) including a light incident surface (5) is assigned to each light collecting element (3), and each light guide (4) is retained in a holding element (14) at a distance (8) from the light collecting elements (3); said distance (8) between the light collecting elements (3) and the light incident surfaces (5) of the light guides (4) corresponds at least approximately to the focal length of the light collecting elements (3). The light incident surfaces (5) of the light guides (4) are located inside the holding elements (14).

An object moving device includes: a first drive mechanism configured to move a head unit in a first direction and in a second direction; a second drive mechanism configured to move an illumination unit in the first direction; and a third drive mechanism configured to move a camera unit in the first direction. A control unit controls the first drive mechanism to move the head unit on a first path. The control unit controls the second and third drive mechanisms to move the illumination unit and the camera unit on the first path between the first container and the second container. When the head unit and the illumination unit interfere with each other on the first path, the control unit implements control such that the head unit moves in the second direction and the head units moves in the first direction on a second path parallel to the first path.

A photobioreactor has an optical waveguide formed at least in part from a highly scattering optically transmitting polymer. The optical waveguide has a light distributing part immersed in a container holding photoactive biological material and a light collecting part outside the container.

A culture container includes a first transparent member being capable of keeping a predetermined temperature; a second transparent member facing to the first transparent member; a housing member to which the first transparent member and the second transparent member are adhered forming a culture space being capable of housing a well plate together with the first transparent member and the second transparent member; and a sealing member for sealing a liquid injected into the culture space between the first transparent member and the housing member.

Embodiments described herein provide systems for optimizing organism growth, destruction or repair, by controlling the duty cycle, wavelength band and frequency of photon bursts to an organism, through the high frequency modulation of photons in an individual color spectrum to the organism, where the photon modulation is based upon the specific needs of the organism. Devices for the optimization of organism growth, destruction or repair through the high frequency modulation of photons of individual color spectrum to the organism are also provided. Further provided are methods for the optimization of organism growth, destruction or repair through the use of high frequency modulation of photons of individual color spectrums.