Abstract: The present disclosure relates to a novel class of bifunctional molecules that are useful in a targeted or selective degradation of a protein.

Abstract: Methods for an instrument including a light source of are provided. A method for an instrument including a light source includes providing light from the light source to a target location in a process chamber. The method includes receiving the light at a sensor. The method includes determining, using data from the sensor, a first position of the light at the target location. Moreover, the method includes determining whether to adjust the light to a second position at the target location. Related instruments are also provided.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Methods for an instrument including a light source of are provided. A method for an instrument including a light source includes providing light from the light source to a target location in a process chamber. The method includes receiving the light at a sensor. The method includes determining, using data from the sensor, a first position of the light at the target location. Moreover, the method includes determining whether to adjust the light to a second position at the target location. Related instruments are also provided.

Abstract: Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Abstract: Disclosed are systems and methods for manipulating chemical, biological, and/or biochemical samples, optionally supported on substrates and/or within chambers, for example biological samples contained on chips, within biological chambers, etc. In certain embodiments, an apparatus configured to be able to position a chamber or other substrate in one or more modules surrounding the apparatus is disclosed. The apparatus may be configured to be able to move the chamber or substrate in any set of directions, such as radially, vertically, and/or rotationally, with respect to the apparatus. The apparatus may be manually operated and/or automatically controlled. Examples of modules include, but are not limited to, stacking or holding modules, barcode readers, filling modules, sampling modules, incubation modules, sensor modules (e.g., for determining cell density, cell viability, pH, oxygen concentration, nutrient concentration, fluorescence measurements, etc.), assay modules (e.g.

Abstract: Fluid transfer devices described herein can include a body portion and a tip portion. A fluid pathway extends through the body and tip portions through which fluid may be transferred, for example, from a fluid-dispensing apparatus to a fluidic chamber of a microreactor. In some embodiments, the fluid transfer device is connected to the fluid-dispensing apparatus with an engaging element. The engaging element may be part of the body, and can enable the dispensing apparatus to repeatedly engage the body at one predetermined position. The body is capable of storing the fluid received from the dispensing apparatus. The tip portion may be formed of a rigid material (e.g., a metal), and/or may be configured to repeatedly pierce a septum without damaging either the tip or the body. Advantageously, in certain embodiments, the fluid transfer device can controllably transfer small volumes of fluid (e.g., 1 ?L) with a high degree of accuracy.

Abstract: The present invention generally relates to chips, particularly microfluidic chips, that are rotatable and/or have a generally circular or rotationally symmetric geometry. The chips may be substantially planar in certain instances. In some cases, the chips of the invention can have more than one reaction site, which can, for example, contain cells. The reaction site can be very small, in some cases with a volume of less than about 1 ml. Reactions, transport, and/or other manipulations within the chip can be facilitated by rotating the chip, for example, at tens, hundreds or thousands of revolutions per minute (RPM). In some cases, data may also be written to and/or read from the chip. The chips of the invention can be used, for example, to move fluid from one portion of a chip to another, to concentrate and/or separate a mixture (e.g., a cell suspension), to lyse or fractionate a cell, or the like.

Abstract: Disclosed are systems and methods for manipulating chemical, biological, and/or biochemical samples, optionally supported on substrates and/or within chambers, for example biological samples contained on chips, within biological chambers, etc. In certain embodiments, an apparatus configured to be able to position a chamber or other substrate in one or more modules surrounding the apparatus is disclosed. The apparatus may be configured to be able to move the chamber or substrate in any set of directions, such as radially, vertically, and/or rotationally, with respect to the apparatus. The apparatus may be manually operated and/or automatically controlled. Examples of modules include, but are not limited to, stacking or holding modules, barcode readers, filling modules, sampling modules, incubation modules, sensor modules (e.g., for determining cell density, cell viability, pH, oxygen concentration, nutrient concentration, fluorescence measurements, etc.), assay modules (e.g.

Abstract: The present invention provides techniques for conveniently and reliably storing and/or retrieving data associated with a chemical, biological, or biochemical chip, reactor, or reaction system. The data can pertain to the reactor; to chemical, biological, or biochemical species introduced into, taken from, or otherwise associated with the reactor; to conditions to which the reactor and/or some or all of its contents has been, is being, or will be exposed to, or the like. Various aspects of the present invention relate to memory and data storage components suitable for use in chips or other reaction systems. These components may include silicon integrated circuits, magnetic media, optical media, radio-frequency tags, smart cards, bar-codes and other kinds of data storage devices. The chip may contain a reaction site having a volume of less than about 2 ml. In some embodiments, the chip may be constructed in such a way as to be able to support a living cell.

Abstract: This disclosure generally relates to systems and methods for manipulating chambers and other substrates for chemical, biological, or biochemical samples, such as cell culture and other chambers, within units such as incubators. In certain embodiments, the invention provides a technique for maintaining a plurality of substrates or chambers in a housing within which a predetermined environment is maintained, different from the environment external to the housing, and moving substrates or chambers in and out of the housing, in some cases without creating a large opening in the housing (e.g., by opening a door significantly larger than the substrates). A technique is provided, in certain embodiments, in which a plurality of substrates are mounted in fixed, secured relation to each other within a housing providing a predetermined, controlled environment, and are moved within the housing so that they can be evenly exposed to any differences in environment within the housing.

Abstract: An adaptive control system for reducing undesired signals comprises a processor (36) which provides secondary signals for sources (37) for interference with the undesired signals. Sensors (42) measure the residual Vibration which is indicative of the interference between the undesired and secondary signals. The processor (36) uses the residual signal to adjust the secondary signals to reduce the residual signals. Noise generation means (48) is provided to add a low level noise signal to the secondary signal and to provide a low level noise signal to the processor (36). The processor (36) is adapted to transform the low level noise signal and the residual signal from sensors (42) to provide the amplitude and phase of spectral components of the signals. The processor (36) modifies the secondary signals using these spectral components to obtain better reduction of the undesired signals.

Abstract: An adaptive control system for reducing undesired signals comprises sensors (31) to provide signals indicative of the undesired signals, and a processor (36) which processes the first signal to provide a secondary signal for output to sources (37) to interfere with the undesired signals. Sensors (42) are provided to detect the residual signals which are indicative of the interference between the undesired and secondary signals. Within the processor the signals indicative of the undesired signals and the residual signals are transformed into the frequency domain and collated. The outcome of the collation is inverse transformed and the processor adjusts the secondary signal using this inverse transform to reduce the residual signal from the sensors (42).

Abstract: A glory hole silo comprising a cylindrical casing open at the upper end thereof; an upwardly open porch for supporting a flowline, said porch extending horizontally from and cantilevered with respect to said casing, the upper surface of said porch opening to the interior of said casing and provided with means communicating with the interior of said casing for attaching a flowline; and a removable roof extending over the open upper end of said casing and porch. The porch structure permits flowlines to be readily connected without the intervention of a diver.

Abstract: The flat-plate type wind turbine rotor blade comprises a rigid spoke having a single thin flexiblie skin associated therewith. The skin is formed to provide a delta-wing and a flap extension. The delta-wing and the flap extension are angularly disposed at about 25.degree. to each other. The spoke lies along the junction of the delta-wing and the flap extension. A substantially rigid peripheral member extends along the margin of the skin. The peripheral member and the spoke are joined to provide a frame to which the skin is secured. Arrays of parallel reinforcing rib members extend between the spoke and the peripheral member. These rib members are mounted on the pressure surface of the skin. The ribs on the delta-wing are positioned at an angle of about 60.degree. from the axis of the spoke; the ribs on the flap extension are positioned at an angle of about 75.degree. from said axis. They therefore coincide with the main flow paths of the air flow over the blade surface.