Abstract: Disclosed are compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are compositions comprising a previously cryopreserved umbilical tissue, wherein after cryopreservation and subsequent thawing the umbilical tissue comprises: a) viable cells native to the umbilical tissue; b) tissue integrity of native umbilical tissue; c) one or more growth factors that are native to the umbilical tissue; and d) depleted amounts of one or more types of functional immunogenic cells. Disclosed are methods of producing compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are methods of treating damaged tissue comprising administering to the site of the damaged tissue compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels.

Abstract: This invention provides disrupted cartilage products, methods of manufacturing disrupted cartilage products, and methods of treating a subject comprising administering a cartilage product. The cartilage products are manufactured by a method comprising disrupting a collagen matrix, e.g. to produce a flexible cartilage product. Optionally, the cartilage products comprise viable chondrocytes, bioactive factors such as chondrogenic factors, and a collagen type II matrix. Optionally, the cartilage products are non-immunogenic.

Abstract: This invention provides porated cartilage products and methods of producing porated cartilage products. Optionally, the cartilage products are sized, porated, and digested to provide a flexible cartilage product. Optionally, the cartilage products comprise viable chondrocytes, bioactive factors such as chondrogenic factors, and a collagen type II matrix. Optionally, the cartilage products are non-immunogenic.

Abstract: Disclosed are methods of lyophilizing a tissue sample comprising obtaining a tissue sample, contacting the tissue sample with a lyoprotectant solution, freezing the tissue sample, performing a first drying step of the tissue sample after freezing, and performing a second drying step of the tissue sample after the first drying step. Disclosed are lyophilized tissues prepared using the disclosed methods of lyophilizing a tissue sample comprising obtaining a tissue sample, contacting the tissue sample with a lyoprotectant solution, freezing the tissue sample, performing a first drying step of the tissue sample after freezing, and performing a second drying step of the tissue sample after the first drying step. Disclosed are methods of treating a wound or tissue defect comprising administering a reconstituted lyophilized tissue to the wound or tissue defect.

Abstract: Provided herein is a bone repair composition that is composed of periosteum containing an angiogenic growth factor(s), cancellous bone chips containing viable osteogenic cells, and, optionally, demineralized bone matrix (DBM) chips. Also provided herein are articles of manufacture and methods of use thereof to treat bone defects.

Abstract: This invention provides porated cartilage products and methods of producing porated cartilage products. Optionally, the cartilage products are sized, porated, and digested to provide a flexible cartilage product. Optionally, the cartilage products comprise viable chondrocytes, bioactive factors such as chondrogenic factors, and a collagen type II matrix. Optionally, the cartilage products are non-immunogenic.

Abstract: Disclosed are compositions comprising a non-homogenized chorionic matrix, a homogenized amniotic matrix and a homogenized UC (UC) matrix, wherein the non-homogenized chorionic matrix comprises viable cells. Disclosed are methods of making the compositions disclosed herein comprising preparing a non-homogenized chorionic matrix, preparing a homogenized amniotic matrix, preparing a homogenized UC matrix, and combining the non-homogenized chorionic matrix, the non-homogenized chorionic matrix, and the homogenized UC matrix. Disclosed are methods of treating a tissue injury or chronic pain comprising administering any of the disclosed compositions to an area of a subject comprising a tissue injury.

Abstract: Disclosed are compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are compositions comprising a previously cryopreserved umbilical tissue, wherein after cryopreservation and subsequent thawing the umbilical tissue comprises: a) viable cells native to the umbilical tissue; b) tissue integrity of native umbilical tissue; c) one or more growth factors that are native to the umbilical tissue; and d) depleted amounts of one or more types of functional immunogenic cells. Disclosed are methods of producing compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are methods of treating damaged tissue comprising administering to the site of the damaged tissue compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels.

Abstract: Provided herein is a placental product comprising an immunocompatible amniotic membrane. Such placental products can be cryopreserved and contain viable therapeutic cells after thawing. The placental product of the present invention is useful in treating a patient with a tissue injury (e.g. wound or burn) by applying the placental product to the injury. Similar application is useful with ligament and tendon repair and for engraftment procedures such as bone engraftment.

Abstract: The disclosure relates to techniques for triggering magnetic resonance data acquisition. The techniques include detecting a respiration direction of a respiration signal of an acquisition subject, predicting in real time an amplitude peak value of an expiration signal in the current respiration period according to the real-time respiration signal of the acquisition subject, multiplying the amplitude peak value by a preset coefficient, and using the product as a trigger point threshold of the current respiration period. When it is determined that an expiration stage of the current respiration period is starting, the techniques also include calculating in real time or periodically the absolute value of the difference between the amplitude of the current expiration signal and the trigger point threshold currently calculated, and if the absolute value of the difference is less than a preset difference threshold, then triggering MR data acquisition.

Abstract: Provided herein is a placental product comprising an immunocompatible amniotic membrane. Such placental products can be cryopreserved and contain viable therapeutic cells after thawing. The placental product of the present invention is useful in treating a patient with a tissue injury (e.g. wound or burn) by applying the placental product to the injury. Similar application is useful with ligament and tendon repair and for engraftment procedures such as bone engraftment.

Abstract: A support assembly for supporting a biological product (e.g., membrane) in an operative position. The support assembly has a base and a cover. A membrane receiving portion of the base defines a plurality of perforations that extend between top and bottom surfaces of the product receiving portion. The cover is releasably coupled to the base in a product-covering position in which the cover overlies the product receiving portion of the base. In the operative position, the biological product engages the top surface of the product receiving portion and the bottom surface of the cover.

Abstract: The present disclosure provides techniques for determining a respiration phase by extracting a distance characteristic value, a score characteristic value, and an area characteristic value from the respiration signal, wherein the distance characteristic value, the score characteristic value and the area characteristic value are used to indicate waveform variation between two adjacent waveforms in the respiration signal. The techniques include training a respiration signal model according to the distance characteristic value, the score characteristic value, and the area characteristic value to determine the respiration phase of the respiration signal using the respiration signal model.

Abstract: In a method, device and digital receiver for transmitting signals in magnetic resonance imaging, M channels of digital signals are received over M receiving channels from a digital matrix processor. One receiving channel corresponds to one channel of digital signal and the M channels of digital signals include one channel of main signal and (M?1) channels of high-order signals. The M channels of digital signals are combined into N channels of combined signals, wherein the main signal and at least one channel of high-order signal are combined into one channel of combined signal, or at least two channels of high-order signals are combined into one channel of combined signal. N and M are both positive integers, N is less than M, and M is greater than or equal to 2.

Abstract: Provided herein is a bone repair composition that is composed of periosteum containing an angiogenic growth factor(s), cancellous bone chips containing viable osteogenic cells, and, optionally, demineralized bone matrix (DBM) chips. Also provided herein are articles of manufacture and methods of use thereof to treat bone defects.

Abstract: This invention provides porated cartilage products, methods of producing porated cartilage products, and methods of treating subjects by administering cartilage products. Optionally, the cartilage products are sized, porated, and digested to provide a flexible cartilage product. Optionally, the cartilage products comprise viable chondrocytes, bioactive factors such as chondrogenic factors, and a collagen type II matrix. Optionally, the cartilage products are non-immunogenic.

Abstract: Disclosed are compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are compositions comprising a previously cryopreserved umbilical tissue, wherein after cryopreservation and subsequent thawing the umbilical tissue comprises: a) viable cells native to the umbilical tissue; b) tissue integrity of native umbilical tissue; c) one or more growth factors that are native to the umbilical tissue; and d) depleted amounts of one or more types of functional immunogenic cells. Disclosed are methods of producing compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels. Also disclosed are methods of treating damaged tissue comprising administering to the site of the damaged tissue compositions comprising umbilical tissue, wherein the umbilical tissue comprises one or more engineered channels.

Abstract: Provided herein is a bone repair composition that is composed of periosteum containing an angiogenic growth factor(s), cancellous bone chips containing viable osteogenic cells, and, optionally, demineralized bone matrix (DBM) chips. Also provided herein are articles of manufacture and methods of use thereof to treat bone defects.

Abstract: A digital mode matrix phase calibration includes acquiring an actual phase deviation ??mn forming an actual phase deviation matrix ?? of a factory system; calculating an ideal phase deviation forming an ideal phase deviation matrix; calculating a phase deviation of the actual phase deviation and the ideal phase deviation; acquiring a maximum value of the phase deviation; when the maximum value ??max is less than a preset threshold ?, calculating a field system phase deviation ??mn, and a field system phase deviation matrix ?? formed by the field system phase deviation ??mn subjecting a field system to phase calibration. By acquiring only one row and one column in the phase deviation matrix, the technical solution in embodiments of the present invention can fit phase deviations of other rows and columns, and the method subjects the system to phase calibration quickly.

Abstract: Provided herein is a placental product comprising an immunocompatible chorionic membrane. Such placental products can be cryopreserved and contain viable therapeutic cells after thawing. The placental product of the present invention is useful in treating a patient with a tissue injury (e.g. wound or burn) by applying the placental product to the injury. Similar application is useful with ligament and tendon repair and for engraftment procedures such as bone engraftment.