Disclosed herein include methods, compositions, and kits enabling expression of multiple proteins from a single mRNA with a predetermined stoichiometry. There are provided, in some embodiments, nucleic acid compositions comprising a promoter operably linked to a polynucleotide comprising a first nucleic acid unit encoding first unit payload protein(s) and a second nucleic acid unit encoding second unit payload protein(s). The first nucleic acid unit and the second nucleic acid unit can each comprise a 3′ engineered translation initiation site (eTIS) comprising a three-nucleotide tunable element immediately upstream of a start codon. The eTIS of each of the first nucleic acid unit and the second nucleic acid unit can be configured to achieve a predetermined stoichiometry of the first unit payload protein(s) and the second unit payload protein(s) in a cell or cell-like environment.

The present disclosure provides imaging agents that are useful for the detection and evaluation of heart conditions, such as myocardial infarction. Upon activation, the imaging agents of the present disclosure may be detected using an ultrasound imaging device.

The present invention relates to ultrasound mediated delivery of antimicrobial agents to sites of infection, and particularly for treatment of infections. Thus, the invention provides a cluster composition and a pharmaceutical composition, for use in delivery and preparation for administration of antimicrobial agents and treatment of infections.

Disclosed herein include methods, compositions, and kits suitable for use in dynamic non-destructive imaging. The non-destructive imaging can be nonlinear ultrasound imaging. There are provided, in some embodiments, nucleic acid compositions encoding gas vesicles (GVs) capable of producing nonlinear ultrasound contrast upon expression in a prokaryotic cell (e.g., a probiotic bacterial cell) or a eukaryotic cell (e.g., a therapeutic mammalian cell).

Disclosed herein include methods, compositions, and kits suitable for use in dynamic non-destructive imaging. The non-destructive imaging can be nonlinear ultrasound imaging. There are provided, in some embodiments, nucleic acid compositions encoding gas vesicles (GVs) capable of producing nonlinear ultrasound contrast upon expression in a prokaryotic cell (e.g., a probiotic bacterial cell) or a eukaryotic cell (e.g., a therapeutic mammalian cell).

The present disclosure relates to the field of polymer chemistry and more particularly to poly(sarcosine) polymers and uses thereof. The disclosure is also directed to compositions comprising a protein and a poly(sarcosine) polymer and uses thereof.

Cancer treatment methods using thermotherapy and/or enhanced immunotherapy are disclosed herein. In one embodiment, the method comprising the steps of: (i) applying controlled thermal energy at 40-43° C. for a first predetermined time period to damage and weaken tumor cells of a tumor in a patient; (ii) administering pulsed high intensity focused ultrasound (pHIFU) in a first ultrasound mode to the tumor cells in the patient so as to damage the tumor cells without increasing the thermal energy; and (iii) administering low intensity focused ultrasound (LIFU) in a second ultrasound mode to further damage the tumor cells at a temperature of 39-43° C. for a second predetermined time period while performing observation of the tumor cells by ultrasonic thermometry.

The present invention generally relates to the field of ultrasound contrast-agents (USCA). In particular, it relates to a freeze-dried composition comprising an amphiphilic material and a mixture of freeze-drying protecting components, which may be reconstituted for preparing a suspension of gas-filled microvesicles with calibrated size, useful in diagnostic or therapeutic applications. It further relates to the method for the preparation of such freeze-dried composition.

The present disclosure provides novel modified nanodroplets with a layerby-layer (LBL) assembly formulation (“LBLnNDs”). The LBLnNDs of the present disclosure comprise gaseous perfluorocarbon core, polymer shell, and multiple alternating positively and negatively charged biopolymer layers dispersed layerby-layer onto the shell of the LBLnNDs. Methods of making and use of the LBLnNDs are also provided.

The presently disclosed drug-loaded liposomal conjugated to polymer microbubbles showed: i) increased tumor drug concentration; ii) reduced tumor growth; and ii) increased survival time in a mouse cancer model when exposed to concurrent high and low acoustic pressure ultrasonic pulses as compared to individual high or low acoustic pressure ultrasonic pulses. Notably, when unconjugated drug-loaded liposome were administered with free microbubbles and exposed to concurrent high and low acoustic pressure ultrasonic pulses, a superior tumor growth inhibition was also seen. Three weeks after treatments, DoxLPX+US group showed significantly better left ventricular function indices from echocardiography imaging than the free Dox group. Clinical methods using these liposomal conjugated microbubbles permit an increased therapeutic drug delivery and improved safety profile, respectively due to enhanced, preferential drug accumulation in target tumor tissue and simultaneously reduced drug delivery to non-target tissue.