Patent Description:
As specified by the claims, the present invention relates to improved pharmaceutical formulations of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof and a tonicity modifier in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM>, and methods of using the formulations of exendin (<NUM>-<NUM>) for treating or preventing hyperinsulinemic hypoglycemia that includes post-bariatric hypoglycemia (PBH), and so relates to the fields of medicine, medicinal chemistry, pharmacology, chemistry, and biology.

Insulin is a hormone secreted to control high blood glucose levels. Abnormal increases in insulin secretion can lead to profound hypoglycemia that can result in seizures, brain damage and death. Glucagon-like peptide-<NUM> (GLP-<NUM>) is a gastrointestinal hormone that is released postprandially from intestinal L-cells and binds to GLP-<NUM> receptors on beta cells of the pancreas, thereby enhancing insulin release. In patients with PBH, GLP-<NUM>-mediated insulin secretion is exaggerated.

Approximately <NUM>,<NUM>-<NUM>,<NUM> bariatric surgical procedures are performed in the United States each year. As the number of bariatric surgeries to treat severe obesity has increased, so too has the number of individuals who experience PBH. Accordingly, there is a growing unmet need for a therapy that safely and effectively mitigates hyperinsulinemic hypoglycemia and PBH.

Exendin (<NUM>-<NUM>) is a <NUM>-amino acid peptide that selectively targets and blocks glucagon-like peptide-<NUM> (GLP-<NUM>) receptors, normalizing insulin secretion by the pancreas in patients with PBH, thereby reducing hypoglycemia. Exendin (<NUM>-<NUM>) re-constituted in saline for intravenous or subcutaneous administration is currently undergoing human clinical trials as a treatment for PBH (Stanford Clinical Trials, Clinicaltrials. , clinical trials identifiers: NCT02771574 and NCT02550145). However, there remains a need for improved liquid pharmaceutical formulations of exendin (<NUM>-<NUM>) that provide improved potency, purity, and stability. <CIT> describes [<NUM>I] exendin <NUM>-<NUM> in an assay buffer at pH <NUM>. <CIT> describes as useful the inhibitory fragment comprising exendin-<NUM>(<NUM>-<NUM>). e2) describes lyophilized synthetic exendin (<NUM>-<NUM>) dissolved in <NUM>% human serum albumin, and its infusion.

Liquid pharmaceutical formulations as specified by the claims comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof in a physiological buffer having a pH in the range of about <NUM> to about <NUM> are provided. In some embodiments, the liquid pharmaceutical formulation comprises the pharmaceutically acceptable salt exendin (<NUM>-<NUM>) acetate or exendin (<NUM>-<NUM>) trifluoroacetate.

In some embodiments, the physiologically acceptable buffer is an acetate buffer, a citrate buffer, a phosphate buffer, or a histidine buffer. In some embodiments, the physiologically acceptable buffer is sodium acetate or sodium citrate. In some embodiments, the buffering agent (e.g., sodium acetate or sodium citrate) is present in the formulation at a concentration from about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the buffering agent (e.g., sodium acetate or sodium citrate) is present in the formulation at a concentration from about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>) (e.g., from <NUM> mmol. L-<NUM> (<NUM>) to <NUM> mmol. L-<NUM> (<NUM>)). In some embodiments, the physiologically acceptable buffer comprises sodium acetate at a concentration of about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), or about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises sodium acetate at a concentration of about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises sodium citrate at a concentration of about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises sodium acetate at a concentration of at least <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises sodium citrate at a concentration of at least <NUM> mmol. L-<NUM> (<NUM>).

As specified by the claims, the buffered liquid formulation comprises a tonicity modifier. In some embodiments, the tonicity modifier comprises mannitol, dextrose, glycerin, lactose, sucrose, trehalose, or a mixture thereof. In some embodiments, the tonicity modifier is mannitol. In some embodiments, the tonicity modifier is present at a concentration of about <NUM> to about <NUM>/ml. In some embodiments, the tonicity modifier is present at a concentration of about <NUM>/ml. In some embodiments, the tonicity modifier is present at a concentration of at least <NUM>/ml. In some embodiments, the tonicity modifier is added to target an isophysiological osmolality of about <NUM> mOsm/kg.

In some embodiments, the buffered liquid formulation has a pH of at least pH <NUM> to about pH <NUM>. In some embodiments, the buffered liquid formulation comprises a buffer having a pH in the range of <NUM> to <NUM>. In some embodiments, the buffer has a pH of about <NUM>.

In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration (e.g., peptide concentration) of about <NUM> to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml). In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM> to about <NUM>/ml, e.g., from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, or from about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml). In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM>/ml, <NUM>/ml, <NUM>/ml, or <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of at least <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration above <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of at least <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM>/ml. In some embodiments, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof at a concentration of about <NUM>/ml.

As specified by the claims, the exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof does not exhibit visible aggregation in the formulation. In some embodiments, the buffered liquid formulation comprising exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof does not exhibit detectable aggregation of the exendin (<NUM>-<NUM>) or pharmaceutically acceptable salt thereof. In some embodiments, the buffered liquid formulation does not exhibit detectable aggregation of the exendin (<NUM>-<NUM>) or pharmaceutically acceptable salt thereof, as determined by whether the buffered liquid formulation remains as a non-gelatinous solution when stored at <NUM> for <NUM>, <NUM>, <NUM>, <NUM> or <NUM> hours. In some embodiments, the buffered liquid formulation does not exhibit detectable aggregation of the exendin (<NUM>-<NUM>) or pharmaceutically acceptable salt thereof, as determined by visual or light microscopy inspection of the buffered liquid formulation for aggregation or precipitation when stored at <NUM> for <NUM>, <NUM>, <NUM>, <NUM> or <NUM> hours.

In some embodiments, the buffered liquid formulation comprising exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof as described herein is formulated for subcutaneous administration. In some embodiments, the buffered liquid formulation is formulated for once a day (QD) or twice a day (BID) subcutaneous administration. In some embodiments, the buffered liquid formulation is administered in the morning, in the evening, or both. In some embodiments, the buffered liquid formulation is administered QD by subcutaneous injection in the morning (e.g., at least <NUM> minutes before a morning meal). In some embodiments, the buffered liquid formulation is administered BID by subcutaneous injection (e.g., in the morning and in the evening).

In some embodiments, a buffered liquid formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof as described herein, when administered to a human subject, exhibits an improved pharmacokinetic profile as compared to a composition comprising the same dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof formulated in <NUM>% normal saline. In some embodiments, the buffered liquid formulation exhibits a higher Cmax of exendin (<NUM>-<NUM>) (e.g., as measured in a plasma sample from a subject administered the formulation) than a composition comprising the same dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof formulated in <NUM>% normal saline.

In another aspect, therapeutic methods using a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein are provided. In some embodiments, methods of treating or preventing hyperinsulinemic hypoglycemia are provided. In some embodiments, methods of treating or preventing post-bariatric hypoglycemia are provided. In some embodiments, a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein is administered to a subject twice daily (BID) at a dosage in the range of <NUM> - <NUM>, e.g., about <NUM>-<NUM> BID or about <NUM>-<NUM> BID, e.g., at a dosage of about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, or about <NUM> BID. In some embodiments, a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein is administered to a subject once daily (QD) at a dosage in the range of <NUM> - <NUM>, e.g., about <NUM>-<NUM> QD, <NUM>-<NUM> QD, <NUM>-<NUM> QD, or <NUM>-<NUM> QD, e.g., at a dosage of about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, or about <NUM> QD. In some embodiments, a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein is administered to a subject at a dosage of about <NUM> QD. In some embodiments, a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein is administered to a subject at a dosage of about <NUM> BID. In some embodiments, methods of treating or preventing hyperinsulinemic hypoglycemia include administration of the buffered liquid exendin (<NUM>-<NUM>) formulation to a subject who has previously had an upper-gastrointestinal procedure, e.g., a bariatric or metabolic procedure (e.g., gastric bypass surgery).

Exendin (<NUM>-<NUM>) is a glucagon-like peptide-<NUM> (GLP-<NUM>) antagonist that selectively blocks GLP-<NUM> receptors present on pancreatic cells, thereby preventing GLP-<NUM>-mediated enhancement of insulin secretion. Exendin (<NUM>-<NUM>) formulated in normal saline (<NUM>% sodium chloride, also referred to herein as "<NUM>% normal saline") has been administered in animal and human clinical studies for the treatment of hyperinsulinemic hypoglycemia. However, in the first clinical study involving subcutaneous injection of exendin (<NUM>-<NUM>) reconstituted in normal saline, an inverse dose-linearity was demonstrated with increasing concentration of injectate solution, suggesting concentration-dependent peptide aggregation and precipitation, with reduced pharmacokinetic exposure and clinical activity at higher concentrations. See, Example <NUM> of <CIT>. Furthermore, as described herein in Examples <NUM> and <NUM>, exendin (<NUM>-<NUM>) in normal saline (not falling within the specified scope of the claims) has been shown to exhibit aggregation leading to lower exposure of exendin (<NUM>-<NUM>) under certain conditions, such as certain storage conditions or at certain concentrations of exendin (<NUM>-<NUM>).

Thus, in one aspect, the present disclosure provides for improved liquid pharmaceutical formulations of exendin (<NUM>-<NUM>) that exhibit reduced aggregation as compared to compositions comprising the same concentration of exendin (<NUM>-<NUM>) formulation in <NUM>% normal saline (not falling within the specified scope of the claims). In another aspect, the present invention provides for formulations of exendin (<NUM>-<NUM>) that exhibit improved pharmacokinetic profiles as compared to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline. In some embodiments, for example as shown in Example <NUM>, the buffered liquid exendin (<NUM>-<NUM>) formulations of the instant disclosure, when administered to a subject, exhibit a higher Cmax for exendin (<NUM>-<NUM>) than a composition comprising the same dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof formulated in <NUM>% normal saline. Additionally, as described in Example <NUM>, it has been found that the buffered liquid exendin (<NUM>-<NUM>) formulations of the instant disclosure confer greater pharmacokinetic exposure with longer duration of action as compared to exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline. Thus, the liquid pharmaceutical formulations of exendin (<NUM>-<NUM>) described herein also provide the advantage of improved pharmacokinetics. Additionally, the liquid pharmaceutical formulations of exendin (<NUM>-<NUM>) described herein can support lower and/or less frequent dosing for the treatment or prevention of hyperinsulinemic hypoglycemia.

The terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting. In this specification and in the claims that follow, reference will be made to a number of terms that shall be defined to have the following meanings unless a contrary intention is apparent. In some cases, terms with commonly understood meanings are defined herein for clarity and/or for ready reference, and the inclusion of such definitions herein should not be construed as representing a substantial difference over the definition of the term as generally understood in the art.

Although any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, the preferred methods and materials are now described.

All numerical designations, e.g., pH, temperature, time, concentration, and molecular weight, including ranges, are approximations which are varied ( + ) or (-) by increments of <NUM> or <NUM>, as appropriate (e.g., pH <NUM> or <NUM>). It is to be understood, although not always explicitly stated, that all numerical designations are preceded by the term "about. " References to ranges include the end-points unless indicated otherwise. For example, administration of a dose of exendin (<NUM>-<NUM>) in the range <NUM>/ml - <NUM>/ml includes administration of <NUM>/ml or <NUM>/ml.

Thus, for example, reference to "a compound" includes a plurality of compounds.

The term "comprising" is intended to mean that the compounds, compositions and methods include the recited elements, but not excluding others. "Consisting essentially of" when used to define compounds, compositions and methods, means excluding other elements that would materially affect the basic and novel characteristics of the claimed invention. "Consisting of" means excluding any element, step, or ingredient not specified in the claim. Embodiments defined by each of these transition terms are within the scope of this invention.

"Exendin (<NUM>-<NUM>)" or "Ex(<NUM>-<NUM>)" or "Ex9" refers to a <NUM> amino acid peptide with an empirical formula of C<NUM>H<NUM>N<NUM>O<NUM>S and a molecular weight of <NUM> Daltons. Exendin (<NUM>-<NUM>) comprises residues <NUM>-<NUM> of the GLP-<NUM> receptor agonist exendin-<NUM> and is a GLP-<NUM> receptor antagonist. See, <NPL>). The amino acid sequence for exendin (<NUM>-<NUM>) is shown as follows: H-Asp-Leu-Ser-Lys-Gln-Met-Glu-Glu-Glu-Ala-Val-Arg-Leu-Phe-Ile-Glu-Trp-Leu-Lys-Asn-Gly-Gly-Pro-Ser-Ser-Gly-Ala-Pro-Pro-Pro-Ser-NH<NUM> (SEQ ID NO: <NUM>). Exendin (<NUM>-<NUM>) has a predicted isoelectric point of <NUM> and has a net charge of -<NUM> at pH <NUM> that increases to a net charge of +<NUM> at pH <NUM>. As used herein, the term "exendin (<NUM>-<NUM>)" also encompasses pharmaceutically acceptable salts of exendin (<NUM>-<NUM>), including but not limited to sulfate, hydrochloride, phosophate, sulfamate, acetate, citrate, lactate, tartrate, methanesulfonate, ethanesulfonate, benzenesulfonate, p-toluenesulfonate, cyclohexylsulfamate and quinate salts. In some embodiments, exendin (<NUM>-<NUM>) is in the form of exendin (<NUM>-<NUM>) acetate or exendin (<NUM>-<NUM>) trifluoroacetate. Where not otherwise specified herein, exendin (<NUM>-<NUM>) acetate is used. Exendin (<NUM>-<NUM>) and pharmaceutically acceptable salts thereof are commercially available (e.g., Bachem (Clinalfa, Läufelfingen, Switzerland)).

As used herein, the term "tonicity modifier" refers to a compound or agent that adjusts the tonicity (osmotic pressure gradient) of a solution to prevent harmful effects that can occur upon administration of a solution that differs significantly from the tonicity of physiologic fluids. In some embodiments, a tonicity modifier comprises mannitol, dextrose, glycerin, lactose, sucrose, trehalose, or a mixture thereof.

As used herein, the term "physiologically acceptable buffer" refers to a solution that is suitable for use in a formulation for administration to a subject and that has the effect of maintaining or controlling the pH of the formulation in the pH range desired for the formulation. In some embodiments, the physiologically acceptable buffer maintains the pH of the formulation in a pH range of about <NUM> to about <NUM>. In some embodiments, the physiologically acceptable buffer maintains the pH of the formulation at a pH above <NUM>. Acceptable buffers include, but are not limited to, acetate buffers, citrate buffers, phosphate buffers, and mixtures thereof.

The term "pharmaceutical formulation" or "pharmaceutical formulation," as used herein, refers to a composition suitable for administration to a subject. Generally a pharmaceutical formulation is sterile, and preferably free of contaminants that are capable of eliciting an undesirable response within the subject (e.g., the compounds in the pharmaceutical formulation are pharmaceutical grade). Pharmaceutical formulations can be designed for administration to subjects or patients in need thereof via a number of different routes of administration, including oral, intravenous, buccal, rectal, parenteral, intraperitoneal, intradermal, intramuscular, subcutaneous, inhalational and the like. In some embodiments, a pharmaceutical formulation as described herein is formulated for subcutaneous administration.

As used herein, a "therapeutically effective amount" is an amount of an active ingredient (e.g., exendin (<NUM>-<NUM>) or its pharmaceutically acceptable salt) that eliminates, ameliorates, alleviates, or provides relief of the symptoms or clinical outcomes for which it is administered.

The terms "treatment," "treating," and "treat," as used herein in reference to administering exendin (<NUM>-<NUM>) to treat hyperinsulinemic hypoglycemia, covers any treatment of a disease in a human subject, and includes: (a) reducing the risk, frequency or severity of hypoglycemic episodes in patients with a history of hyperinsulinemic hypoglycemia, (b) reducing the risk of occurrence of hypoglycemia in a subject determined to be predisposed to the disease, such as a person who has received post-bariatric surgery, but not yet diagnosed as having the disease, (c) impeding the development of the disease; and/or (d) relieving the disease, i.e., causing regression of the disease and/or relieving one or more disease symptoms.

The terms "administer," "administering," and "administration" as used herein, refer to introducing a compound (e.g., exendin (<NUM>-<NUM>)), a composition, or an agent into a subject or patient, such as a human. As used herein, the terms encompass both direct administration, (e.g., self-administration or administration to a patient by a medical professional) and indirect administration (e.g., the act of prescribing a compound or composition to a subject).

"QD" and "BID" have their usual meanings of, respectively, administration of a buffered liquid formulation of exendin (<NUM>-<NUM>) once per day or twice per day. In some embodiments, administration once per day (QD) means that at least <NUM> hours, at least <NUM> hours, or about <NUM> hours elapse between administrations. In some embodiments, administration once per day means administration about every <NUM> hours. In some embodiments, administration twice per day (BID) means that at least <NUM> hours, at least <NUM> hours, at least <NUM> hours, at least <NUM> hours, at least <NUM> hours, or about <NUM> hours elapse between administrations. In some embodiments, administration twice per day means administration about every <NUM> hours.

As used herein, the terms "patient" and "subject" interchangeably refer to an individual (e.g., a human or a non-human mammal) having or prone to a condition that can be treated or prevented by administration of an exendin (<NUM>-<NUM>) formulation as provided herein. In some embodiments, a patient or subject has hyperinsulinemic hypoglycemia. In some embodiments, a patient or subject has previously had a bariatric procedure (e.g., gastric bypass surgery).

As used herein, the terms "aggregate," "aggregation," and "precipitation" are used interchangeably to refer to a physical interaction between exendin (<NUM>-<NUM>) polypeptides in a formulation that results in formation of oligomers, which may form large aggregates that can precipitate from solution. Large aggregates of exendin (<NUM>-<NUM>) may by visible to the naked eye or may be visible using detection methods known in the art, such as light microscopy. Aggregate formation by a polypeptide, such as during storage of a formulation, can adversely affect biological activity of the polypeptide, resulting in loss of therapeutic efficacy of the pharmaceutical formulation. In some embodiments, a formulation comprising exendin (<NUM>-<NUM>) as described herein does not exhibit "detectable aggregation," e.g., upon storage or administration to a subject, when aggregates are not visible by light microscopy (e.g., after a period of time such as <NUM>, <NUM>, or <NUM> hours).

The term "stored" or "storage" as used herein refers to storage of a formulation, e.g., a buffered liquid formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof as described herein, at a specified temperature for a specified period of time. In some embodiments, the formulation is stored for a prolonged period of time (e.g., one month, two months, three months, four months, five months, six months or longer). In some embodiments, the formulation is stored at a temperature of about <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, or <NUM>. In some embodiments, the formulation is stored at a defined temperature for a defined period of time (e.g., at <NUM>) for a defined period of time (e.g., <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, or <NUM> hours) for the purposes of testing one or more properties of the formulation, e.g., for testing whether the formulation exhibits aggregation.

As specified by the claims, buffered liquid formulations are provided that comprise exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM>, the formulation further comprising a tonicity modifier.

As described herein, it has been surprisingly found that certain properties and pharmacokinetic parameters of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof can be modulated by selecting an appropriate exendin (<NUM>-<NUM>) concentration, tonicity modifier, physiologically acceptable buffer, and pH. For example, as described in Example <NUM> below, buffered liquid formulations comprising exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof can be improved with respect to properties such as exendin (<NUM>-<NUM>) aggregation after storage for period of time, potency of exendin (<NUM>-<NUM>) after storage for a period of time, and purity of exendin (<NUM>-<NUM>) after storage for a period of time by the selection of the exendin (<NUM>-<NUM>) concentration, tonicity modifier, physiologically acceptable buffer, and pH.

It has also been found, as described in Examples <NUM> and <NUM> below, that formulations comprising exendin (<NUM>-<NUM>) in a physiologically acceptable buffer having a pH above <NUM>, e.g., a pH in the range of about <NUM> to about <NUM>, exhibit improved pharmacokinetic properties relative to reconstituted lyophilized exendin (<NUM>-<NUM>) known in the art. For example, Example <NUM> shows that subcutaneous injection of a buffered exendin (<NUM>-<NUM>) formulation resulted in a higher Cmax for exendin (<NUM>-<NUM>) in plasma relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof formulated in <NUM>% normal saline. See, <FIG> and <FIG>. Example <NUM> shows that subcutaneous injection of a buffered exendin (<NUM>-<NUM>) formulation resulted in a higher Cmax, a higher <NUM>-hour AUC, and higher trough plasma concentrations of exendin (<NUM>-<NUM>) as compared to reconstituted lyophilized exendin (<NUM>-<NUM>).

As specified by the claims, in some embodiments, the buffered formulation comprises exendin (<NUM>-<NUM>). As specified by the claims, in some embodiments, the formulation comprises a pharmaceutically acceptable salt of exendin (<NUM>-<NUM>). In some embodiments, the formulation comprises the pharmaceutically acceptable salt exendin (<NUM>-<NUM>) acetate or exendin (<NUM>-<NUM>) trifluoroacetate.

In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof at a concentration of about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, or about <NUM>-<NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml). In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml. In some embodiments, the formulation comprises exendin (<NUM>-<NUM>) at a concentration of about <NUM>/ml.

As specified by the claims, the buffered liquid formulation comprises exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM>. In some embodiments, the buffer is compatible with subcutaneous administration. In some embodiments, the physiologically acceptable buffer is at a pH that prevents, limits, or reduces the formation of exendin (<NUM>-<NUM>) aggregates in the liquid pharmaceutical formulation upon storage or administration to a subject.

In one embodiment, a physiologically acceptable buffer comprises a solution having a stable pH over a prolonged period of time (e.g., about <NUM> hour, about <NUM> hours, about <NUM> hours, about <NUM> hours, about <NUM> hours, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> month, or longer). In one embodiment, a physiologically acceptable buffer comprises a solution that stabilizes the functionality of the exendin (<NUM>-<NUM>) during prolonged storage. In one embodiment, the storage can comprise about <NUM> hour, about <NUM> hours, about <NUM> hours, about <NUM> hours, about <NUM> hours, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> days, about <NUM> month, or longer.

As specified by the claims, the buffered liquid formulation comprises a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM> (e.g., a range including <NUM>, <NUM>, <NUM>, <NUM>, <NUM> and <NUM>). In one embodiment, the physiologically acceptable buffer has a pH in the range of <NUM> to <NUM> (e.g., <NUM>, <NUM>, <NUM>, or <NUM>). In one embodiment, the physiologically acceptable buffer has a pH of <NUM>. As specified by the claims, the physiologically acceptable buffer has a pH in the range of about <NUM> to about <NUM>. In one embodiment, the physiologically acceptable buffer has a pH of about <NUM>.

In one embodiment, the physiologically acceptable buffer comprises an acetate buffer, a citrate buffer, a phosphate buffer, a histidine buffer, or a mixture thereof. In one embodiment, the physiologically acceptable buffer comprises sodium acetate, potassium acetate, trisodium citrate, magnesium citrate, potassium citrate, potassium phosphate, or a mixture thereof. In one embodiment, the physiologically acceptable buffer comprises a buffering agent (e.g., sodium acetate) at a concentration from about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), or about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>) (e.g., about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), about <NUM> mmol. L-<NUM> (<NUM>), or about <NUM> mmol. L-<NUM> (<NUM>)). In some embodiments, the physiologically acceptable buffer comprises the buffering agent (e.g., sodium acetate) at a concentration of at least <NUM> mmol. L-<NUM> (<NUM>).

In some embodiments, the physiologically acceptable buffer comprises an acetate buffer. In some embodiments, the buffering agent is sodium acetate. In some embodiments, the buffering agent is potassium acetate. In some embodiments, the physiologically acceptable buffer comprises an acetate buffer (e.g., sodium acetate or potassium acetate) at a concentration of about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), e.g., about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises an acetate buffer (e.g., sodium acetate or potassium acetate) at a concentration of about <NUM> mmol. L-<NUM> (<NUM>).

In some embodiments, the physiologically acceptable buffer comprises a citrate buffer. In some embodiments, the buffering agent is trisodium citrate. In some embodiments, the buffering agent is magnesium citrate. In some embodiments, the buffering agent is potassium citrate. In one embodiment, the physiologically acceptable buffer comprises the citrate buffer (e.g., sodium citrate, magnesium citrate, or potassium citrate) at a concentration from about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), e.g., about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises the citrate buffer (e.g., sodium citrate, magnesium citrate, or potassium citrate) at a concentration of about <NUM> mmol. L-<NUM> (<NUM>).

In one embodiment, the physiologically acceptable buffer comprises a phosphate buffer. In one embodiment, the physiologically acceptable buffer comprises potassium phosphate. In one embodiment, the physiologically acceptable buffer comprises potassium phosphate at a concentration from about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>), e.g., about <NUM> mmol. L-<NUM> (<NUM>) to about <NUM> mmol. L-<NUM> (<NUM>). In some embodiments, the physiologically acceptable buffer comprises the phosphate buffer (e.g., potassium phosphate) at a concentration of about <NUM> mmol. L-<NUM> (<NUM>).

As specified by the claims, the buffered formulation comprises a tonicity modifier. In some embodiments, the tonicity modifier is mannitol, dextrose, glycerin, lactose, sucrose, trehalose, or a mixture thereof. In some embodiments, the tonicity modifier is mannitol. The use of tonicity modifiers is well known in the medicinal arts, and one of skill in the art can use one or more of the tonicity modifiers disclosed herein to provide a liquid pharmaceutical formulation suitable for subcutaneous administration. See, for example, <NPL>); see also,<NPL>).

In some embodiments, the tonicity modifier or combination of tonicity modifiers is present in the formulation at a concentration of about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, about <NUM>-<NUM>/ml, or about <NUM>-<NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml). In some embodiments, the formulation comprises the tonicity modifier at a concentration range of about <NUM>/ml to about <NUM>/ml.

In some embodiments, the tonicity modifier or combination of tonicity modifiers is present in the formulation in an amount that results in the formulation having an isophysiological osmolality. In some embodiments, the tonicity modifier or combination of tonicity modifiers is present in the formulation in an amount that results in the formulation having an osmolality of about <NUM> to <NUM> mOsm/kg (e.g., about <NUM> mOsm/kg, about <NUM> mOsm/kg, about <NUM> mOsm/kg, about <NUM> mOsm/kg, about <NUM> mOsm/ kg, or about <NUM> mOsm/kg). In some embodiments, the tonicity modifier or combination of tonicity modifiers (e.g., mannitol, dextrose, glycerin, lactose, sucrose, trehalose, or a combination thereof) is present in the formulation in an amount that results in the formulation having an osmolality of about <NUM> mOsm/kg.

In some embodiments, the tonicity modifier comprises mannitol. In some embodiments, the mannitol is present at a concentration of about <NUM>-<NUM>/ml. In some embodiments, the mannitol is present at a concentration in the range of about <NUM>/ml to about <NUM>/ml. In some embodiments, the mannitol is present at a concentration of about <NUM>/ml. In some embodiments, the mannitol is present at a concentration of at least <NUM>/ml.

In one embodiment, the tonicity modifier comprises dextrose. In one embodiment, the dextrose is present at a concentration of about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml).

In one embodiment, the tonicity modifier comprises glycerin. In some embodiments, the glycerin is present at a concentration of about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml).

In one embodiment, the tonicity modifier comprises lactose. In one aspect, the lactose is present at a concentration of about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml).

In one embodiment, the tonicity modifier comprises sucrose. In some embodiments, the sucrose is present at a concentration of about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml).

In one embodiment, the tonicity modifier comprises trehalose. In one aspect, the trehalose is present at a concentration of about <NUM>/ml to about <NUM>/ml (e.g., about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml).

In some embodiments, the buffered formulation comprises two or more tonicity modifiers. In some embodiments, the buffered formulation comprises two or more tonicity modifiers selected from the group consisting of mannitol, dextrose, glycerin, lactose, sucrose, and trehalose. In some embodiments, the buffered formulation comprises mannitol at least one other tonicity modifier.

In some embodiments, the formulation further comprises one or more additional excipients such as preservatives, surfactants (e.g., a polysorbate or a poloxamer), or colorants (e.g., pharmaceutically acceptable dyes, inorganic pigments, and natural colorants). A wide variety of pharmaceutically acceptable excipients are known in the art. Pharmaceutically acceptable excipients have been amply described in a variety of publications, including, for example, <NPL>; <NPL>; and <NPL>.

In another aspect, methods of treatment comprising administering a buffered liquid formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof as described herein are provided. In some embodiments, the method comprises administering a buffered liquid formulation of exendin (<NUM>-<NUM>) as described herein in an amount effective to prevent or reduce the symptoms of hyperinsulinemic hypoglycemia. In some embodiments, the method comprises administering a buffered liquid formulation of exendin (<NUM>-<NUM>) as described herein in an amount effective to prevent or reduce the symptoms, metabolic outcomes, and/or clinical outcomes of post-bariatric hypoglycemia.

In some embodiments, a subject to be treated according to the methods described herein is a subject having hyperinsulinemic hypoglycemia (HH). In certain embodiments, the subject having hyperinsulinemic hypoglycemia has previously had bariatric surgery (e.g., Roux-en-Y Gastric Bypass) and/or a related metabolic procedure. In certain embodiments, the subject has previously had bariatric surgery (e.g., Roux-en-Y Gastric Bypass) and/or a related metabolic procedure and is at risk for developing hyperinsulinemic hypoglycemia. In some embodiments, the subject having hyperinsulinemic hypoglycemia has previously had an upper-gastrointestinal procedure, such as gastrectomy or esophagectomy.

"Hyperinsulinemic hypoglycemia," as used herein, encompasses the conditions dumping syndrome, late dumping syndrome, nesideoblastosis, noninsulinoma pancreatogenous hypoglycemia syndrome (NIPHS), and/or post-prandial reactive hypoglycemia. Hyperinsulinemic hypoglycemia may result from a gastric, bariatric, or metabolic procedure, such as a Roux-en-Y gastric bypass (RYGB) or vertical sleeve gastrectomy (VSG), or may have a congenital, acquired, or induced origin.

Subjects with hyperinsulinemic hypoglycemia may be identified by any suitable method. In some embodiments, hyperinsulinemic hypoglycemia is diagnosed by the presence of Whipple's triad, which has the following criteria: (<NUM>) the occurrence of hypoglycemic symptoms; (<NUM>) documented low plasma glucose level at the type of the symptoms; and (<NUM>) resolution of the symptoms after plasma glucose is raised. In some embodiments, hyperinsulinemic hypoglycemia is defined by the occurrence of capillary glucose ≤ <NUM>/dL at least once per month by report by the subject or medical record. In some embodiments, hyperinsulinemic hypoglycemia is defined by a plasma glucose concentration of <<NUM>/dL detected by self-monitoring of plasma glucose, continuous glucose monitoring for at least <NUM> minutes, or a laboratory measurement of plasma glucose. In some embodiments, hyperinsulinemic hypoglycemia is defined by a plasma glucose concentration of ≤<NUM>/dL during an oral glucose tolerance test or meal tolerance test in association with inappropriately elevated plasma insulin (≥<NUM> pmol. L-<NUM> (≥<NUM> uU/mL)) or c-peptide (><NUM>/dL) when glucose was ≤<NUM>/dL. In some embodiments, hyperinsulinemic hypoglycemia is defined by a plasma glucose concentration of ≤<NUM>/dL during an oral glucose tolerance test or meal tolerance test in association with inappropriately elevated plasma insulin (≥<NUM> pmol. L-<NUM> (≥<NUM> uU/mL)) or c-peptide (><NUM>/dL) when glucose was ≤ <NUM>/dL. In some embodiments, hyperinsulinemic hypoglycemia is diagnosed by a positive provocative test, e.g., an oral glucose tolerance test (OGTT) or a mixed meal tolerance test (MMTT). See, <NPL>; see also, <NPL>.

In one embodiment, the subject to be treated has previously had a bariatric procedure and/or related metabolic procedure, such as a Roux-en-Y Gastric Bypass procedure. Bariatric and/or related metabolic procedures include, but are not limited to, Roux-en-Y Gastric Bypass, Vertical Sleeve Gastrectomy, placement of an endosleeve device, such as the EndoBarrier Gastrointestinal Liner System, also called an "endoluminal liner," duodenal mucosal resurfacing, also referred to as duodenal ablation, partial bypass of the duodenum, involving duodeno-ileal or duodeno-jejunal anastomosis, vagal nerve blockade, and/or pyloroplasty).

A bariatric procedure (i.e., bariatric surgery) typically involves any of the foregoing: partially or completely bypassing the duodenum and/or decreasing nutrient exposure to the duodenum, increasing the rapidity of nutrient transit to the lower part of the intestines (often specifically the ileum), and/or otherwise increasing ileal nutrient exposure. Bariatric surgery may be intended for weight loss or metabolic benefit (such as resolution of diabetes), or both. Such weight loss or metabolic procedures, referred to herein as "bariatric procedures" may enhance secretion of GLP-<NUM> from the distal small intestine, especially the ileum, leading to elevated insulin secretion, and in some subjects hypoglycemia. In some embodiments, the subject may be referred to as a "post bariatric surgery" subject or "post-RYGB.

In another embodiment, the subject to be treated has previously had a related metabolic procedure. As but one example, in one embodiment, the subject to be treated has previously had a non-bariatric surgical procedure involving the gastrointestinal system (including but not limited to esophagectomy, for example for treatment of esophageal cancer, Nissen Fundoplication, for example for treatment of gastroesophageal reflux, or gastrectomy, for example for treatment or prevention of gastric cancer) and so may be referred to herein as "post gastrointestinal surgery.

In another embodiment, the subject to be treated is prediabetic and/or insulin resistant and may benefit from prevention of pancreatic hyperstimulation from oral carbohydrate ingestion leading to post-prandial hypoglycemia. In another embodiment, the subject to be treated has a congenital, acquired, or induced form of hyperinsulinemic hypoglycemia, such as congenital hyperinsulinism or sometimes referred to as congenital nesidioblastosis.

Suitable patient populations and methods of identifying patients are also described in PCT Patent Application No. <CIT>.

In some embodiments, the patient is a human patient. In some embodiments, the patient is an adult. In some embodiments, the patient is a juvenile. In some embodiments, the patient is an adult who has previously undergone a bariatric procedure (e.g., gastric bypass surgery).

In some embodiments, a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein is administered by subcutaneous administration (e.g., subcutaneous injection). Sites of injection, include, but are not limited to, injection in the thigh, abdomen, upper arm region, or upper buttock region.

In some embodiments, buffered liquid exendin (<NUM>-<NUM>) formulations of the present disclosure are formulated for subcutaneous administration. In one embodiment, the buffered liquid exendin (<NUM>-<NUM>) formulations of the present invention are formulated for subcutaneous administration according to a once daily (QD) or twice daily (BID) regime.

In some embodiments, the buffered liquid exendin (<NUM>-<NUM>) formulation is formulated as a single-use prefilled syringe, e.g., in a kit comprising multiple single-use prefilled syringes (e.g., <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, or <NUM> prefilled syringes). In some embodiments, the single-use prefilled syringe comprises an exendin (<NUM>-<NUM>) liquid pharmaceutical formulation comprising about <NUM>-<NUM> of exendin (<NUM>-<NUM>), a tonicity modifier, and a buffer having a pH in the range of <NUM> to <NUM>.

In some embodiments, the buffered liquid exendin (<NUM>-<NUM>) formulation is formulated as a sterile, preserved isotonic solution in a unit or multi-dose glass vial or ampule for administration with the use of a syringe, similar to a glucagon emergency kit. In some embodiments, the buffered liquid exendin (<NUM>-<NUM>) formulation is provided as an injectable solution in a single-dose tray containing a vial of a buffered liquid exendin (<NUM>-<NUM>) formulation as described herein (e.g., a formulation comprising about <NUM>-<NUM> of exendin (<NUM>-<NUM>), a tonicity modifier, and a buffer having a pH of about <NUM>, and optionally an appropriate volume of an antimicrobial preservative), a vial connector, a syringe, and one or more needles.

In some embodiments, the buffered liquid exendin (<NUM>-<NUM>) formulation is formulated as a sterile, preserved isotonic solution in a glass cartridge pen-injector device. As a non-limiting example, the formulation comprises about <NUM>-<NUM> of exendin (<NUM>-<NUM>) (e.g., about <NUM>-<NUM> or about <NUM>-<NUM> of exendin (<NUM>-<NUM>)), a tonicity modifier and a buffer having a pH in the range of about <NUM>, and optionally an appropriate volume of an antimicrobial preservative.

In some embodiments, each dose is administered in a total volume ranging from <NUM>-<NUM> injectate, with most subjects administering an injection volume ranging from <NUM>-<NUM>, e.g., <NUM>-<NUM>.

In some embodiments, compositions comprising a therapeutically effective dose of a liquid pharmaceutical formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof and a tonicity modifier in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM> are administered to a subject in need thereof for the treatment or prevention of hyperinsulinemic hypoglycemia.

In one embodiment, the method comprises administering (e.g., subcutaneously administering) a therapeutically effective dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof and a tonicity modifier in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM> to a subject in need thereof. In some embodiments, the therapeutically effective amount of exendin (<NUM>-<NUM>) (or a pharmaceutically acceptable salt thereof) is an amount ranging from about <NUM>/ml to about <NUM>/ml, e.g., from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, from about <NUM>/ml to about <NUM>/ml, or from about <NUM>/ml to about <NUM>/ml. In some embodiments, the therapeutically effective amount of exendin (<NUM>-<NUM>) (or a pharmaceutically acceptable salt thereof) is an amount of about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, about <NUM>/ml, or about <NUM>/ml.

In some embodiments, the method comprises administering (e.g., subcutaneously administering) a buffered liquid formulation of exendin (<NUM>-<NUM>) as described herein at a total daily dosage of exendin (<NUM>-<NUM>) from about <NUM> to about <NUM>, e.g., a total daily dosage of exendin (<NUM>-<NUM>) of about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>. In some embodiments, the buffered formulation is administered at a total daily dosage of exendin (<NUM>-<NUM>) of at least about <NUM>, at least about <NUM>, at least about <NUM>, at least about <NUM>, or at least about <NUM>. In some embodiments, the buffered formulation is administered at a total daily dosage of exendin (<NUM>-<NUM>) of about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, or about <NUM>.

The dosage ranges described above are exemplary adult doses, and may vary depending upon the age and weight of the patient as would be known by those skilled in the pharmaceutical arts. It will be appreciated that in some embodiments, dosage may be increased or decreased during the course of treatment. For example, some physicians may desire to treat with a low or initiating (starting) dose, escalate to an increased dose if the initiating dose does not provide sufficient therapeutic benefit, and maintain the initiating dose if the initiating dose provides sufficient therapeutic benefit.

In some embodiments, a therapeutically effective amount of exendin (<NUM>-<NUM>) (or a pharmaceutically acceptable salt thereof) as a buffered liquid formulation is administered once daily (QD). QD administration is well-known in the medical arts. In some embodiments QD doses are administered (e.g., self-administered) at about <NUM> hour intervals (e.g., <NUM> a. on successive days). However, shorter (e.g., <NUM> a. and <NUM> a. on successive days) or longer (e.g., <NUM> a. and <NUM> a. on successive days) intervals between administration are possible provided the administrations are at least about <NUM> hours apart. Preferably, the administrations are at least about <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, or <NUM> hours apart. Preferably, the administrations are not more than <NUM> hours apart. Although administration once a day is preferred, the dosage administered can occur more frequently (e.g., two times a day) or less frequently (e.g., once every other day).

In some embodiments, the buffered liquid formulation is administered twice daily (BID). BID (twice per day) administration is well known in the medical arts. The buffered liquid formulation can be administered at specific points in the day or schedule of a subject, e.g., morning, afternoon, evening, night, before or during or after meals, before bedtime, etc. In some embodiments, the liquid pharmaceutical formulation is administered about once every <NUM> hours. In some embodiments BID doses are administered (e.g., self-administered) at about <NUM> hour intervals (e.g., <NUM> a. and <NUM> p. However, shorter (e.g., <NUM> a. and <NUM> p. ) or longer (e.g., <NUM> a. and <NUM> p. ) intervals between administrations are possible. In some embodiments, the administrations are at least about <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours or <NUM> hours apart. Preferably the administrations are not more than about <NUM> hours apart. Methods of timing the administration of BID dosing are described, for example, in PCT Patent Application No. <CIT>.

In some embodiments, the buffered liquid formulation is administered (e.g., subcutaneously administered) at a dosage of exendin (<NUM>-<NUM>) in the range of <NUM> - <NUM> BID or <NUM> - <NUM> BID, e.g., about <NUM>-<NUM> BID, about <NUM>-<NUM> BID, about <NUM>-<NUM> BID, about <NUM>-<NUM> BID, or about <NUM>-<NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> BID. In some embodiments, a buffered liquid formulation comprising exendin (<NUM>-<NUM>) at a concentration of <NUM>/ml or higher is administered at a dosage of about <NUM>-<NUM> BID, e.g., at a dosage of about <NUM> BID.

In some embodiments, the buffered liquid formulation is administered (e.g., subcutaneously administered) at a dosage of exendin (<NUM>-<NUM>) in the range of <NUM> - <NUM> QD, e.g., about <NUM>-<NUM> QD, about <NUM>-<NUM> QD, about <NUM>-<NUM> QD, or about <NUM>-<NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, the buffered liquid formulation is administered at a dosage of about <NUM> QD. In some embodiments, a buffered liquid formulation comprising exendin (<NUM>-<NUM>) at a concentration of <NUM>/ml or higher is administered at a dosage of at least <NUM> QD, e.g., at a dosage of <NUM>-<NUM> QD, at a dosage of about <NUM> QD, or at a dosage of about <NUM> QD.

In some embodiments, the buffered liquid formulation is administered (e.g., subcutaneously administered) twice daily (BID) within about <NUM> minutes prior to morning and evening meals (or prior to the two main meals of the day). In some embodiments, the administrations prior to the morning and evening meals (or prior to the two main meals of the day) are at least about <NUM> hours apart. In some embodiments, the administration of the buffered liquid formulation is not timed to meals.

In some embodiments, the buffered liquid formulation is administered (e.g., subcutaneously administered) once daily (QD) in the morning or at night to maximally cover the morning and evening meals. For example, in some embodiments, the formulation is administered at night after the evening meal or early in the morning prior to the morning meal (e.g., at least <NUM> minutes prior to the morning meal).

In some embodiments, the buffered liquid formulation is administered (e.g., subcutaneously administered) twice daily (BID) at different doses. In some embodiments, the formulation is administered in the morning and in the afternoon at different doses. In some embodiments, the formulation is administered in the morning and in the evening or at night at different doses. For example, in some embodiments, the formulation is administered in the morning and in the evening or at night, wherein the evening or night dose is a lower dose than the morning dose.

Subjects who are administered a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein may receive therapy for a predetermined time, an indefinite time, or until an endpoint is reached. Treatment may be continued on a continuous daily or weekly basis for at least two to three months, six months, one year, or longer. In some embodiments, therapy is for at least <NUM> days, at least <NUM> days, at least <NUM> days, at least <NUM> days, at least <NUM> days, or at least <NUM> days. In some embodiments, treatment is continued for at least <NUM> months, at least <NUM> months, at least <NUM> months, at least <NUM> months, at least <NUM> months, at least <NUM> months, or at least one year. In some embodiments, treatment is continued for the rest of the patient's life or until administration is no longer effective to provide meaningful therapeutic benefit.

In some embodiments, a buffered liquid formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof and a tonicity modifier in a physiologically acceptable buffer having a pH in the range of about <NUM> to about <NUM> results in an improved absorption profile of exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof formulated in <NUM>% normal saline. In some embodiments, the buffered liquid formulation results in a higher plasma concentration of exendin (<NUM>-<NUM>) over a period about <NUM>-<NUM> hours (e.g., over <NUM>-<NUM> hours, after about <NUM> hour, after about <NUM> hours, after about <NUM> hours, or after about <NUM> hours) after administration to a subject relative to the plasma concentration of exendin (<NUM>-<NUM>) over or at the same period of time of a subject administered the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline.

In one embodiment, the buffered liquid exendin (<NUM>-<NUM>) formulation of the present disclosure, when administered to a subject, results in a greater increase in plasma concentrations of exendin (<NUM>-<NUM>) over a period of about <NUM> to <NUM> hours (e.g., over <NUM>-<NUM> hours, over <NUM>-<NUM> hours, over <NUM>-<NUM> hours, or over <NUM>-<NUM> hours, after about <NUM> hour, after about <NUM> hours, after about <NUM> hours, or after about <NUM> hours) after administration to a subject, as compared to the increase in plasma concentration over the same period of time of a subject administered a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline solution. In some embodiments, the change in plasma concentration of exendin (<NUM>-<NUM>) is measured about <NUM> hour, <NUM> hours, <NUM> hours, <NUM> hours, <NUM> hours, or <NUM> hours after the exendin (<NUM>-<NUM>) formulation is administered to the subject.

In some embodiments, subcutaneous injection of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein results in a higher Cmax of exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline.

In some embodiments, subcutaneous injection of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein results in a higher AUC of exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline. For example, in some embodiments, subcutaneous injection of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein results in a higher <NUM>-hour AUC of exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline.

In some embodiments, subcutaneous injection of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein results in a later Tmax for exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline.

In some embodiments, subcutaneous injection of a buffered liquid formulation comprising exendin (<NUM>-<NUM>) as described herein results in a higher trough concentration of exendin (<NUM>-<NUM>) relative to a composition comprising the same dose of exendin (<NUM>-<NUM>) formulated in <NUM>% normal saline (e.g., when measured after repeat dosing, such as dosing for at least <NUM> days, dosing for at least <NUM> week, dosing for at least <NUM> weeks, or dosing for at least <NUM> month).

The following examples are provided to illustrate, but not to limit, the claimed invention.

This example describes physical and chemical properties of lyophilized exendin (<NUM>-<NUM>) acetate reconstituted in <NUM>% normal saline as compared to the properties of buffered formulations of exendin (<NUM>-<NUM>).

Different concentrations (<NUM>, <NUM>, <NUM>, <NUM>, and <NUM>/ml) of lyophilized exendin (<NUM>-<NUM>) acetate were prepared by reconstituting in <NUM>% normal saline and stored at <NUM>. The pH of each reconstituted exendin (<NUM>-<NUM>) formulation was recorded at day zero and monitored for up to <NUM> days. All concentrations of the reconstituted exendin (<NUM>-<NUM>) formulations resulted in an initial pH of <NUM> to <NUM>. A visual inspection of each reconstituted exendin (<NUM>-<NUM>) formulation was also noted on day zero and monitored for up to <NUM> days, while being held at <NUM>. No aggregation, gelling or precipitation of reconstituted exendin (<NUM>-<NUM>) formulations was observed in any of the samples held at <NUM> over the <NUM> day period.

Aliquots of each of the reconstituted exendin (<NUM>-<NUM>) formulations (<NUM>, <NUM>, <NUM>, <NUM>, and <NUM>/ml) held at <NUM> for seven days were placed at <NUM> overnight. All of the reconstituted exendin (<NUM>-<NUM>) formulations showed aggregation within <NUM> hrs at <NUM> and the aggregates appeared gelatinous under light microscopy (<FIG>, left panel). After <NUM> hours at <NUM>, the reconstituted exendin (<NUM>-<NUM>) formulations had further aggregated (<FIG>, right panel).

To investigate further the temperature at which the reconstituted exendin (<NUM>-<NUM>) formulations in <NUM>% saline began to precipitate and/or aggregate, aliquots of the <NUM>/ml reconstituted exendin (<NUM>-<NUM>) formulations were stored overnight at <NUM>, <NUM>, <NUM>, <NUM>, and <NUM>. As shown in Table <NUM> below, a visual inspection of the reconstituted exendin (<NUM>-<NUM>) formulations demonstrated that none of the <NUM>/ml reconstituted exendin (<NUM>-<NUM>) formulations stored overnight up to <NUM> precipitated out of solution.

Exendin (<NUM>-<NUM>) acetate was formulated in one of two ionic buffers (an acetate buffer or a citrate buffer) of various ionic strengths (<NUM> mmol. L-<NUM> (<NUM>) to <NUM> mmol. L-<NUM> (<NUM>)) and at different pHs (pH <NUM> to <NUM>). Each sample was stored for up to <NUM> days at <NUM> or <NUM>. The formulations were visually inspected for aggregation, and purity and potency were tested by strong cation exchange (SCX)-HPLC.

As shown in Table <NUM> below, none of the tested buffered exendin (<NUM>-<NUM>) formulations precipitated out of solution at <NUM>. Within <NUM> hours at <NUM>, the formulations at pH <NUM> and <NUM> (not falling within the specified scope of the claims) showed visible aggregation, but for all other formulations no aggregation was visible.

The formulations were analyzed by strong cation exchange-high performance liquid chromatography (SCX-HPLC) for purity and potency over a period of <NUM> days. The effects of storage at <NUM> for <NUM> days on the purity and potency of the exendin (<NUM>-<NUM>) buffered liquid formulations are shown in <FIG> and <FIG>.

As shown in <FIG> and Table <NUM> below, citrate and acetate buffers were comparable with respect to the potency of exendin (<NUM>-<NUM>) at the end of the <NUM>-day storage period. The least loss of exendin (<NUM>-<NUM>) (i.e., last impact on potency) was observed with pH <NUM> (not falling within the specified scope of the claims) and pH <NUM>. Higher buffer strength was associated with more loss of exendin (<NUM>-<NUM>) at the end of the <NUM>-day period. As shown in <FIG> and Table <NUM>, the least decrease in purity was observed for the formulation at a pH of <NUM> (not falling within the specified scope of the claims), while the greatest decrease in purity was observed in the formulation at a pH of <NUM>. Increasing the ionic buffer strength (e.g., from <NUM> mmol. L-<NUM> (<NUM>) to <NUM> mmol. L-<NUM> (<NUM>) or <NUM> mmol. L-<NUM> (<NUM>)) resulted in increased purity loss. The citrate and acetate buffers exhibited comparable activity.

The potency and purity of exendin (<NUM>-<NUM>) formulated in <NUM> mmol. L-<NUM> (<NUM>) acetate buffer at various pH after <NUM> days' storage at <NUM> is shown in <FIG>. As shown in <FIG>, the smallest decreases in exendin (<NUM>-<NUM>) were observed at a pH of <NUM> or lower (not falling within the specified scope of the claims) or at a pH of <NUM> or higher. Potency loss was greatest where aggregation was visible (pH <NUM> and <NUM>, not falling within the specified scope of the claims).

The impurity contributions were plotted against pH for exendin (<NUM>-<NUM>) formulated in <NUM> mmol. L-<NUM> (<NUM>) acetate buffer. <FIG> shows the effects of pH on impurities, measured as the % area contribution.

While not wishing to be bound by a particular theory, it is proposed that formulating exendin (<NUM>-<NUM>) in a buffer above the predicted isoelectric point of exendin (<NUM>-<NUM>) (pH <NUM>) is advantageous because once the formulation is administered (e.g., injected), it does not pass through the isoelectric pH on the transition to the physiological pH of approximately <NUM>. Additionally, formulating exendin (<NUM>-<NUM>) in a buffer at such a pH is expected to result in improved properties, such as improved potency, chemical stability, and less susceptibility to aggregation. In contrast, formulating exendin (<NUM>-<NUM>) in normal saline, which typically has a pH of about <NUM>, may result in an increased likelihood of precipitation or aggregation because such a formulation must pass through the isoelectric pH of exendin (<NUM>-<NUM>) en route to physiological pH.

This example shows that exendin (<NUM>-<NUM>) formulated in a buffer having a pH in the range of about <NUM>-<NUM> exhibits improved pharmacokinetic properties as compared to exendin (<NUM>-<NUM>) reconstituted in normal saline. For this example, exendin (<NUM>-<NUM>) acetate at a dose of <NUM> (equivalent to a dose of <NUM> in humans) was formulated in <NUM> mmol. L-<NUM> (<NUM>) sodium acetate and <NUM>/ml mannitol. The formulation had a pH of <NUM>. The formulation was administered to dogs by subcutaneous injection at one of three concentrations: <NUM>/ml, <NUM>/ml, or <NUM>/ml (<NUM> male dogs per group). The plasma concentration of exendin (<NUM>-<NUM>) was monitored after administration over a time course of <NUM> to <NUM> hours (<FIG>).

As a control (not falling within the specified scope of the claims), exendin (<NUM>-<NUM>) acetate at a dose of <NUM> (equivalent to a <NUM> dose in humans) was reconstituted in <NUM>% normal saline having a pH of about <NUM> and administered subcutaneously to two dogs (<NUM> male and <NUM> female). <FIG> shows the resulting plasma concentration profile obtained by administering exendin (<NUM>-<NUM>) reconstituted in <NUM>% normal saline.

As can be seen by comparison of <FIG> and <FIG>, the buffered liquid formulations (comprising exendin (<NUM>-<NUM>) and <NUM>/ml mannitol in <NUM> mmol. L-<NUM> (<NUM>) sodium acetate and having a pH of <NUM>), at all concentrations tested, resulted in a higher plasma concentration of exendin (<NUM>-<NUM>) over the first <NUM> hours after administration as compared to the lyophilized exendin (<NUM>-<NUM>) reconstituted in normal saline.

Post-Bariatric Hypoglycemia (PBH) is a rare but serious complication of bariatric surgery manifested by frequent episodes of symptomatic postprandial hypoglycemia, for which there are no approved pharmacotherapies. A central role for exaggerated meal-induced secretion of the incretin hormone, glucagon-like peptide-<NUM> (GLP-<NUM>) with dysregulated insulin secretion has been established, making GLP-<NUM> receptor antagonism an attractive and targeted therapeutic approach. Studies evaluating the use of a single intravenous (IV) infusion or subcutaneous (SC) injection of the GLP-<NUM> receptor antagonist exendin (<NUM>-<NUM>) have demonstrated that a single dose of exendin (<NUM>-<NUM>) can prevent postprandial hypoglycemia, normalize beta cell function, and reduce neuroglycopenic symptoms in patients with PBH during oral glucose tolerance testing (OGTT).

This multiple-ascending dose (MAD) study evaluated the efficacy, tolerability, and pharmacokinetic profile of two formulations of exendin (<NUM>-<NUM>) subcutaneously administered over up to <NUM> days BID in participants with PBH. In Part A of this two-part study, <NUM> participants with PBH underwent a baseline OGTT followed by multiple ascending doses of up to <NUM> days of BID lyophilized exendin (<NUM>-<NUM>) reconstituted in <NUM>% normal saline ("Lyo" - not falling within the specified scope of the claims) with a repeat OGTT on the final day of dosing. In Part B of this study, <NUM> participants underwent <NUM> days of BID treatment with a buffered liquid formulation comprising <NUM> exendin (<NUM>-<NUM>) and <NUM>/ml mannitol in <NUM> mmol. L-<NUM> (<NUM>) sodium acetate at a pH of <NUM> ("Liq"). Repeat dosing of both formulations of SC exendin (<NUM>-<NUM>) were well tolerated, improved postprandial hyperinsulinemic hypoglycemia, and reduced associated symptoms in patients with PBH in a dose-dependent manner. The buffered liquid exendin (<NUM>-<NUM>) formulation improved postprandial metabolic and clinical parameters with comparable or greater efficiency than the lyophilized exendin (<NUM>-<NUM>) reconstituted in saline, and also appeared to confer greater exposure and duration of action. In conclusion, buffered liquid exendin (<NUM>-<NUM>) formulations represent a promising, convenient formulation for subcutaneous administration of exendin (<NUM>-<NUM>), and may provide an opportunity for lower and/or less frequent dosing.

PBH is a rare but serious complication of bariatric surgery manifested by frequent episodes of symptomatic postprandial hypoglycemia, for which there are no approved pharmacotherapies. A central role for exaggerated meal-induced secretion of the incretin hormone, glucagon-like peptide-<NUM> (GLP-<NUM>) with dysregulated insulin secretion has been established, making GLP-<NUM> receptor antagonism an attractive and targeted therapeutic approach. Studies evaluating IV infusion (<NPL>; <NPL>) or SC injection of the GLP-<NUM> receptor antagonist Ex-<NUM>-<NUM> (see, <CIT>) have demonstrated that a single dose of exendin (<NUM>-<NUM>) can prevent postprandial hypoglycemia, normalize beta cell function, and reduce neuroglycopenic symptoms in patients with PBH during OGTT. The current trial represents the first assessment in humans of subcutaneously administered exendin (<NUM>-<NUM>) formulated in a buffered liquid formulation. We present interim results (<NUM> of <NUM> participants) from this investigation aimed at evaluating the efficacy, tolerability, and pharmacokinetic profile of multiple ascending doses of two formulations of subcutaneously administered exendin (<NUM>-<NUM>) (lyophilized exendin (<NUM>-<NUM>) reconstituted in saline, or exendin (<NUM>-<NUM>) in a buffered liquid formulation) administered for up to <NUM> days BID in participants with PBH.

This Phase <NUM> MAD study was conducted in two parts, Parts A and B. In Part A, <NUM> participants underwent a baseline OGTT, followed by up to <NUM> days of BID doses of a reconstituted lyophilized formulation of exendin (<NUM>-<NUM>) ("Lyo") ranging from <NUM>-<NUM> with a repeat OGTT on the final day of dosing. In Part B, <NUM> participants underwent a baseline OGTT, followed by <NUM> BID of exendin (<NUM>-<NUM>) formulated in a liquid buffer comprising <NUM> mmol. L-<NUM> (<NUM>) sodium acetate and <NUM>/ml mannitol and having a pH of <NUM> ("Liq") with a repeat OGTT on Day <NUM> of treatment (See <FIG>). In both parts, metabolic, clinical, and pharmacokinetic responses were evaluated, and tolerability and safety were monitored. Determination of dose levels and frequency were based upon interim review of PK, PD, and safety data. Symptoms of hypoglycemia were assessed during each OGTT by use of the Edinburgh Hypoglycemia Symptom Scale (EHSS) (<NUM>,<NUM>). At a plasma glucose of ≤ <NUM>/dL the OGTT was stopped with investigator rescue by IV dextrose.

Eligible participants were men or women, ages <NUM> to <NUM> years, who had undergone Roux-en-Y gastric bypass (RYGB) surgery at least <NUM> months prior, with a documented history of Whipple's triad, with inappropriately elevated insulin concentrations (><NUM> pmol. L-<NUM> (> <NUM>µU/mL)) at the time of hypoglycemia (≤ <NUM>/dL) and a minimum of one symptomatic episode per month by patient report. Characteristics of the <NUM> study participants are provided in Table <NUM>, below.

Part A: Treatment with a reconstituted lyophilized formulation of exendin (<NUM>-<NUM>) reduced the presence and degree of hypoglycemia at all dose levels. Participants receiving doses of ≥ <NUM> did not require IV dextrose rescue. A dose-response relationship was observed for reconstituted lyophilized exendin (<NUM>-<NUM>) with incrementally increasing improvements in glucose nadir, insulin peak, and symptom score (<FIG> and Table <NUM> below). The top two dose cohorts, who on average received approximately <NUM> reconstituted lyophilized exendin (<NUM>-<NUM>) BID over <NUM> days, demonstrated a mean <NUM>% increase in glucose nadir, <NUM>% reduction in peak insulin concentrations, and <NUM>% reduction in overall hypoglycemia symptom score, with a <NUM>% reduction in neuroglycopenic symptoms (<FIG> and <FIG> and Table <NUM> below). All doses were well tolerated with only mild headache or nausea reported, and no drug related adverse events (DRAEs) observed.

On the basis of the interim efficacy, safety, and tolerability results, a fixed dose of <NUM> BID of exendin (<NUM>-<NUM>) buffered liquid formulation was selected for Part B.

Part B: Treatment with BID doses of <NUM> exendin (<NUM>-<NUM>) buffered liquid formulation raised the postprandial glucose nadir during OGTT on the third day of dosing in all participants evaluated, with none requiring IV dextrose rescue. On average, participants achieved a <NUM>% increase in glucose nadir, a <NUM>% reduction in peak insulin concentrations, and a <NUM>% reduction in overall hypoglycemia symptom score, and a <NUM>% reduction in neuroglycopenic symptoms (<FIG>, <FIG>, <FIG>). All doses were well tolerated with no DRAEs observed.

Part A: Increasing doses of reconstituted lyophilized exendin (<NUM>-<NUM>) resulted in incrementally increased exendin (<NUM>-<NUM>) exposure, as demonstrated by Cmax and <NUM>-hour AUC concentrations (<FIG> and Table <NUM>).

Part B: Equivalent doses administered on a mg/kg basis of exendin (<NUM>-<NUM>) buffered liquid formulation, vs reconstituted lyophilized exendin (<NUM>-<NUM>), yielded a higher Cmax, a higher <NUM>-hour AUC, and a later Tmax. The exendin (<NUM>-<NUM>) buffered liquid formulation resulted in higher trough plasma concentrations on the final day of dosing and demonstrated a more sustained absorption profile than comparable doses of reconstituted lyophilized exendin (<NUM>-<NUM>) (<FIG> and Table <NUM>).

In patients with refractory PBH repeat dosing of subcutaneously administered exendin (<NUM>-<NUM>) produced the following results during OGTT provocation: (<NUM>) Dose-dependent improvements in postprandial hyperinsulinemic hypoglycemia, and substantial reductions in the associated symptoms; (<NUM>) Prevention of neuroglycopenia with no need for rescue therapy at doses ≥ <NUM>; and (<NUM>) No drug related adverse events or tolerability concerns. Exendin (<NUM>-<NUM>) buffered liquid formulation, a ready-to-use formulation, provided at least comparable protection against symptomatic postprandial hyperinsulinemic hypoglycemia and may confer greater pharmacokinetic exposure with longer duration of action.

A Phase <NUM> trial was conducted investigating the safety, tolerability, pharmacokinetic and pharmacodynamic profile of single- and multiple-ascending doses of a subcutaneously administered buffered liquid formulation of exendin (<NUM>-<NUM>). For this study, the exendin (<NUM>-<NUM>) was formulated at a concentration of <NUM>/ml in a liquid buffer comprising <NUM> mmol. L-<NUM> (<NUM>) sodium acetate and <NUM>/ml mannitol and having a pH of <NUM>. In this single-center study in healthy volunteers, <NUM> subjects were subcutaneously administered either single ascending doses of exendin (<NUM>-<NUM>) ranging from <NUM> to <NUM> (<NUM> volunteers) or placebo (<NUM> volunteers) (Part A); and <NUM> subjects received <NUM> of <NUM> ascending doses (<NUM>, <NUM> or <NUM> of exendin (<NUM>-<NUM>) administered once daily for <NUM> consecutive days).

Within the single ascending dose group of Part A, <NUM> healthy subjects were enrolled into <NUM> successive cohorts of <NUM> subjects each as follows: <NUM> subjects received exendin (<NUM>-<NUM>) at doses of <NUM>, <NUM>, <NUM> or <NUM> and <NUM> subjects received placebo in each cohort. Within the multiple ascending doses group of Part B, <NUM> healthy subjects were enrolled in <NUM> successive cohorts of <NUM>, <NUM> and <NUM> subjects that received <NUM> of <NUM> dose levels of <NUM>, <NUM> or <NUM>, respectively, of exendin (<NUM>-<NUM>) administered once daily for <NUM> consecutive days.

As shown in Table <NUM> below and <FIG>, mean systemic exposure (Cmax, AUC<NUM>-tau and AUC<NUM>-inf) increased with dose in an approximately dose-proportional manner.

As shown in <FIG>, pre-dose trough plasma concentrations on Day <NUM> of <NUM> BID dosing approached plasma concentrations of exendin (<NUM>-<NUM>) that are expected to be therapeutic (><NUM> ng/ml), with relatively sustained plasma concentrations throughout the daytime hours (prior to next dosing time T=<NUM> hours). Within <NUM> minutes of a <NUM> AM dose administration, the target expected therapeutic concentrations (><NUM> ng/ml) were achieved, with higher peak plasma concentrations and sustained therapeutic concentrations observed throughout the daytime hours.

The dose levels and dosing interval of exendin (<NUM>-<NUM>) for a planned Phase <NUM> Study were selected based on results from this Phase <NUM> Study (e.g., as shown in Table <NUM> and <FIG>) as well as results from a completed MAD study in PBH patients conducted at Stanford University. In the Stanford MAD study, patients with refractory PBH experienced significant improvements in glucose nadir and neuroglycopenic symptoms during oral glucose tolerance testing after dosing with <NUM> BID of exendin (<NUM>-<NUM>), with improved postprandial metabolic and clinical parameters after the buffered liquid formulation as compared to the lyophilized exendin (<NUM>-<NUM>) reconstituted in saline. In the Stanford MAD study, optimal pharmacodynamic effects (postprandial glucose nadir > <NUM>/dl and decrease in peak insulin of at least <NUM>%) were achieved with peak plasma concentrations (Cmax) of at least <NUM> ng/ml. In contrast, in the investigation described herein (e.g., as shown in this example and in Example <NUM>), the buffered liquid formulation demonstrated greater pharmacokinetic and pharmacodynamic efficiency as compared to the reconstituted lyophilized exendin (<NUM>-<NUM>) formulated in normal saline (not falling within the specified scope of the claims).

Claim 1:
A liquid pharmaceutical formulation comprising exendin (<NUM>-<NUM>) or a pharmaceutically acceptable salt thereof and a tonicity modifier in a physiologically acceptable buffer having a pH in the range of <NUM> to <NUM>, wherein the exendin (<NUM>-<NUM>) or the pharmaceutically acceptable salt thereof does not exhibit visible aggregation in the formulation.