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Sunday, 29 May 2016

Difelikefalin

img
Difelikefalin, CR-845; MR-13A-9; MR-13A9
4-amino-1- (D-phenylalanyl-D-phenylalanyl-D-leucyl-D-lysyl) piperidine-4-carboxylic acid
Phase III
C36H53N7O6, 679.40573
OriginatorFerring Pharmaceuticals
DeveloperCara Therapeutics
ClassAnalgesic drugs (peptides)
Mechanism Of ActionOpioid kappa receptor agonists
Who Atc CodesD04A-X (Other antipruritics), N02A (Opioids)
Ephmra CodesD4A (Anti-Pruritics, Including Topical Antihistamines, Anaesthetics, etc), N2A (Narcotics)
IndicationPain, Osteoarthritis, Pruritus
A kappa opioid receptor agonist potentially for treatment of post-operative pain and uremic pruritus.
Difelikefalin, also known CR845, is a novel and potent kappa opioid receptor agonist. CR845 exhibit low P450 CYP inhibition and low penetration into the brain. CR845 may be useful in the prophylaxis and treatment of pain and inflammation associated with a variety of diseases and conditions .
No. CAS 1024828-77-0
2D chemical structure of 1024828-77-0
Difelikefalin ( INN ) (Developmental Code Names CR845 , FE-202845 ), Also Known As D -Phe- D -Phe- D -Leu- D -Lys- [Ganma- (4-N-Piperidinyl) Amino Carboxylic Acid] (As The Acetate Salt ), Is An Analgesic Opioid Peptide [2] Acting As A Peripherally-Specific , Highly Selective Agonist Of The kappa-Opioid Receptor (KOR). [1] [3] [4] [5] It Is Under Development By Cara Therapeutics As An Intravenous Agent For The Treatment Of Postoperative Pain . [1] [3] [5] An Oral Formulation Has Also Been Developed. [5] Due To Its Peripheral Selectivity, Difelikefalin Lacks The Central Side Effects Like Sedation , Dysphoria , And Hallucinations Of Previous KOR-Acting Analgesics Such As Pentazocine And Phenazocine . [1] [3] In Addition To Use As An Analgesic, Difelikefalin Is Also Being Investigated For The Treatment Of Pruritus (Itching). [1] [3] [4 ] Difelikefalin Has Completed Phase IIClinical Trials For Postoperative Pain And Has Demonstrated Significant And "Robust" Clinical Efficacy, Along With Being Safe And Well-Tolerated. [3] [5] It Is Also In Phase II Clinical Trials For Uremic Pruritus In Hemodialysis Patients. [4]
Difelikefalin Acts As An Analgesic By Activating KORs On Peripheral Nerve Terminals And KORs Expressed By Certain Immune System Cells . [1] Activation Of KORs On Peripheral Nerve Terminals Results In The Inhibition Of Ion Channels Responsible For Afferent Nerve Activity , Causing Reduced Transmission Of Pain Signals , While Activation Of KORs Expressed By Immune System Cells Results In Reduced Release Of Proinflammatory , Nerve-Sensitizing Mediators (Eg, Prostaglandins ). [1]

PATENT
κ opioid receptor agonists are known to be useful as therapeutic agents for various pain. Among, kappa opioid receptor agonist with high selectivity for peripheral kappa opioid receptors, are expected as a medicament which does not cause the central side effects. Such as peripherally selective κ opioid receptor agonist, a synthetic pentapeptide has been reported (Patent Documents 1 and 2).

 The following formula among the synthetic pentapeptide (A)

[Formula 1] Being Represented By Compounds Are Useful As Pain Therapeutics. The Preparation Of This Compound, Solid Phase Peptide Synthesis Methods In Patent Documents 1 And 2 Have Been Described.

 

Document 1 Patent: Kohyo 2010-510966 JP
Patent Document 2: Japanese Unexamined Patent Publication No. 2013-241447
 Compound (1) or a salt thereof and compound (A), for example as shown in the following reaction formula, 4-aminopiperidine-4-carboxylic acid, D- lysine (D-Lys), D- leucine (D-Leu) , it can be prepared by D- phenylalanine (D-Phe) and D- phenylalanine (D-Phe) sequentially solution phase peptide synthesis methods condensation.
[Of 4]
 
 
The present invention will next to examples will be described in further detail.
Example
1 (1) Synthesis of Cbz-D-Lys (Boc) -α-Boc-Pic-OMe (3)
to the four-necked flask of 2L, α-Boc-Pic- OMe · HCl [α-Boc-4 - aminopiperidine-4-carboxylic acid methyl hydrochloride] were charged (2) 43.7g (148mmol), was suspended in EtOAc 656mL (15v / w). To the suspension of 1-hydroxybenzotriazole (HOBt) 27.2g (178mmol), while cooling with Cbz-D-Lys (Boc) -OH 59.2g (156mmol) was added an ice-bath 1-ethyl -3 - (3-dimethylcarbamoyl amino propyl) was added to the carbodiimide · HCl (EDC · HCl) 34.1g (178mmol). After 20 minutes, stirring was heated 12 hours at room temperature. After completion of the reaction, it was added and the organic layer was 1 N HCl 218 mL of (5.0v / w). NaHCO to the resulting organic layer 3 Aq. 218ML (5.0V / W), Et 3 N 33.0 g of (326Mmol) was stirred for 30 minutes, and the mixture was separated. The organic layer HCl 218ML 1N (5.0V / W), NaHCO 3 Aq. 218mL (5.0v / w), NaClaq . Was washed successively with 218ML (5.0V / W), Na 2 SO 4 dried addition of 8.74g (0.2w / w). Subjected to vacuum filtration, was concentrated under reduced pressure resulting filtrate by an evaporator, and pump up in the vacuum pump, the Cbz-D-Lys (Boc) -α-Boc-Pic-OMe (3) 88.9g as a white solid obtained (96.5% yield, HPLC purity 96.5%).

[0033]
(2) D-Lys (Boc) Synthesis Of -Arufa-Boc-Pic-OMe (4)
In An Eggplant-Shaped Flask Of 2L, Cbz-D-Lys (Boc) -Arufa-Boc-Pic-OMe (3) 88.3g (142mmol) were charged, it was added and dissolved 441mL (5.0v / w) the EtOAc. The 5% Pd / C to the reaction solution 17.7g (0.2w / w) was added, After three nitrogen substitution reduced pressure Atmosphere, Was Performed Three Times A Hydrogen Substituent. The Reaction Solution Was 18 Hours With Vigorous Stirring At Room Temperature To Remove The Pd / C And After The Completion Of The Reaction Vacuum Filtration. NaHCO The Resulting Filtrate 3 Aq. 441ML And (5.0V / W) Were Added For Liquid Separation, And The Organic Layer Was Extracted By The Addition Of EtOAc 200ML (2.3V / W) In The Aqueous Layer. NaHCO The Combined Organic Layer 3 Aq. 441ML And (5.0V / W) Were Added for liquid separation, and the organic layer was extracted addition of EtOAc 200mL (2.3v / w) in the aqueous layer. NaClaq the combined organic layers. 441mL and (5.0v / w) is added to liquid separation, was extracted by the addition EtOAc 200ML Of (2.3V / W) In The Aqueous Layer. The Combined Organic Layer On The Na 2 SO 4 Dried Addition Of 17.7 g of (0.2W / W), Then The Filtrate Was Concentrated Under Reduced Pressure Obtained Subjected To Vacuum Filtration By an evaporator, and pump up in the vacuum pump, D-Lys (Boc) -α-Boc-Pic- OMe (4) to give 62.7g (90.5% yield, HPLC purity 93.6%).
(3) Cbz-D-Leu -D-Lys (Boc) -α-Boc-Pic-OMe synthesis of (5)
in the four-necked flask of 2L, D-Lys (Boc) -α-Boc-Pic-OMe (4) was charged 57.7 g (120 mmol), was suspended in EtOAc 576mL (10v / w). HOBt 19.3g (126mmol) to this suspension, was added EDC · HCl 24.2g (126mmol) while cooling in an ice bath added Cbz-D-Leu-OH 33.4g (126mmol). After 20 minutes, after stirring the temperature was raised 5 hours at room temperature, further the EDC · HCl and stirred 1.15 g (6.00 mmol) was added 16 h. After completion of the reaction, it was added liquid separation 1N HCl 576mL (10v / w) . NaHCO to the resulting organic layer 3 Aq. 576ML (10V / W), Et 3 N 24.3 g of (240Mmol) was stirred for 30 minutes, and the mixture was separated. The organic layer HCl 576ML 1N (10V / W), NaHCO 3 Aq. 576mL (10v / w), NaClaq . Was washed successively with 576ML (10V / W), Na 2 SO 4 dried addition of 11.5g (0.2w / w). After the filtrate was concentrated under reduced pressure obtained subjected to vacuum filtration by an evaporator, and pump up in the vacuum pump, the Cbz-D-Leu-D- Lys (Boc) -α-Boc-Pic-OMe (5) 85.8g It was obtained as a white solid (98.7% yield, HPLC purity 96.9%).
(4) D-Leu-D -Lys (Boc) -α-Boc-Pic-OMe synthesis of (6)
in an eggplant-shaped flask of 1L, Cbz-D-Leu- D-Lys (Boc) -α-Boc-Pic -OMe the (5) 91.9g (125mmol) were charged, was added and dissolved 459mL (5.0v / w) the EtOAc. The 5% Pd / C to the reaction solution 18.4g (0.2w / w) was added, After three nitrogen substitution reduced pressure atmosphere, was performed three times a hydrogen substituent. The reaction solution was subjected to 8 hours with vigorous stirring at room temperature to remove the Pd / C and after the completion of the reaction vacuum filtration. NaHCO the resulting filtrate 3 Aq. 200mL (2.2v / w) were added to separate liquid, NaHCO to the organic layer 3 Aq. 200mL (2.2v / w), NaClaq . It was sequentially added washed 200mL (2.2v / w). To the resulting organic layer Na 2 SO 4 dried added 18.4g (0.2w / w), to the filtrate concentrated under reduced pressure obtained subjected to vacuum filtration by an evaporator, and a pump-up with a vacuum pump. The resulting amorphous solid was dissolved adding EtOAc 200mL (2.2v / w), was crystallized by the addition of heptane 50mL (1.8v / w). Was filtered off precipitated crystals by vacuum filtration, the crystals were washed with a mixed solvent of EtOAc 120mL (1.3v / w), heptane 50mL (0.3v / w). The resulting crystal 46.1g to added to and dissolved EtOAc 480mL (5.2v / w), was crystallized added to the cyclohexane 660mL (7.2v / w). Was filtered off under reduced pressure filtered to precipitate crystals, cyclohexane 120mL (1.3v / w), and washed with a mixed solvent of EtOAc 20mL (0.2v / w), and 30 ° C. vacuum dried, D-Leu- as a white solid D-Lys (Boc) -α- Boc-Pic-OMe (6) to give 36.6 g (48.7% yield, HPLC purity 99.9%).
(5) Synthesis of Cbz-D-Phe-D- Leu-D-Lys (Boc) -α-Boc-Pic-OMe (7)
to the four-necked flask of 1L, D-Leu-D- Lys (Boc) -α-Boc-Pic-OMe with (6) 35.8g (59.6mmol) was charged, it was suspended in EtOAc 358mL (10v / w). To this suspension HOBt 9.59g (62.6mmol), Cbz- D-Phe-OH 18.7g was cooled in an ice bath is added (62.6mmol) while EDC · HCl 12.0g (62.6mmol) It was added. After 20 minutes, a further EDC · HCl After stirring the temperature was raised 16 hours was added 3.09 g (16.1 mmol) to room temperature. After completion of the reaction, it was added and the organic layer was 1N HCl 358mL of (10v / w). NaHCO to the resulting organic layer 3 Aq. 358ML (10V / W), Et 3 N 12.1 g of (119Mmol) was stirred for 30 minutes, and the mixture was separated. The organic layer HCl 358ML 1N (10V / W), NaHCO 3 Aq. 358mL (10v / w), NaClaq . Was washed successively with 358ML (10V / W), Na 2 SO 4 dried addition of 7.16g (0.2w / w). After the filtrate was concentrated under reduced pressure obtained subjected to vacuum filtration by an evaporator, and pump up in the vacuum pump, Cbz-D-Phe-D -Leu-D-Lys (Boc) -α-Boc-Pic-OMe (7) was obtained 52.5g as a white solid (yield quant, HPLC purity 97.6%).
(6) D-Phe-D -Leu-D-Lys (Boc) synthesis of -α-Boc-Pic-OMe ( 8)
in an eggplant-shaped flask of 2L, Cbz-D-Phe- D-Leu-D-Lys ( Boc) -α-Boc-Pic- OMe (7) the 46.9g (53.3mmol) were charged, the 840ML EtOAc (18V / W), H 2 added to and dissolved O 93.8mL (2.0v / w) It was. The 5% Pd / C to the reaction mixture 9.38g (0.2w / w) was added, After three nitrogen substitution reduced pressure atmosphere, was performed three times a hydrogen substituent. The reaction solution was subjected to 10 hours with vigorous stirring at room temperature to remove the Pd / C and after the completion of the reaction vacuum filtration. NaHCO the resulting filtrate 3 Aq. 235mL (5.0v / w) were added to separate liquid, NaHCO to the organic layer 3 Aq. 235mL (5.0v / w), NaClaq . It was added sequentially cleaning 235mL (5.0v / w). To the resulting organic layer Na 2 SO 4 dried addition of 9.38g (0.2w / w), then the filtrate was concentrated under reduced pressure obtained subjected to vacuum filtration by an evaporator, pump up with a vacuum pump to D-Phe -D-Leu-D-Lys ( Boc) -α-Boc-Pic-OMe (7) was obtained 39.7g (yield quant, HPLC purity 97.3%).
351mL was suspended in (10v / w). To this suspension HOBt 7.92g (51.7mmol), Boc-D-Phe-OH HCl HCl
(8) D-Phe-D -Phe-D-Leu-D-Lys-Pic-OMe Synthesis Of Hydrochloric Acid Salt (1)
In An Eggplant-Shaped Flask Of 20ML Boc-D-Phe-D -Phe-D- Leu-D- lys (Boc) -α -Boc- Pic-OMe (9) and 2.00gg, IPA 3.3mL (1.65v / w), was suspended by addition of PhMe 10mL (5v / w). It was stirred at room temperature for 19 hours by addition of 6N HCl / IPA 6.7mL (3.35v / w). The precipitated solid was filtered off by vacuum filtration and dried under reduced pressure to a white solid of D-Phe-D-Phe- D- Leu-D-Lys-Pic- OMe 1.59ghydrochloride (1) (yield: 99 .0%, HPLC purity 98.2%) was obtained.
(9) D-Phe-D -Phe-D-Leu-D-Lys-Pic-OMe Purification Of The Hydrochloric Acid Salt (1)
In An Eggplant-Shaped Flask Of 20ML-D-Phe-D- Phe D-Leu -D-Lys- pic-OMe hydrochloride crude crystals (1) were charged 200mg, EtOH: MeCN = 1: after stirring for 1 hour then heated in a mixed solvent 4.0 mL (20v / w) was added 40 ° C. of 5 , further at room temperature for 2 was time stirring slurry. Was filtered off by vacuum filtration, the resulting solid was dried under reduced pressure a white solid ((1) Purification crystals) was obtained 161 mg (80% yield, HPLC purity 99.2% ).
(10) D-Phe-D -Phe-D-Leu-D-Lys-Pic Synthesis (Using Purified
(1)) Of (A) To A Round-Bottomed Flask Of 10ML D-Phe-D-Phe-D- -D-Lys Leu-Pic-OMe Hydrochloride Salt (1) Was Charged With Purified Crystal 38.5Mg (0.0488Mmol), H 2 Was Added And Dissolved O 0.2ML (5.2V / W). 1.5H Was Stirred Dropwise 1N NaOH 197MyuL (0.197mmol) at room temperature. After completion of the reaction, concentrated under reduced pressure by an evaporator added 1N HCl 48.8μL (0.0488mmol), to obtain a D-Phe-D-Phe- D-Leu-D-Lys- Pic (A) (yield: quant , HPLC purity 99.7%).
D-Phe-D-Phe- D-Leu-D-Lys-Pic-OMe (1) physical properties 1 H NMR (400 MHz, 1M DCl) [delta] ppm by: 0.85-1.02 (yd,. 6 H), 1.34-1.63 ( m, 5 H), 1.65-2.12 ( m, 5 H), 2.23-2.45 (m, 2 H), 2.96-3.12 (m, 4 H), 3.19 (ddt, J = 5.0 & 5.0 & 10.0 Hz), 3.33-3.62 (m, 1 H), 3.68-3.82 (m, 1 H), 3.82-3.95 (m, 4 H), 3.95-4.18 (m, 1 H), 4.25-4.37 (m, 2 H), 4.61-4.77 (M, 2 H), 7.21-7.44 (M, 10 H) 13 C NMR (400MHz, 1M DCl) Deruta Ppm: 21.8, 22.5, 24.8, 27.0, 30.5, 30.8, 31.0, 31.2, 31.7, 37.2 , 37.8, 38.4, 39.0, 39.8, 40.4, 40.6, 41.8, 42.3, 49.8, 50.2, 52.2, 52.6, 54.6, 55.2, 57.7, 57.9, 127.6, 128.4, 129.2, 129.6, 129.7, 129.8 dp 209.5 ℃
Example 2
(Trifluoroacetic Acid (TFA)
Use) (1) D-Phe-D-Phe-D-Leu-D-Lys-Pic-OMe TFA Synthesis Of Salt (1)
TFA 18ML Eggplant Flask Of 50ML (18V / W) , 1- Dodecanethiol 1.6ML (1.6V / W), Triisopropylsilane 0.2ML (0.2V / W), H 2 Sequentially Added Stirring The O 0.2ML (0.2V / W) Did. The Solution To The Boc-D-Phe- D- Phe-D-Leu-D -Lys (Boc) -α-Boc-Pic-OMe the (9) 1.00g (1.01mmol) was added in small portions with a spatula. After completion of the reaction, concentrated under reduced pressure by an evaporator, it was added dropwise the resulting residue in IPE 20mL (20v / w). The precipitated solid was filtered off, the resulting solid was obtained and dried under reduced pressure to D-Phe-D-Phe- D-Leu -D-Lys-Pic-OMe · TFA salt as a white solid (1) (Osamu rate 93.0%, HPLC purity 95.2%).
(2) D-Phe-D -Phe-D-Leu-D-Lys-Pic synthesis of (A)
to a round-bottomed flask of 10mL D-Phe-D-Phe -D-Leu-D-Lys-Pic-OMe TFA were charged salt (1) 83mg (0.0843mmol), was added and dissolved H2O 431μL (5.2v / w). Was 12h stirring dropwise 1N NaOH 345μL (0.345mmol) at room temperature. After completion of the reaction, concentrated under reduced pressure by an evaporator added 1N HCl 84.3μL (0.0843mmol), to obtain a D-Phe-D-Phe- D-Leu-D-Lys-Pic (A) ( yield: quant, HPLC purity 95.4%).
Example
3 (HCl / EtOAc
Use) (1) In An Eggplant-Shaped Flask Of 30ML Boc-D-Phe-D -Phe-D-Leu-D-Lys (Boc) -Arufa-Boc-Pic-OMe (9) 1. It was charged with 00g (1.01mmol ), was added and dissolved EtOAc7.0mL (7.0v / w). 4N HCl / EtOAc 5.0mL (5.0v / w) was added after 24h stirring at room temperature, the precipitated solid was filtered off by vacuum filtration, washed with EtOAc 2mL (2.0v / w). The resulting solid D-Phe-D-Phe- D-Leu-D-Lys-Pic-OMe hydrochloride (1) was obtained 781mg of a white solid was dried under reduced pressure (the 96.7% yield, HPLC purity 95.4%).
(2) D-Phe-D -Phe-D-Leu-D-Lys-Pic (A) Synthesis of
eggplant flask of 10mL D-Phe-D-Phe -D-Leu-D-Lys-Pic-OMe hydrochloride were charged salt (1) 90 mg (0.112 mmol), H 2 was added and dissolved O 0.47mL (5.2v / w). Was 12h stirring dropwise 1N NaOH 459μL (0.459mmol) at room temperature. After completion of the reaction, concentrated under reduced pressure by an evaporator added 1N HCl 0.112μL (0.112mmol), was obtained D-Phe-D-Phe- D-Leu-D-Lys-Pic (A) ( yield: quant, HPLC purity 93.1%).
4 Example
Compound (1) Of The Compound By Hydrolysis Synthesis Of (The A) (Compound (1) Without
Purification) Eggplant Flask 10ML D-Phe-D-Phe -D-Leu-D-Lys-Pic-OMe (1) Charged Hydrochloride Were (Without Pre-Step Purification) 114.5Mg (0.142Mmol), H 2 Was Added And Dissolved O 595MyuL (5.2V / W). Was 14H Stirring Dropwise 1N NaOH 586MyuL (0.586Mmol) At Room Temperature. After Completion Of the reaction, concentrated under reduced pressure by an evaporator added 1N HCl 0.15μL (0.150mmol), was obtained D-Phe-D-Phe- D-Leu-D-Lys-Pic (A) (yield: quant, HPLC purity 95.2 %).
Example 1 Comparative
Path Not Via The Compound (1) (Using Whole Guard Boc-D-Phe-D-Phe-D-Leu-D-Lys (Boc) -Alpha-Boc-Pic-OMe
(A)) (1) D--Boc Phe- D-Phe-D-Leu-D-Lys (Boc) -Arufa-Boc-Pic-OH Synthesis Of
Eggplant Flask Of 30ML Boc-D-Phe-D -Phe-D-Leu-D- Lys (Boc) -α- Boc-Pic -OMe (9) were charged 1.00g (1.00mmol), was added and dissolved MeOH 5.0mL (5.0v / w). After stirring for four days by the addition of 1N NaOH 1.1 mL (1.10mmol) at room temperature, further MeOH 5.0mL (5.0v / w), 1N NaOH 2.0mL the (2.0mmol) at 35 ℃ in addition 3h and the mixture was stirred. After completion of the reaction, 1 N HCl 6.1 mL was added, After distilling off the solvent was concentrated under reduced pressure was separated and the organic layer was added EtOAc 5.0mL (5.0mL) .NaClaq. 5.0mL (5.0v / w) Wash the organic layer was added, the organic layer as a white solid was concentrated under reduced pressure to Boc-D-Phe-D- Phe-D-Leu-D-Lys (Boc) - α-Boc-Pic-OH 975.1mg (99.3% yield, HPLC purity 80.8% )
(2) D-Phe-D -Phe-D-Leu-D-Lys-Pic synthesis of (A)
to a round-bottomed flask of 20mL Boc-D-Phe-D -Phe-D-Leu-D-Lys (Boc) It was charged -α-Boc-Pic-OH ( 10) 959mg (0.978mmol), was added and dissolved EtOAc 4.9mL (5.0v / w). And 4h stirring at room temperature was added dropwise 4N HCl / EtOAc 4.9mL (5.0mL) at room temperature. After completion of the reaction, it was filtered under reduced pressure, a white solid as to give D-Phe-D-Phe- D-Leu-D-Lys-Pic the (A) (96.4% yield, HPLC purity 79.2%) .
 If not via the compound of the present invention (1), the purity of the compound obtained (A) was less than 80%.
 
 
PATENT

References

  1.  S. Sinatra Raymond; Jonathan S. Jahr;. J. Michael Watkins-Pitchford (14 October 2010) The Essence Of Analgesia And Analgesics .... Cambridge University Press Pp 490-491 ISBN  978-1-139-49198-3 .
  2.  A Janecka, Perlikowska R, Gach K, Wyrebska A, Fichna J (2010) "Development Of Opioid Peptide Analogs For Pain Relief".. Curr Pharm Des... 16 (9):. 1126-35 Doi : 10.2174 / 138161210790963869 . PMID  20030621 .
  3. Apfelbaum Jeffrey (8 September 2014). Ambulatory Anesthesia, An Issue Of Anesthesiology Clinics, . Elsevier Health Sciences. Pp. 190-. ISBN  978-0-323-29934-3 .
  4.  Cowan Alan;. Gil Yosipovitch (10 April 2015) Pharmacology Of Itch .... Springer Pp 307- ISBN  978-3-662-44605-8 .
  5.  Allerton Charlotte (2013). Pain Therapeutics: Current And Future Treatment Paradigms .... Royal Society Of Chemistry Pp 56- ISBN  978-1-84973-645-9 .

REFERENCES

1: Cowan A, Kehner GB, Inan S. Targeting Itch With Ligands Selective For kappa Opioid
. Receptors Handb Exp Pharmacol 2015; 226:.. 291-314 Doi:
.. 10.1007 / 978-3-662-44605-8_16 Review PubMed PMID: 25861786.

Difelikefalin
Difelikefalin.svg
Systematic (IUPAC) Name
Amino--4 1- ( D -Phenylalanyl- D -Phenylalanyl- D -Leucyl- D -Lysyl) Piperidine-4-Carboxylic Acid
Clinical data
Of Routes
Administration
Intravenous
Pharmacokinetic Data
BioavailabilityPasento 100 ( IV ) [1]
MetabolismMetabolized Not [1]
Biological half-lifeHours 2 [1]
ExcretionAs Unchanged Excreted
Drug Via Bile And Urine [1]
Identifiers
CAS Number1024828-77-0
ATC codeNone
ChemSpider44208824
Chemical data
Formula36 53 6
Molar mass679.85 g / mol
///// Difelikefalin,  CR845 , FE-202845,  Phase III, PEPTIDES
CC (C) C [C @ H] (C (= O) N [C @ H] (CCCCN) C (= O) N1CCC (CC1) (C (= O) O) N) NC (= O) [ C @@ H] (Cc2ccccc2) NC (= O) [C @@ H] (Cc3ccccc3) N

[F-18](2S,4S)-4-(3-Fluoropropyl)glutamine

STR1

[F-18](2S,4S)-4-(3-Fluoropropyl)glutamine

CAS 1196963-79-7
MF C8 H15 F N2 O3
Heptanoic acid, 2-​amino-​4-​(aminocarbonyl)​-​7-​(fluoro-​18F)​-​, (2S,​4S)​-
[18F](2S,4S)-4-FPGln
[18F](2S,4S)-4-(3-fluoropropyl)glutamine, 4

The early diagnosis of malignant tumors plays a very important role in the survival prognosis of cancer patients. In this non-invasive diagnosis, diagnostic imaging procedures are an important tool. In the last few years has mainly PET technology (P ositronen- E mission-Tomographie) proved to be particularly useful. The sensitivity and specificity of PET technology depends significantly on the used signal-emitting substance (tracer) and their distribution in the body from. In the search for suitable tracers one tries to take advantage of certain properties of tumors differ, the tumor tissue from healthy, surrounding tissue. The preferred commercially used isotope which finds application for PET, 18 F 18 F represents by its short half-life of less than 2 hours special requirements for the preparation of suitable tracer.Complex, long synthetic routes and purifications are with this isotope is not possible, because otherwise a significant portion of the radioactivity of the isotope has already decayed before the tracer can be used for diagnosis. It is therefore often not possible to established synthetic routes for non-radioactive fluorination to be applied to the synthesis of18 F-tracer. Furthermore, the high specific activity of 18 F (80 GBq / nmol) at very low substance amounts of [18 F] fluoride for the tracer synthesis, which in turn an extreme excess of precursor-related and the success of a non-radioactive fluorination based Radio synthetic strategy designed unpredictable
FDG ([18 F] F 2 luoro d esoxy lukose g) -PET is a widely accepted and popular tool in the diagnosis and other clinical tracking of tumor diseases. Malignant tumors compete with the host organism to glucose supply to the nutrient supply (Warburg O. About the metabolism of carcinoma cell Biochem;.. Kellof G. Progress and Promise of FDG PET Imaging for Cancer Patient Management and Oncologic Drug Development Clin Cancer Res 2005;.. 11 (8): 2785-2807) where tumor cells compared to surrounding cells of normal tissue usually an increased glucose metabolism. This is used when using fluorodeoxyglucose (FDG), a glucose derivative, which is amplified transported into the cells, but there included metabolically after phosphorylation as FDG-6-phosphate (“Warburg effect”). 18 F-labeled FDG is Therefore, an effective tracer for the detection of tumors in patients using PET technology. Imaging were looking for new PET tracers in recent years increasingly amino acids for 18 F PET used (eg (review): Eur J Nucl Med Mol Imaging 2002 May; 29 (5):.. 681-90). In this case, some of the 18F-labeled amino acids for the measurement of the speed rate of protein synthesis, the most useful derivatives but for the direct measurement of the cellular uptake in the tumor. Known 18 F-labeled amino acids are, for example, from tyrosine, phenylalanine, proline, aspartic and unnatural amino acids derived (eg J. Nucl Med 1991; 32:.. 1338-1346, J Nucl Med 1996; 37: 320-325, J Nucl Med 2001; 42: 752-754 J Nucl Med and 1999, 40: 331-338).. Glutamic acid and glutamine than 18 F-labeled derivatives not known, whereas non-radioactive fluorinated glutamine and glutamic acid derivatives are well known; Thus, for Example those which at γ-position (for Ex (review):Amino Acids (2003) April; 24 (3):… 245-61).. or at β-position (e.g. ExTetrahedron. Lett. .; 30; 14; 1989, 1799-1802, J. Org Chem .; 54; 2; 1989, 498-500,Tetrahedron: Asymmetry, 12, 9; 2001; 1303-1312) havefluorine..
Of glutamic acid having the chemical functionalities protecting groups in β and γ position or a leaving group, has already been reported in the past. So was informed of glutamate as mesylate or bromide in γ-position whose acid and amine functions were provided with ester or Z-protecting groups (J. Chem Soc Perkin Trans. 1;.. 1986, 1323-1328) or, for example, of γ-chloro-glutamic acid without protecting groups(Synthesis, (1973); 44-46). About similar derivatives, but where the leaving group is positioned in β-position has also been reported on several occasions. Z Ex. Chem. Pharm. Bull .; 17; 5; (1969); 879-885,J.Gen.Chem.USSR (Engl.Transl.); 38; (1968); 1645-1648, Tetrahedron Lett .; 27; 19; (1986); 2143-2144, Chem. Pharm. Bull .; EN; 17; 5; 1969;873-878, patent FR 1461184 , Patent JP 13142 .)
The current PET tracers, which are used for tumor diagnosis have some undisputed disadvantages: in FDG accumulates preferably in those cells with increased glucose metabolism on, but there are also other pathological and physiological conditions of increased glucose metabolism in the cells involved and tissues, eg, Ex. of infection or wound healing (summarized in J. Nucl. Med. Technol. (2005), 33, 145-155). It is still often difficult to decide whether a detected by FDG-PET lesion actually neoplastic origin or due to other physiological or pathological state of the tissue. Overall, the diagnostic activity by FDG-PET in oncology has a sensitivity of 84% and a specificity of 88% to(Gambhir et al., ” A tabulated summary of the FDG PET literature “J. Nucl. Med. 2001, 42, 1- 93S). Tumors in the brain can be represented very difficult in healthy brain tissue, for example, by the high accumulation of FDG.
The previously known 18 F-labeled amino acid derivatives are in some cases well suited to detect tumors in the brain ((review): Eur J Nucl Med Mol Imaging 2002 May; 29 (5):. 681-90), but they can in other tumors do not compete with the imaging properties of the “gold standard”[18 F] 2-FDG. The metabolic accumulation and retention of previously F-18 labeled amino acids in tumorous tissue is usually lower than for FDG. Moreover, the accessibility of isomerically pure F-18-labeled non-aromatic amino acids is chemically very demanding.
Similar to glucose increased metabolism in proliferating tumor cells has been described (Medina, J Nutr 1131: 2539S-2542S, 2001; Souba, Ann Surg 218:. 715-728, 1993) for glutamic acid and glutamine. The increased rate of protein and nucleic acid synthesis and energy production per se be accepted as reasons for increased Glutaminkonsum of tumor cells. The synthesis of the corresponding C-11 and C-14 labeled with the natural substrate thus identical compounds, has already been described in the literature (eg. Ex.Antoni, enzymes Catalyzed Synthesis of L- [4-C-11] Aspartate and L – [5-C-11] Glutamate J. Labelled Compd Radiopharm 44; (4) 2001: 287-294) and Buchanan, The biosynthesis of showdomycin: studies with stable isotopes and the determination of principal precursor J….. Chem. Soc. Chem. Commun .;EN; 22; 1984, 1515-1517). First indications with the C-11 labeled compound indicate no significant tumor accumulation.
Although the growth and proliferation of most tumors is fueled by glucose, some tumors are more likely to metabolize glutamine. In particular, tumor cells with the upregulated c-Myc gene are generally reprogrammed to utilize glutamine. We have developed new 3-fluoropropyl analogs of glutamine, namely [(18)F](2S,4R)- and [(18)F](2S,4S)-4-(3-fluoropropyl)glutamine, 3 and 4, to be used as probes for studying glutamine metabolism in these tumor cells. Optically pure isomers labeled with (18)F and (19)F (2S,4S) and (2S,4R)-4-(3-fluoropropyl)glutamine were synthesized via different routes and isolated in high radiochemical purity (≥95%). Cell uptake studies of both isomers showed that they were taken up efficiently by 9L tumor cells with a steady increase over a time frame of 120 min. At 120 min, their uptake was approximately two times higher than that of l-[(3)H]glutamine ([(3)H]Gln). These in vitro cell uptake studies suggested that the new probes are potential tumor imaging agents. Yet, the lower chemical yield of the precursor for 3, as well as the low radiochemical yield for 3, limits the availability of [(18)F](2S,4R)-4-(3-fluoropropyl)glutamine, 3. We, therefore, focused on [(18)F](2S,4S)-4-(3-fluoropropyl)glutamine, 4. The in vitro cell uptake studies suggested that the new probe, [(18)F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, is most sensitive to the LAT transport system, followed by System N and ASC transporters. A dual-isotope experiment using l-[(3)H]glutamine and the new probe showed that the uptake of [(3)H]Gln into 9L cells was highly associated with macromolecules (>90%), whereas the [(18)F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, was not (<10%). This suggests a different mechanism of retention. In vivo PET imaging studies demonstrated tumor-specific uptake in rats bearing 9L xenographs with an excellent tumor to muscle ratio (maximum of ∼8 at 40 min). [(18)F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, may be useful for testing tumors that may metabolize glutamine related amino acids.


STR1

[18F](2S,4S)-4-(3-Fluoropropyl)glutamine as a Tumor Imaging Agent

Departments of Radiology and Pharmacology, University of Pennsylvania, 3700 Market Street, Philadelphia, Pennsylvania 19104, United States
Mol. Pharmaceutics201411 (11), pp 3852–3866
DOI: 10.1021/mp500236y
Publication Date (Web): August 05, 2014
Copyright © 2014 American Chemical Society
*Email: kunghf@sunmac.spect.upenn.edu. Phone: 215-662-3096. Fax: 215-349-5035.
ACS AuthorChoice – This is an open access article published under an ACS AuthorChoice License, which permits copying and redistribution of the article or any adaptations for non-commercial purposes.
This article is part of the Positron Emission Tomography: State of the Art special issue.

Abstract

Abstract Image
Although the growth and proliferation of most tumors is fueled by glucose, some tumors are more likely to metabolize glutamine. In particular, tumor cells with the upregulated c-Myc gene are generally reprogrammed to utilize glutamine. We have developed new 3-fluoropropyl analogs of glutamine, namely [18F](2S,4R)- and [18F](2S,4S)-4-(3-fluoropropyl)glutamine, 3 and 4, to be used as probes for studying glutamine metabolism in these tumor cells. Optically pure isomers labeled with 18F and 19F (2S,4S) and (2S,4R)-4-(3-fluoropropyl)glutamine were synthesized via different routes and isolated in high radiochemical purity (≥95%). Cell uptake studies of both isomers showed that they were taken up efficiently by 9L tumor cells with a steady increase over a time frame of 120 min. At 120 min, their uptake was approximately two times higher than that of l-[3H]glutamine ([3H]Gln). These in vitro cell uptake studies suggested that the new probes are potential tumor imaging agents. Yet, the lower chemical yield of the precursor for 3, as well as the low radiochemical yield for 3, limits the availability of [18F](2S,4R)-4-(3-fluoropropyl)glutamine, 3. We, therefore, focused on [18F](2S,4S)-4-(3-fluoropropyl)glutamine, 4. The in vitro cell uptake studies suggested that the new probe, [18F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, is most sensitive to the LAT transport system, followed by System N and ASC transporters. A dual-isotope experiment using l-[3H]glutamine and the new probe showed that the uptake of [3H]Gln into 9L cells was highly associated with macromolecules (>90%), whereas the [18F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, was not (<10%). This suggests a different mechanism of retention. In vivo PET imaging studies demonstrated tumor-specific uptake in rats bearing 9L xenographs with an excellent tumor to muscle ratio (maximum of ∼8 at 40 min). [18F](2S,4S)-4-(3-fluoropropyl)glutamine, 4, may be useful for testing tumors that may metabolize glutamine related amino acids.
PATENT
US 20100290991
Figure US20100290991A1-20101118-C00029
PATENT
WO 2009141091
PATENT


REFERENCES
Molecular Pharmaceutics (2014), 11(11), 3852-3866
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FR1461184ATitle not available
JPS58113142ATitle not available
WO2008052788A1*30 Oct 20078 May 2008Bayer Schering Pharma Aktiengesellschaft[f-18]-labeled l-glutamic acid, [f-18]-labeled l-glutamine, derivatives thereof and use thereof and processes for their preparation
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