Actualizing Hybrid Pressure and Silicone Therapies with 3D Printing and Scanning
               A Randomized  Controlled  Trial.  J Med  Assoc Thailand,   Population for COVID-19: A Prospective Real-World Study.
               103(5):39–43.                                       Iran J Public Health, 49(supple 1):3670.
           36.  Uslu  A, Sürücü  A, Korkmaz MA, et al.,  2019, Acquired      https://doi.org/10.18502/ijph.v49is1.3670
               Localized  Hypertrichosis Following Pressure Garment   47.  Chow L,  Yick  KL, Kwan MY, et  al., 2020, Customized
               and/or  Silicone Therapy  in  Burn Patients.  Ann  Plast  Surg,   Fabrication Approach for Hypertrophic Scar Treatment: 3D
               82(2):158–61.                                       Printed Fabric Silicone Composite. Int J Bioprint, 6(2):262.
               https://doi.org/10.1097/sap.0000000000001686        https://doi.org/10.18063/ijb.v6i2.262
           37.  Ng WL, Chan A, Ong YS, et al., 2020, Deep Learning for   48.  Boone LA, 1995, Development of a Customized  Pattern
               Fabrication  and Maturation  of 3D Bioprinted  Tissues and   Drafting System for Interim Burnscar Pressure Garments
               Organs. Virtual Phys Prototyp, 15(3):340–58.        Utilizing Fabric Properties and Circumference Measurements.
           38.  Sun  W, Starly B, Daly AC, et al., 2020,  The Bioprinting   University of Alberta, Edmonton, Alta.
               Roadmap. Biofabrication, 12(2):5158.            49.  Yu A, 2015, Development of Pressure Therapy Gloves for
           39.  Ng WL, Chua CK, Shen YF, 2019, Print Me An Organ! Why   Hypertrophic Scar Treatment. The Hong Kong Polytechnic
               We Are Not There Yet. Prog Polym Sci, 97:101145.    University, Hong Kong.
               https://doi.org/10.1016/j.progpolymsci.2019.101145  50.  Yu A, Yick KL, Ng SP, et al., 2016, Numerical Simulation
           40.  Kang HW, Lee  SJ, Ko IK, et  al., 2016, A 3D Bioprinting   of Pressure Therapy Glove by Using Finite Element Method.
               System  to  Produce  Human-scale  Tissue  Constructs  with   Burns, 42(1):141–51.
               Structural Integrity. Nat Biotechnol, 34(3):312–9.     https://doi.org/10.1016/j.burns.2015.09.013
               https://doi.org/10.1038/nbt.3413                51.  Wu JZ, Dong RG, Rakheja  S, et al., 2002, Simulation  of
           41.  Oladapo BI, Ismail SO, Afolalu TD, et al., 2021, Review on   Mechanical  Responses of Fingertip to Dynamic Loading.
               3D Printing:  Fight  against  COVID-19.  Mater  Chem  Phys,   Med Eng Phys, 24(4):253–64.
               258:123943.                                     52.  Lai  CH, Li-Tsang CW, 2009,  Validation  of the  Pliance  X
               https://doi.org/10.1016/j.matchemphys.2020.123943   System in measuring interface pressure generated by pressure
           42.  Rendeki  S, Nagy B, Bene  M, et  al., 2020,  An Overview   garment. Burns, 35(6):845–51.
               on Personal Protective  Equipment  (PPE) Fabricated      https://doi.org/10.1016/j.burns.2008.09.013
               with  Additive  Manufacturing  Technologies  in the Era of   53.  Wiseman J, Simons M, Kimble R, et al., 2018, Reliability and
               COVID-19 Pandemic. Polymers, 12(11):1–18.           Clinical Utility of the Pliance X for Measuring Pressure at the
               https://doi.org/10.3390/polym12112703               Interface of Pressure Garments and Burn Scars in Children.
           43.  Hale L, Linley E, Kalaskar DM, 2020, A Digital Workflow   Burns, 44(7):1820–8.
               for Design and Fabrication of Bespoke Orthoses Using 3D      https://doi.org/10.1016/j.burns.2018.05.002
               Scanning and 3D Printing, a Patient-based Case Study. Sci   54.  Reid  W,  Evans  J, Naismith  R,  et  al.,  1987, Hypertrophic
               Rep, 10(1):7028–7.                                  Scarring and Pressure Therapy. Burns, 13:S29–32.
               https://doi.org/10.1038/s41598-020-63937-1          https://doi.org/10.1016/0305-4179(87)90090-8
           44.  Zolfagharian  A, Gregory  TM, Bodaghi  M, et  al., 2020,   55.  Leung K, Cheng J, Ma G, et al., 1984, Complications of Pressure
               Patient-Specific 3D-printed Splint for Mallet Finger Injury.   Therapy for Post-burn Hypertrophic Scars: Biomechanical
               Int J Bioprint, 6(2):1–13.                          Analysis Based on 5 Patients. Burns, 10(6):434–8.
               https://doi.org/10.18063/ijb.v6i2.259               https://doi.org/10.1016/0305-4179(84)90085-8
           45.  Holt SG, Yo JH, Karschimkus C, et al., 2020, Monitoring Skin   56.  Miyatsuji A, Matsumoto T, Mitarai S, et al., 2002, Effects of
               Temperature at the Wrist in Hospitalised Patients May Assist   Clothing Pressure Caused by Different Types of Brassieres
               in the Detection of Infection. Intern Med J, 50(6):685–90.  on Autonomic Nervous System Activity Evaluated by Heart
               https://doi.org/10.1111/imj.14748                   Rate Variability Power Spectral Analysis. J Physiol Anthropol
           46.  Chen G, Xie J, Dai G, et al., 2020, Validity of the Use of   Appl Hum Sci, 21(1):67–74.
               Wrist and Forehead Temperatures in Screening the General      https://doi.org/10.2114/jpa.21.67








           134                         International Journal of Bioprinting (2021)–Volume 7, Issue 1